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Have you ever wondered how the water in your faucet gets there? Where your garbage goes? What all the pipes underneath city streets do? For those who have ever stopped mid-crosswalk, looked around at a rapidly moving metropolis, and asked themselves "How does it all work?," THE WORKS is required reading.
ALL CITIES, BIG AND S M A L L , rely on a vast array of interconnected systems to take care of their citizens' most basic needs: keeping water bubbling through the pipes, traffic moving on the streets, power flowing to businesses a n d homes. Largely invisible and almost always taken for granted, these are the basic building blocks of urban life. But how exactly do these systems w o r k ? Using New York City—among the biggest and most complex of world cities—as its point of reference, The Works: Anatomy of a City answers that question. Deftly interweaving text and graphics, it sheds light on the technologies that power the metropolis: how do a billion gallons of water each day get to city homes and businesses? Who coordinates traffic lights to keep traffic moving on roads? How do flowers get to your corner store from Holland or bananas from Ecuador? Where does waste go w h e n you flush your toilet? What happens w h e n a subway car stalls? It also describes the people w h o lie behind these technologies—the pilot w h o brings a ship through the Narrows, the sandhogs w h o are digging Water Tunnel No. 3 under Manhattan, the maintenance engineer w h o ensures the Holland Tunnel doesn't leak. Scattered throughout are fascinating facts and anecdotes: did you know that the George Washington Bridge was originally designed to be clad i n concrete, but its skeleton was so attractive that the Port Authority decided to leave it "naked"? Or that city sewage used to be sent by train to a field i n western Texas but is now routinely turned into pellets that
( c o n t i n u e d on b a c k
flap)
1105
(continued /rom / r o n t /lap)
fertilize orange groves in Florida? That the more than a billion gallons of water New Yorkers use each day are gravity fed, meaning they will naturally rise to the sixth floor of any building without needing a pump? Or that retired subway cars travel by barge to the mid-Atlantic, where they are dumped overboard to form natural reefs for fish? Unique in the breadth and depth of its information, here is "the city that never sleeps" operating 24/7. The Works is the ultimate guide to the w a y things work in the modern city.
Kate A s c h e r received her M.Sc. and Ph.D. in government from the London School of Economics and her B.A. in political science from Brown University. Kate formerly held positions at the Port Authority of New York and New J e r s e y and in corporate finance overseas before taking up her current position as executive vice president of the New York City Economic Development Corporation.
The Penguin Press
A member of Penguin Group ( U S A ) Inc. 375 Hudson Street, New York, N . Y . 1 0 0 1 4 www.penguin.com
ISBN
1-59420-071-8
THE W O R K S
A N A T O M Y OF
Kate Ascher Researched by Wendy Marech Designed by Alexander Isley Inc.
The Penguin Press New York 2005
THE PENGUIN PRESS Published by the Penguin Group Penguin Group (USA) Inc., 375 Hudson Street, New York, New York 10014, U.S.A. Penguin Group (Canada), 90 Eglinton Avenue East, Suite 700, Toronto, Ontario, Canada M4P 2Y3 (a division of Pearson Penguin Canada Inc.) Penguin Books Ltd, 80 Strand, London WC2R oRL, England Penguin Ireland, 25 St. Stephen's Green, Dublin 2, Ireland (a division of Penguin Books Ltd) Penguin Books Australia Ltd, 250 Camberwell Road, Camberwell, Victoria 3124, Australia (a division of Pearson Australia Group Pty Ltd) Penguin Books India Pvt Ltd, 11 Community Centre, Panchsheel Park, New Delhi - no 017, India Penguin Group (NZ), Cnr Airborne and Rosedale Roads, Albany, Auckland 1310, New Zealand (a division of Pearson New Zealand Ltd) Penguin Books (South Africa) (Pty) Ltd, 24 Sturdee Avenue, Rosebank, Johannesburg 2196, South Africa Penguin Books Ltd, Registered Offices: 80 Strand, London WC2R oRL, England First published in 2005 by The Penguin Press, a member of Penguin Group (USA) Inc. 1 3 5 7 9 10 8 6 4 2 Copyright © Portfolio Projects, 2005. All rights reserved Illustration credits appear on pages 218 and 219. CIP data availbale. ISBN 1-59420-071-8 Printed in Singapore Set in FF Eureka and Square 721 Designed by Alexander Isley Inc.
Without limiting the rights under copyright reserved above, no part of this publication may be reproduced, stored in or introduced into a retrieval system, or transmitted, in any form or by any means (electronic, mechanical, photocopying, recording or otherwise), without the prior written permission of both the copyright owner and the above publisher of this book. The scanning, uploading, and distribution of this book via the Internet or via any other means without the permission of the publisher is illegal and punishable by law. Please purchase only authorized electronic editions and do not participate in or encourage electronic piracy of copyrightable materials. Your support of the author's rights is appreciated.
To Rebecca and Nathaniel
live in the world's largest cities—places like London, Sao Paulo, Shanghai, and New York—and hundreds of millions more commute to them each day. Wave upon wave of vehicles course through their streets, while thousands of tons of cargo move in and out of their freight terminals. Less visibly, millions of gallons of clean water flow silently
through their pipes—while millions more
e.g., on a unified system of water delivery,
are carried away as waste. All the while,
on in-city generation of power, on the world s
vast amounts of power are consumed by
largest central steam system.
their homes and businesses and millions of gigabytes of data flow through their telecom wires. Rarely does a resident of any of the
The magnitude and scope of the infrastructure that supports daily life in New York makes it the ideal subject for a study of how cities work. New York has
world's great metropolitan areas pause to
everything: sewers, power, telecom,
consider the complexity of urban life
water, road, rail and marine traffic—all
or the myriad systems that operate round
piled atop one another in what may be the
the clock to support it. He or she wakes
densest agglomeration of infrastructure
up in the morning to turn on a tap, switch
anywhere on earth. Exploring the systems
on a light, flush a toilet or perhaps grab
that keep New York functioning at the
a banana—little knowing how much effort,
pace it does provides a fascinating insight
on the part of how many people, goes
into the complexity of urban life at the
into making the simplest morning routine
dawn of the twenty-first century.
possible. The rest of the day is also
The chapters that follow explore five of
deceptively simple: crossing a street, riding
the most interesting, and in many cases
the subway, taking out the garbage—even
least visible, components of New York City's
the most mundane domestic tasks would be
infrastructure: moving people, moving
impossible without the far-reaching,
freight, providing power, supporting
complex, and often invisible network of
communications, and keeping the city clean.
infrastructure that supports them.
Like the essential systems that keep a
While this holds true for urban life across
human body running, each of these is vital
the globe, no city is more dependent on its
to the functioning of the metropolis.
infrastructure than New York. A vertical as
And as with any lesson in anatomy, these
well as a horizontal city, power is king:
complex systems—while interdependent—
without it, the two things that move more
are best studied discretely. Each chapter
bodies than any other—the subway and
is devoted to a system, and may be read as
elevators—would grind to a screeching halt.
a whole or, alternatively, in sections
As a city of trade, thousands of tons of goods
designed to highlight its most important
move in and out of its ports and terminals
component parts. In either case, the
each day—by rail, truck, sea, and air. And as
graphic explanations and illustrations that
one of the world's most densely populated
accompany the text should form an
urban areas, it relies on communal delivery
integral—and we hope enlightening—
of services to an extent few cities do—
part of the reading experience.
The world of infrastructure
is vast, and to many of us infinitely
interesting. Throughout this book, every attempt has been made to select those topics that seemed most relevant and at the same time least familiar to a broad spectrum of readers, and to approach them in a way that readers will easily grasp.
The pages that follow are full of both facts and This information
explanations.
is generally intended to convey an order of
magnitude, a chronology of events, or a broad causal relationship. While every effort has been made to ensure that the data presented here are accurate at the time of publication, neither the publisher nor the author assumes any responsibility for or changes that occur after publication.
errors,
Moving People Moving Freight Power
2
Streets
26
Subway
44
Bridges £r Tunnels
58
Rail Freight
68
Maritime Freight
80
Air Cargo
86
Markets
92
Electricity
no
Natural Gas
116
Communications Keeping It Glean
124
Telephone
136
Moving the Mail
142
The Airwaves
152
Water
170
Sewage
184
Garbage
The Future
204
Index
220
Between residents, visitors and commuters, tens of millions of journeys are made each day within New York City's boundaries. Many of these are made by mass transit, generally subway or bus; the remainder rely on taxis, private cars, or commercial vehicles. Just how the street and transit networks get everybody where they are going—safely, quickly, and with relatively little hassle—is one of the miracles of the modern city. Streets are, of course, the most important element of moving large numbers of people—without a system of traffic signals and pedestrian crossings, urban life would be chaotic indeed. But subways are also important, and keep the volume of people on the roads to a manageable level. And bridges and tunnels, as an extension of the region s roadways, are equally necessary to move people smoothly across this city of islands.
and subway system below while providing a platform for traffic signals, parking signs and meters, streetlights, and sewers. Alongside the streets run the equally important sidewalks, which
New York is a city of streets. Almost 20,000 miles of streets and highways connect the o J inhabitants of the five boroughs. Only 1,250
cater to pedestrian life and offer a foundation for conveniences like telephones and mailboxes, and for the urban vegetation known as street trees. The street system we see today is both more complex and yet more orderly than at
any time in New York's history. The earliest
of those miles represent highways: most
roads, clustered in lower Manhattan,
are primary and secondary roads (7,300
were narrow affairs—easily choked with the
miles) or local streets (11,000 miles).
traffic of the day. As Manhattan expanded
The streets themselves, while simple in appearance, provide either the covering
northward, roads to northern settlements were developed somewhat randomly,
or the foundation for a world of related
probably along the routes of old Indian
infrastructure. They protect the utilities
trails. Many if not all of these roads were the predecessors of today's broad north-
Streets
south avenues. The first real systemization of streets— and perhaps the event that best explains what we see around us today—was the development of the Grid Plan for Manhattan in 1811. Also known as the Commissioners' Plan, it fixed block and lot sizes and imposed the rectilinear grid that governs
The Commissioners' Plan
Manhattan's streets. While it succeeded in its
of
primary purpose of underpinning orderly
1811
The Commissioners' Plan for
M a n h a t t a n , also known as the Grid Plan,
real estate development, it arguably failed
was adopted in 1 8 1 1 by the Common Council
to provide capacity for the heavy north-
of the city. It mandated a gridiron layout
south traffic that would later be addressed
for the expansion of M a n h a t t a n ' s s t r e e t
by the development of the subways.
network, which up t o t h a t time had evolved haphazardly. The plan's authors envisioned the heaviest traffic would flow from east to w e s t , so t h e s e s t r e e t s were spaced closely (the width of these s t r e e t s was set at 6 0 feet between building lines). In c o n t r a s t , north-south avenues were set farther apart and were wider ( 1 0 0 feet between building lines).
Keeping traffic moving on the streets of New York almost two centuries after the Grid Plan was introduced is a formidable
New York's Street Network
and expanding task. From 1982 to 2000, when the population of the city increased
Highways
by roughly 10 percent, the number of
Major Roads
miles traveled within city borders rose by
M i n o r Roads
some 45 percent. Twenty years ago, roughly 3.4 hours each day were considered "rush hour"; today, rush hour has more than doubled, to between seven and eight hours each day. But it is not just cars that are the focus of the city's traffic management efforts. Pedestrians are an equal presence on the streets, and any successful system must carefully integrate and synchronize the two. Doing so requires more than just the streetlights which govern traffic at 11,400 of the city's 40,000 intersections. It involves parking rules and restrictions, a pedestrian crossing system, one-way traffic patterns, and a host of other innovations—bus lanes, truck routes, "thru streets," and limitedaccess roads, to name just a few.
4
The Works
Mouing People
Streets Regional Traffic
Most of the vehicles that clog Manhattan's streets, and
many that regularly use streets in the outer boroughs, come from outside the city. Each day, an estimated I.I million cars and trucks cross into New York—from New Jersey, Long
Anatomy of an Accident
Island, or Westchester. Managing this flow—on highways,
major accident occurs in the
bridges, tunnels, and local roads—is an important part of
region, among the most important agencies to
the overall effort to keep New Yorkers on the move.
t r a v e l e r s is Transcom. Created originally
While the city's Department of Transportation (DOT)
when a
metropolitan
as a way to enable its member agencies to share
is largely responsible for the movement along city streets
road construction information and resolve
and bridges, a number of agencies share responsibility
schedule conflicts, it soon gave birth to a round-
for the wider regional road transportation network, including
the-clock control room, set up to communicate
the Port Authority (trans-Hudson bridges and tunnels);
information about major traffic accidents in the
the Triborough Bridge and Tunnel Authority (Verrazano,
region. The idea is simple: when an accident
Triborough, Whitestone, and Throgs Neck bridges,
occurs, the transportation agency responsible for
among others); and New York State (all state highways).
t h a t road will be too busy dealing with the
Altogether, more than 16 different public transportation or
problem to inform neighboring jurisdictions of the
safety agencies—with more than 100 different control
incident. Transcom's job is to do j u s t t h a t .
rooms—operate within the region. Alert times 5 : 3 0 - 6 : 0 0 a.m.
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Transcom Screen Shot
Until recently, little if any coordination existed between these agencies, particularly with respect to infrastructure repairs, leaving the public to suffer through weekend after weekend of torturous road travel. That changed rather dramatically in the mid-1980s with the birth of Transcom, the "United Nations of transportation." An organization made up of 18 member agencies, Transcom monitors roadways in the tristate area and shares information on active and
At 7:00 a.m.
planned construction, sports events, and accidents with its
Subsequently, outreach w a s expanded
member agencies. In addition to providing advice for
with calls to agencies in Pennsylvania,
investigation, cleanup, and
Delaware, M a r y l a n d , a n d South
inspection for structural damage.
broadcast over the radio, Transcom also orchestrates the variable message signs that drivers may find along the region's highways—telling them where the delays are and how they might best avoid them—and runs a round-the-clock control room to deal with major traffic accidents in the region.
Jersey. Communications referred t o the / a c t t h a t although the New
Agencies alerted: New Jersey
Jersey-bound lower level was likely to
Transit Public Affairs, New York
have a lane clear shortly, delays
Waterway Ferry, Smart Routes
would be extended due t o the pending
(Boston), M e t r o Traffic (Providence).
Before 6:00 a.m. Within ten minutes, the closure w a s expanded to incorporate
the
entire
M a n a g e m e n t Center, MTA Command Center, NYC DOT, NYC Transit
Before 7:00 a.m. The communications outreach, / o l l o w i n g / u l l closure, incorporated the approaches coming into New York. The information disseminated gave the impression of a temporary closure and estimated a delay of 6 0 - 9 0 minutes during the impending rush hour. Agencies alerted: New Jersey State Police, Westchester County Police, Port Authority Staten Island Bridges, Verrazano Narrows Bridge,
Agencies alerted: Lincoln Tunnel,
Buses, S h a d o w / M e t r o Traffic, Throgs
Palisades Interstate Parkway, New
Neck Bridge, Whitestone Bridge,
Jersey Transit Buses, Port Authority
Trihoro Bridge, NY State
Bus Terminal, Bergen County Police,
LaGuardia Airport, New Jersey
Fort l e e Police, NYPD Traffic
Turnpike Authority.
Newburgh Beacon Bridge, Henry Hudson Bridge, Tenafly Police, leonia Police, Edgewater Police, Inglewood Cliffs Police, Alpine Police, Palisades Park Police, Pennsylvania DOT, Connecticut DOT, New York State DOT, JFK I n t e r n a t i o n a l Airport, New Jersey Highway Authority, M e t r o Traffic (Delmarva), M e t r o Traffic (Hartford).
Thruway,
6
The Works
Moving People
Streets Traffic Signals
New York City is awash in
traffic lights—11,400 of them to be exact. Contrary to the belief of many, they are not intended to limit speed; their primary purpose is to control right-of-way at
1. Fifteen computers a t the TMC control up to 720 intersections each, monitoring real-time data including current signal displays, traffic detectors, and cycle lengths for each intersection. The area computers are connected to t h e intersections themselves by a variety of broadband cable technologies.
intersections. In that sense, they are critical 2. In addition to the computers, traffic flow is monitored on video cameras by TMC staff. Some 230 cameras, 90 of them in Manhattan, send images to the operations center. In case of an incident the TMC engineers can remotely adjust signal timing online or, if needed, dispatch m a i n t e n a n c e engineers.
to the successful coexistence of people and cars in the urban environment. As with most conventional traffic lights, New York's have two phases: an east-west one and a north-south one. They generally operate on 60-, 90-, or 120-second intervals; the cycle is determined by local traffic conditions and may even be longer at times. The city's longest cycles are on the West Side Highway and on Queens Boulevard, each of which features cycle times of two
3. The TMC also manages the "don't walk" signals t h a t govern pedestrian flow. These are programmed to accommodate an average stride of four feet per second but can be adjusted to fit local conditions. In areas with a concentration of elderly people or young children, a slower stride (three feet per second) governs the pedestrian crossing cycle.
minutes and fifteen seconds. Anyone who has ever had a good run down Columbus or up Amsterdam avenues in Manhattan knows that lights on major avenues in the city are often set sequentially—turning green in about six-second progressions. (The ideal cruising speed is about 30 miles per hour, which is, not coincidentally, the speed limit.) But other lights turn green simultaneously, including on many of the two-way avenues like Park Avenue. These lights are choreographed by New York City Department of Transportation at its Traffic Management Center (TMC) in Long Island City or manipulated manually by DOT staff. Connected to the lights by city-owned coaxial cable running under the streets, the TMC can change the length of red and green signals to accommodate daily fluctuations in traffic flow. During the morning rush hour, for instance, longer green lights on roadways leading into
4. Although a green light on one
Manhattan facilitate the movement of inbound traffic; in the evening, the pattern is reversed. Similar adjustments are made for planned events, such as parades and ballgames, and for unplanned ones, such as roadway accidents or water main bursts.
face of a traffic signal generally corresponds with a red light on the 5. Detector signals provide real-time information on traffic conditions. Magnetic loops adjacent to major intersections sense metal in cars passing above and send vehicle counts back to the operations center.
opposite side, in most cases there is a two-second period when both sides are red.
Traffic Light Buttons
was t o allow traffic t o flow freely on
M o s t of the 5 , 0 0 0 traffic lights not
t h e larger road until a sensor in
controlled directly by t h e T M C
the side street—or a button located
are set mechanically at boxes located
along it—signaled t h e presence of
near the intersection. Some of
a vehicle or pedestrian.
them—though not as many as one
Some 3 , 2 5 0 or so of these buttons
might expect—are still controlled,
remain in New York City, but fewer
at least in p a r t , by push buttons
than a quarter of them actually work.
located on nearby poles. Called
The cost of removing t h e deactivated
"semi-actuated signals" by traffic
ones is high (roughly $ 4 0 0 per
engineers, they f i r s t appeared in
intersection), so they remain—a
New York City in 1 9 6 4 . Located a t
testament t o a level of control
the intersection of a major roadway
by man over machine t h a t many New
and a minor side s t r e e t , t h e idea
Yorkers might wish still existed.
To address the daily conflicts between cars and pedestrians in New York, split phasing was introduced in parts of Manhattan in the fall of 2002 and became a permanent city initiative in 2004. Split phasing divides a traffic signal into three distinct parts, shown below, to provide pedestrians a safe street-crossing period, free from vehicle turns.
In the first instance, traffic on the avenue moves ahead on the green light, and traffic on the cross street is sto
During the next phase, traffic on the
In the last stage, both cars
avenue is stopped while vehicles on the cross street that are traveling
t u r n i n g from and going s t r a i g h t on
straight ahead may proceed. Those turning from the cross street
move; pedestrians m a y continue t o
are n o t permitted to move, enabling pedestrians on the avenue to cross on both sides of the street.
the cross street are allowed to cross on the n o n t u r n i n g crosswalk.
The Works
Moving People
Streets
Traffic Cameras
To monitor traffic flow across
number have been contested, and very few ticket recipients
the city, DOT has installed
have been found not guilty.
cameras at major intersections and on highways and bridges.
The program is apparently achieving its goals; studies have
Many of these cameras simply allow traffic engineers to
shown a 40 percent decrease in the total number of
watch and adjust signal timing. Others are more active in
motorist violations at intersections with the cameras. City
their pursuit of drivers violating traffic rules. "Red-light
transportation planners would like to see the program
cameras," for example, have been installed at fifty major
expand to additional locations. In the meantime, another
intersections throughout the city. These cameras take
200 locations have "dummy" cameras, which flash strobe
high-resolution photographs of vehicles that go through red
lights in similar fashion to the real ones.
lights, including a close-up of the license plate. Summonses, including a photograph of the plate, are sent to violators. New York was the first major city in the United States to implement a red-light enforcement program. Since its inception in 1993, more than 1.4 million summonses have been issued throughout the five boroughs. Only a small
Traffic Camera Locations Top Infraction Sites Madison and East 79th St., M a n h a t t a n ^{Park Avenue and East 30th St., M a n h a t t a n
-^C J-495 Service Rd. Westbound a t Van Dam St., Queens Kings Highway and Remsen Ave., Brooklyn
-^Cl-678 Service Rd. Eastbound a t Hillside Ave., Queens
130th St. a n d 20th Ave., Queens
-^C Rutland a n d Utica Aves., Brooklyn
Avenue Z a n d Coney Island Ave., Brooklyn
Q
Still Camera
+
Video Camera Top Infraction Site
How Red-Light Cameras Work
Red-light cameras are connected to
The computer calculates the speed of
The license plate in the photograph
The digital or photographic evidence
the traffic signal and to two sensors buried in the pavement
the vehicle and then takes a second shot of the car in the middle
is then referenced against Department 0 / M o t o r Vehicles d a t a ,
time in case the ticket is challenged.
a t the crosswalk or stop line. If a vehicle activates only one sensor
of the intersection. A camera records t h e d a t e , time, speed, a n d seconds elapsed since the light turned red.
to ensure the plate matches the description on record. The d a t a
ajter the light has turned red, the computer knows it has stopped a t the edge of the intersection; if it activates both, the computer takes a digital photo of the car entering the intersection.
Thru Streets Program
is stored online for a period of
are then converted to a printed violation a n d forwarded to the city's Department of Finance, and a summons is sent by mail to the owner of the vehicle in question.
Midtown Manhattan auto speeds are
notoriously slow—4.8 mph on average eastbound and 4.2
To better manage the midtown grid, in the fall of 2002, DOT selected certain streets to be designated "thru steets" to facilitate crosstown traffic. No turns would be permitted
mph on average heading west. Many factors contribute
on or off five pairs of streets (36th/37th, 45th/46th,
to this problem beyond simply the high volume of vehicles
49th/50th, 53rd/54th, 59th/6oth) from Third to Sixth avenues
using the streets: large numbers of pedestrians, illegal
—with the exception of Park Avenue—between the hours
parking, construction activity, and truck loading are most
of 10 a.m. and 6 p.m. Neighboring streets were earmarked for localized circulation and commercial goods delivery,
to blame.
which was facilitated by providing curb space on both sides (as opposed to one side) of these adjacent streets.
Speeding Across Town Before
>v*i>sr
After
The Works
Moving People
Streets Traffic-Calming Measures Thru streets and split phasing are just two of the newest weapons in the DOT's armory of traffic-management techniques; traffic lights and stop signs, in contrast, Neckdowns, also
are two of the oldest. Some are laborintensive, such as deploying police at congested intersections. Others, such as
called curb
extensions,
Bus Bulbs involve widening
the
sidewalk
involve narrowing
at a bus stop so t h a t
the street and widening
buses do not leave the
the sidewalk.
travel lane when stopping
concrete barriers, may be temporary—and
Roadway Narrowing can be achieved either by widening
the sidewalk
or by using street markings to indicate
to pick up passengers.
narrowed
Bike Lanes must be a t least five feet wide when located next to a curb or parking.
Roadway Color or Texture may be used to accent or better define pedestrian crossing areas.
travel
lanes.
simply a way to protect or facilitate ongoing repair or construction. Beyond these, there are more than a dozen accepted "traffic-calming" measures designed to slow traffic or manage pedestrian flow.
Pedestrian Refuges involve small islands located in the middle of a two-way street, which allow pedestrians to cross in stages.
Speed Humps m a y be
Raised Crosswalks,
as high as three or / o u r inches, a n d m a y be circular, parabolic, or flat-topped in shape.
two to four inches above the street, may be located a t intersections or in the middle of a block.
Roadway Medians generally appear as raised islands along the center of a street.
Raised Intersections involve flat, raised areas t h a t cover a n intersection and often include a textured
surface.
Chicanes involve
Partial Diverters
Diagonal Diverters
All-Pedestrian Phases
building o u t curb lines
block travel in a
force all traffic to turn in
involve red lights on
on a l t e r n a t i n g sides
particular direction at
a certain direction.
of the street.
an intersection.
both streets a t an intersection, which allows pedestrians protected crossing
time.
Gateway Treatment involves a combination of measures, such as texture and raised street surfaces, to mark the entrance to a particular area.
Leading Pedestrian Intervals involve holding all vehicles at an intersection while giving pedestrians on at least one approach a green walk sign.
11
Calming Queens Boulevard
Twelve-lane
Queens Boulevard is one of the widest streets in the city. It is also one of the busiest—and most dangerous. A t least 5 0 pedestrians have been killed along Queens Boulevard in the last decade alone. To make the s t r e e t safer, in 2 0 0 0 , DOT began implementing improvements along Queens Boulevard between the Long Island Expressway and Union Turnpike. Pedestrian fatalities subsequently dropped, from an average of nine a year in the 1 9 9 0 s to just three in 2 0 0 1 and two in 2 0 0 2 . Roughly 1 6 , 0 0 0 linear feet of pedestrian
Midblock signalized crossings, with highvisibility crosswalk markings, were installed at three locations.
Nine new highvisibility crosswalks
fencing were installed on the service road medians.
were introduced.
Sidewalk extensions, known as neckdowns were installed a t 14 locations.
Pedestrian refuge areas at service road medians were expanded a t nine locations.
12
The Works
Moving People
Streets
For a city of extraordinary diversity, New York's streets are remarkably uniform—materialwise, that is. The vast majority of city streets consist of two layers of asphalt over a concrete base, although a handful are made entirely of concrete. Nearly all are graded to be slightly higher in the center, to allow water to run off into catch basins at street corners. Sidewalks are generally concrete with steel-faced curbs, though distinctive curbs made of granite or bluestone may be found within a historic district or near notable commercial buildings. The use of asphalt as a paving material in the city is largely a twentieth-century phenomenon. Various forms of impacted stone and gravel were common street materials until 1872, when Battery Park and Fifth Avenue were the first streets to be paved with asphalt. But the longest-lived and most durable New York City street material to date is cobblestone: it has served as the road material of choice for two hundred years.
The A r t of the Manhole Cover /v-rrn ~rr~r~i /-rrrr fArm nrri~7f~r"r~r~ , 3)J£JLSJ4
-rrrrrrr
The Catskill Water m a n h o l e cover
Con Edison m a i n t a i n s t h e largest
A commemorative manhole cover,
The Borough of Richmond, now
was p a r t of the second phase of
n u m b e r of manhole covers in
called Global Energy, was
known as Staten Island, was created
the city's development of its upstate
the city, encompassing various designs.
designed by Karim Rashid
when the City of New York was
for Con Edison in honor of the
incorporated in 1898.
water delivery system.
millennium.
Beneath City Streets
Most New York City roads
have
two top layers, each consisting of two to three inches of asphalt.
Below the asphalt is usually a base layer of concrete, though
occasionally
wood or clay is found below the
History in Stone
New York's
cobblestones are not as old as most New Yorkers
surface. think. The concept of using small round stones as s t r e e t paving dates back 3 5 0 y e a r s , but the cobblestones we ride across today are a mere 150
years old. Flat rectangles of Belgian granite,
they were originally brought to New York in the 1 8 3 0 s as ship ballast. Today, some 3 6 lane miles of cobblestones remain in New York City. Some s t r e e t s , like W o o s t e r , Greene, M e r c e r , and Bond in S o H o , are in a protected historic district; others—such as P e r r y and Sewer pipes generally r u n down t h e middle of the street; catch basins located a t the corners feed into it.
Bank s t r e e t s — a r e not. Four times as
expensive as asphalt, cobblestones in "unprotected" d i s t r i c t s will only occasionally be replaced in kind. Often holes in these streets are filled in with asphalt or a mix of other kinds of s t o n e s .
This snow/lake design dates from the
This cover can be traced back to t h e
late nineteenth century and was
city's Department of Public Works.
used to cover manholes used by the electric utility companies.
This manhole cover design was done for the Fire Department.
The initials RTS stand for "rapid t r a n s i t system " and are found above some subway shafts.
The Works
Moving People
Streets Street Defects
New York City streets are in
Street Repair
constant need of repair, either on
a spot basis or requiring replacement of the street surfaces in its entirety. Most of the repair work is caused by extreme winter temperatures and heavy truck traffic, although some is simply a product of general wear and tear. A variety of street defects keep DOT crews busy. Potholes are one kind of common defect; others include sinkholes, ditches, hummocks, ponding, open or failed street cuts, and cracked catch basins. Repair tactics vary, according to the defect. If the problem is the result of a failed utility cut,
Ponding conditions refer to the buildup 0 / w a t e r and occur a t low points in t h e roadway as a result of poor drainage systems or insufficient grading.
Cave-ins, also known as sinkholes, are characterized by jagged edges around a deep hole.
the responsible utility company is asked to make the fix. If the defect is too large for the DOT's emergency pothole crew, a temporary "make safe" repair is completed until the street can be properly restored. The most dangerous defects are those found in a crosswalk or driving lane —and they are repaired first. Both street and utility crews rely on a uniform system of prerepair street markings to distinguish the type and location of underground infrastructure adjacent to a repair area. These seemingly random colored markings on streets are actually part of a sophisticated repair language: different colors and shapes are used to indicate either
Manhole covers can present a danger to drivers if they are cracked or missing or improperly placed above or below street level.
Old utility cuts are generally square or rectangular. If the repair was made within the last three years, the contractor is responsible for fixing it.
the limits of the work zone or the location of nearby utility lines. White paint is generally used to delineate a work site in advance of repair work being undertaken by city or private repair crews.
S t r e e t Markings
GU
) Level of Service C: >24 sq. ft./ped. At LOS C, sufficient space is available to select normal walking speeds and to bypass other pedestrians in primarily unidirectional streams. Where reversedirection or crossing movements exist, minor conflicts will occur, and speeds and volume will be somewhat lower.
Level of Service E: >6 sq. ft./ped. At LOS E, virtually all pedestrians would have their normal walking speed restricted, requiring frequent adjustment of gait. At the lower range of this LOS, forward movement is possible only by "shuffling." Insufficient space is provided for passing of slower pedestrians.
Level of Service D: >15 sq. ft./ped. At LOS D, freedom to select individual walking speed and to bypass other pedestrians is restricted. Where crossing or reverse-flow movements exist, t h e probability of conflict is high, and its avoidance requires frequent changes in speed and position.
The Works
Moving People
Streets Street signs abound in New York and
other street signs are also required to have a consistent
are a key element in the city's
shape, color, style, and meaning. Nearly all New York City signs are produced at DOT's sign shop in Maspeth, Queens.
efforts to manage its vehicular flow. Signs indicate where to
Only very rarely does a New York City sign maker have a
turn and where not to, where to park and for how long, where to catch a bus, how fast to travel, etc. They also, of
chance to be creative. The most recent opportunity came
course, tell pedestrians or drivers what street they're on.
with the initiation of the "thru streets" initiative in midtown
There are over one million signs on New York City streets,
Manhattan in 2002. After much deliberation, the color
with parking and street-cleaning signs the most
purple—not yet a nationally designated color—was chosen
predominant. Just as a stop sign is universally recognized,
for the new signs.
The Evolution of a Street Sign £
The division of signs and
|?|
markings
the end limits of the streets chosen
it was the express street concept.
for the Thru Streets program.
A plan for the sign layout is devised.
,THR
U
0
(TU* '
THRU
©
THRU
DOT proposes signs for specific street locations. • These are placed at the entrances to the Thru Streets, and on the Thru Streets themselves.
Generic letters, w i t h o u t distortion, are chosen for readability. In order to make it look as if the words were moving,
• Turn restriction signs are also proposed. • Signs are also proposed for the street corners.
• the word " T h r u " is given a slant. t i 101 I I I MvU *
TI I
11*11 111 x
1 _
DOT chooses the street corridors and
is given a concept. In this case,
• lines are drawn off to the left.
• Once it has been determined, the formula for sign assignation is applied to every intersection.
Colors are chosen.
WHRU
• Because of standards set out in a federal traffic m a n u a l , certain colors can't be used.
STREET
Q
The borough office okays the signs.
• Green, which is for directional signs, is considered. • Coral and purple are both unassigned colors. • Purple s t a n d s o u t , a n d it is also used for E-ZPass, which makes
7M
it
The sign specifications are sent to
48" 5-C BLACK STHRU STREET BLACK ARROW
desirable.
NEXT T U R N PERMITTED AT AVE I0AM-6PM MON-FRI
5-D BLACK
the sign shop in Maspeth. Approximately 700 signs, including those for changes in parking regulations, are made.
3
^
I n / o r m a t i o n will be printed in regulation size and style.
Counting Signs New
the
Street-cleaning regulations 3 3 . 2 % Other parking regulations 2 3 . 4 %
York is home
to a world of s t r e e t signs— over a million. Some, like
Snow emergency route signs 3 . 3 %
those governing a l t e r n a t e side of the
s t r e e t parking, Arterial
signs 1 . 5 %
are fashioned specifically for city s t r e e t s .
Priority regulatory signs 1 3 % (stop signs, do not enter)
Street name signs 1 9 . 3 %
Turn restrictions and other intersection signs 6.3%
There are 1 3 0 , 0 0 0 "priority regulation " signs, which include stop signs as well as one-way arrow and "do not enter" signs.
An estimated 3 3 2 , 0 0 0 signs depicting streetcleaning regulations are found on city streets.
t ^
Street-marking changes, such as t u r n lanes and " t h r u " lanes, are made to the streets. Changes in parking regulations are also instituted.
NEXT TURN PERMITTED AT 3 AVE
The signals division installs mast arms for the signs.
Because all signs c a n n o t be h u n g simultaneously, signs are hung in advance and then covered the program is officially
until
unveiled.
^
Inspectors from the planning u n i t are sent to study compliance and to make traffic counts. The Police Department also sends officers to monitor the traffic.
^
Small adjustments, such as allowing t u r n s onto Park Avenue, are made. So as to not have to make entirely new signs, overlays are used when possible.
^
10AM-6PM° MON-FRI DEPT OF TRANSPORTATION
Maintenance records are begun. Signs last approximately 1 0 years.
HOUR PARKING 0 A M - 7 P M
WALL Over 1 9 0 , 0 0 0 street signs can be found across the five boroughs.
INCLUDING SUNDAY
There are 2 3 4 , 0 0 0 parking regulation signs.
More than 6 0 , 0 0 0 signs govern t u r n s and other movements a t city intersections.
The Works
Moving People
Streets Two Centuries of Streetlights
t
1820
1800
1807 Among the earliest lampposts were those made of wood, which burned oil.
1830
1 1840
—1 1850
—I— 1880
1— i860
1892 The j î r s t o r n a m e n t a l
1825 Gas streetlighting was first installed in New York City in 1825 a n d continued into the twentieth century.
lamppost w a s placed on Fi/th Ave. in 1892 and was limited to t h a t street.
I 1930 1900 The bishop's crook, which appeared a t the t u r n of the last century, was the second o r n a m e n t a l electric streetlight. It was reproduced in 1980.
40
— i — 1950
1908 The boulevard system was designed for streets with center malls. Mast arm lights
1970
1
1990
1980 The original cobra streetlight featured a pendant light with the recognizable octagonal pole.
reached over the roadway.
A century after electric lighting began pushing gas streetlights into oblivion, New York City is awash in streetlights— 333,670 in all. These include 35 to 40 different types. recognizable by an illumination component
The Streetlight of the Flltlire In February 2 0 0 4 , a competition
closely resembling the head of a cobra.
to design a new citywide streetlight was
First introduced in the 1950s, its design is
undertaken by the city's Department of
purely functional; as a result, it has
Design and Construction in conjunction with
The standard is the cobra streetlight,
relatively few fans. More beloved are the
DOT. Some 2 0 1 entries from 2 4 countries
30 or so other models that survive in
were submitted to a panel made up of
small numbers across the city—models with
prominent architects, engineers, and public
magical names like bishop's crook, reverse
servants. The winning design, announced
scroll, and lyre.
in October 2 0 0 4 , was submitted by Thomas
Historic or modern, street lighting
Phifer and P a r t n e r s . The new design will
is big business. The city pays Con Ed roughly
be used to light streets, sidewalks, and parks
$50 million each year in lighting bills,
within the city.
most of which finds its way to the New York Power Authority, which provides the electricity. In residential areas, illumination is at no volts; in commercial areas— where some business districts choose to buy and maintain their own streetlights— it is provided at 220 volts.
Parking Meters
Parking meters
traffic cop, regulating who can use valuable
Alternate Side of the S t r e e t Parking N o t all parking
curb space and for how long. For the city,
the city costs money: in residential areas,
they are an important revenue generator:
parking is generally free to those lucky enough
the 66,000 meters belonging to DOT's
to find a space. B u t in many areas of the
act as a sort of
in
Division of Meter Collections collectively
city even free parking is complicated, thanks
bring in upward of $70 million each
to alternate side of the street regulations,
year. Although parking meters in some areas
which force drivers to clear one side of the
have been replaced by "muni-meters,"
street every couple of days for street cleaning.
which issue tickets that must be placed on
Begun in the 1 9 5 0 s on the Lower East Side
car dashboards, the familiar gray boxes
as an experiment to facilitate the movement
are unlikely to disappear from the New York
of newly mechanized street-cleaning
City landscape anytime soon.
machines, the program today incorporates some 1 0 , 0 0 0 miles of city roads.
Most meters are designed to run a little long, to avoid challenges to their accuracy. A mechanical meter with a new timer can run from one to nine minutes long over the course of an hour.
0
Coins deposited in the meters accumulate in a coin box located in the " v a u l t " of each meter. Separate keys are needed to open the vault and the coin box located within.
Each parking meter has the capacity to hold between $ 3 0 and $ 6 0 , depending on the size of the coin box and the mix of coins.
DOT's Division 0 / M e t e r Collections is responsible for collecting coins from each of the roughly 66,000 parking meters t h r o u g h o u t the city a t least once during a 2 4 - d a y cycle. To collect coins from parking meters, collection crews use "canisters," steel boxes t h a t roll along the streets. Field supervisors are assigned to observe the crews during their collection assignments to ensure collection procedures are being carefully followed.
%
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Moving People
Streets Look down any street in the city, and
one year), they can plant them. There are several ways
chances are you will see at least
to do this:
a few trees sprouting from the concrete. At last count, there
• Fill Out a Street Tree Request Form and Wait.
were an estimated 2.5 million trees in the city, of which
There is no charge for this service, but it can take up to
500,000 or so can be found on the streets (as opposed to the
two years until the requested tree gets planted by the
parks or backyards) of the metropolis.
Parks Department.
It's not easy being green in the middle of the city. In
• Visit the Parks Department s One-Stop Tree Shop.
addition to the usual challenges of disease and insects, street
Residents pay for the tree and its installation,
trees are also subject to vandalism, neglect, dogs, and
but parks staff pick it, plant it, and care for it.
generally difficult growing conditions. Yet they are a vital part of the streetscape, adding shade and color to the
• Plant It. This requires a permit from the Borough Forestry Office, adherence to a list of approved species,
sidewalks, providing cleaner air, contributing to energy
and an inspection. If a new tree pit is to be dug,
savings, and raising property values.
both a permit from the Department of Transportation
Street trees are one of the few municipal services where citizens may participate firsthand. New Yorkers can assist in tree maintenance so long as they complete the officially licensed, 12-hour "Citizen Pruner" course offered by Trees New York, which covers subjects such as tree biology and identification, pests, tree pruning, and tree-pit gardening. Although New Yorkers can't own street trees (all trees planted in the city's right-of-way become city property after
Mapping New York's Trees
and strict observance of guidelines for removing concrete are required.
A Sampling of New York's S t r e e t Trees
Serviceberry is a small tree that produces w h i t e / l o w e r s .
Japanese Flowering Cherry is a small, rounded tree t h a t does best in lawns and grassy strips.
Korean Mountain Ash is a narrow, small tree t h a t produces a white /lower.
Japanese Tree Lilac h a s a pyramidal shape and produces a white flower.
American Hornbeam is a slow-
Chinese Elm features purple leaves in the fall a n d is sensitive to the Asian long-horned beetle.
Red Maple is a medium-height tree with a rounded shape.
Bald Cypress has a pyramidal shape a n d can grow beyond 50 feet in height.
English Oak is a slow-growing tree t h a t can tolerate salty and dry conditions.
to the Asian long-horned beetle and is
growing tree with a pyramidal shape.
Gingko is a narrow, slow-
Callery Pear grows to
growing tree t h a t / e a t u r e s yellow
between 35 a n d 50 feet in height a n d
leaves in the fall.
produces a white /lower.
Shantung Maple is susceptible there/ore prohibited from Queens, Brooklyn, and M a n h a t t a n .
European Ash is prohibited in Queens, Brooklyn, and M a n h a t t a n due to its sensitivity to the Asian long-horned beetle.
Golden Raintree is a rounded tree t h a t produces yellow flowers.
Pin Oak has leaves that t u r n scarlet in the fall and can tolerate wet or dry soils.
Scholar Tree has a rounded shape and features creamcolored /lowers,
26
The Works
Moving People
of trains, it is absolutely the biggest—its 6,200 cars servicing 25 lines dwarf the fleets of even its largest competitors. And with 45,600 employees, represented by 25 unions, it is arguably one of the most complex subway systems to operate. The system we recognize
New York City's subway system is among the busiest urban transit systems in the world.
today by its award-winning color-coded map dates back to the nineteenth century. The earliest public transport within the city's bounds took the form of a 12-seat stagecoach running north along Broadway from the Battery
Every day, it handles over 4.5 million
starting in 1827; the earliest railways—
passengers—which equates to roughly 1.4
elevated ones—made their debut in 1868.
billion passengers each year. In terms
Not long after that, the first subway—
of volume, it is among the world's largest—
an experimental one run on pneumatic
surpassed only by Tokyo, Moscow, Seoul
power—was built furtively under City Hall,
and Mexico City. With respect to the number
but was abandoned for lack of political support within just a few years.
Subway Though g r a n t e d a license to build a p n e u m a t i c tube to carry
packages
under Broadway between Warren and Cedar streets, Alfred
Beach—a
young inventor—proceeded to drill a "people-moving
t u n n e l " in stealth.
The true predecessors of the modern subway were private subway lines set up by entrepreneurs after the turn of the last century. The earliest was the Interborough Rapid Transit (IRT) Line, which opened
In its first year, 4 0 0 , 0 0 0 people rode the car, but a stock market crash caused investors to withdraw and the service was terminated in 1873, three years after it began.
in 1904 and ran for nine miles along Broadway from City Hall to 145th St. in Manhattan. Initially calling at 28 stations, the IRT service was extended to the
Building a Subway Network The earliest subway
Bronx the following year, and subsequently
lines s t r e t c h e d along Broadway, from
to Brooklyn in 1908 and Queens in 1915.
north to s o u t h , and connected the
A second private line, the Brooklyn Rapid
boroughs of M a n h a t t a n and Brooklyn.
Transit Company (BRT), began providing
Gradually, the system expanded t o
service to Brooklyn at about the same time,
Queens and the Bronx.
but ran short of cash and emerged from bankruptcy as the Brooklyn-Manhattan Transit Corporation (BMT). The first city-run service, the Independent Rapid Transit Railroad (IND), did not appear until 1932. Eight years later, with the private lines on the verge of bankruptcy, the city purchased both the IRT and BMT and became the sole operator of all subway and elevated lines within city limits. The city operated the lines under the jurisdiction of its Bureau of Transport until 1953, when the New York State legislature created the New York City Transit Authority as a separate public corporation to manage and operate all city-owned transportation— Introduction of subway lines by years
subways, buses, and trolleys.
1930
Naming the Subways
1940
The letter system
of subway names was introduced following the unification of the independent subway lines in the 1 9 4 0 s , and the system of color codes was introduced in 1 9 7 9 to tie
together,
graphically, trains running along the same lines.
OOO OOOOO
OOOOOO
OOO O0OO
1, 2, 3, 4, 5, 6, 7, 9
A, B, C, D, E, F
J, L, M, N, Q, R, W
AA, QB, RJ
The first subway company, the IRT, originally designated the subway routes by the avenues they r a n under (e.g., Lexington) and included reference to the line's northern terminus. In 1948, this system was replaced with the numbered code t h a t is still in use today.
The IND, which made its appearance
The IND system of letter names was
in 1 9 3 2 , initially relied on a
extended to the various lines of
letter code t h a t r a n from A to H.
the BMT in i960, using some of the
For m a n y years, express trains on the BMT a n d IND systems bore single letters while local trains on these lines carried double ones (the AA, for example, w a s the slow train to Harlem). I n 1985, after color codes were introduced on the subway, double letters were eliminated entirely.
rest of the alphabet.
The Works
Mowing People
Subway The Subway Network
New York's subwaysystem is made up of a
far-flung and complex network of physical facilities. Its 25 interconnected lines stretch across four boroughs (Staten Island has its own overland railway system), with the New York's subway r u n s across / o u r boroughs day a n d night. It has more stations
longest (the C line) covering a length of over 32 miles. Some 68 bridges and 14 tunnels carry track through or into
t h a n other large systems a n d
468 subway stations. There, another 60 elevators and 161
relies on a system of parallel
escalators provide service to passengers.
express a n d local tracks to speed travel across the city.
The system runs along 842 miles of track—enough to stretch from the city to Chicago. Roughly 20 percent of it, or 180 miles, is not used for passenger service at all: it comprises support yards, shops, and storage areas that support the passenger network. But at its heart lie 660 miles of working track—two-thirds of it underground, with the remainder either elevated (156 miles) or at grade (57). Many of these miles lie in parallel, to support the local/express system— only 230 distinct "route miles" exist.
Tokyo boasts an a n n u a l ridership approaching three billion—making it as widely used as the New York a n d Paris systems combined. It also reaches the highest speeds—62 miles per h o u r on certain stretches.
Moscow opened its first Metro line in 1 9 3 5 . Today, its 270-kilometer system carries roughly three billion passengers a year through 165 stations, some of which are deep enough to serve as bomb shelters in the event of a nuclear war.
London's subway system is the oldest of the four major city subways in the world—it opened in 1863. I t is also the longest, serving 253 route miles. Its longest line, the Central Line, stretches a full 46 miles west to east across London.
Moscow
Tokyo
New York
London
In many ways, the system—although largely underground —relies on technology similar to other American railroads. Its track gauge, the distance between the rails, is the same as all major American rail systems (4 feet 8 inches) and its signaling system is hardly unique. But what set New
MOPNÎLLCJ S c h e d u l e d
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t r û i n s
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m o r n i n g rush
York's subway system apart from its very earliest days was the integration of local and express tracks into one network:
9
New York was the first major world city to construct and operate such a two-tiered system. Today, its uniqueness
-^^-^J^ - -
8 minutes
stems largely from the 24/7 nature of its operation: no %3
other major city boasts service all night long. 7 minutes
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Around-the-Clock Service: People per Car per Hour
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30
The Works
Moving People
Subway New York's subway
the network currently includes 734 token
system has more stations
booths and over 31,000 turnstiles. The
than any of its worldwide counterparts—
busiest single station in the system is Times
468 in total. More than half of them are
Square: it handles over 35 million paying
underground; the remainder are either
passengers each year. But that number is
elevated (153) or built on an embankment or
dwarfed by the number of passengers
"open cut" (39). The highest station is
moving through the 34th St.-Penn Station
Smith/Ninth Street in Brooklyn (F, G lines);
-Herald Square complexes on the A, C,
the lowest is 191st St. in Manhattan (1/9
E, B, D, F, N, Q, R, and 1, 2, 3, 9 lines:
lines), at 180 feet below street level.
collectively these three stations handle 60
Most New York subway stations are built to accommodate large volumes of passengers:
million fare passengers each year.
31
Times Square Station
The Times
Square s t a t i o n , deep under W e s t 4 2 n d S t . and Eighth Ave., is the busiest—and arguably the most complex—station in the subway system. The addition of new IRT, B M T , and IND lines to the original 1 9 0 4 IRT station over time created t h e transportation hub t h a t we know today. M a j o r redevelopment currently under way at the station, costing $ 2 5 0 million, encompasses renovation to platforms, passageways, and mezzanines, as well as elevators and escalators.
Abandoned Stations „ , „ „ . Uptown Platform Q, R, W Trams n
x
Over the f i r s t hundred
years of its existence, a number of subway platforms, * ' r
levels, and even entire stations have been taken out of use. The most notable is the City Hall s t a t i o n on the original IRT line—known for its soaring ceiling, skylights, and period chandeliers. The sharp curves along the platform proved too much for subsequent generations of t r a i n s , and it was abandoned in 1 9 4 5 . In t o t a l , t h e r e are nine abandoned stations in t h e
network
—five of which can t o d a y be seen from passing subway trains. These include W e s t 9 1 s t S t . along the 1 , 2 , 3 , 9, lines; E a s t 1 8 t h S t . on the 4 , 5 , 6 ; W o r t h S t . on t h e 4 , 5 , 6 ; the old City Hall station on the 6 line; and M y r t l e A v e . on the B, D , N , and Q lines.
The Works
Moving People
Subway Token Timeline
The first token, minted by the IRT in 1928 in expectation of a two-cent increase, was never issued. The fare increase w a s overturned by the Supreme Court and the tokens w e n t into storage until 1 9 4 3 , when they were sold to the Hudson and M a n h a t t a n Railroad for their metal value.
Upon unification of the IND, BMT, and IRT systems in 1940, a transfer token was minted t o enable passengers t o move through a turnstile a t no additional cost on the second leg of their j o u r n e y by bus or subway.
The first full fare token debuted in 1953, when the Transit Authority was created. At 16 millimeters in width, it featured the u n u s u a l "y" c u t o u t . Fares stood at 15 cents through 1966 a n d then rose to 20 cents in 1970.
In 1970, a new, larger token — s t i l l with the "y" cut— was introduced for the fare
After 1 0 years, in 1980, the 23mm "y" cut was replaced with a solid brass
increase to 3 0 cents. This token survived the increase to 3 5 cents in 1973 and 50 cents in 1975 (despite an announcement, no doubt designed to avoid hoarding,
token (and a 60-cent fare). I t remained in use for
t h a t a new token would be introduced in 1975).
—I— 1930
Entering a Station Trains usually enter the station a t a b o u t 25 mph, under either a green or yellow signal. The train operator reverses the controller (motors r u n in reverse) to decelerate, and then employs air brakes to bring the train to a halt.
Be/ore opening the train doors, the conductor (generally in the center car) lowers the window and points his or her finger when the car is lined up with a mark at the center of the platform. If the train is not lined up properly, he or she calls the operator to adjust the position of the train before opening the doors.
The train doors remain open for at least 10 seconds, while the conductor makes any announcement over the public address system. Before closing the doors, he or she must also announce "stand clear of the closing doors, please." The back half of the train doors are closed first, followed by the / r o n t .
The conductor then signals the train operator that he or she can proceed. The conductor then visually inspects both front and back sections of the t r a i n to ensure t h a t no passengers are being dragged along by the train.
—I—r 1950
1— i960
only six years, during which time the fare jumped to 75 cents, 90 cents, and, ultimately, $ 1 . 0 0 .
Subway Announcements Although they are not always audible or intelligible, station announcements are an inevitable part of the subway experience. In general, announcements across the system are uniform: "Please do not hold train doors open"; "Due to a schedule adjustment, we are holding this train in the station"; or "There is a southbound train approaching 96th St." And with good reason: the Transit Authority's policy has been to provide only information needed to use the system wisely and "to cause minimal intrusion on our customers' right to think their own thoughts as they ride our trains." Ad-libbing, as it is referred to in the "blue book" of subway announcements, is frowned upon. However, in an attempt to be more customer-friendly, announcers are permitted to use their discretion in making the following announcements "in order to add just a touch of something extra": • The time of day: "Ladies and gentlemen, the time is three o'clock." • Patronage recognition: "Thank you for riding with MTA New York City Transit." • Or both: "Ladies and gentlemen, the time is three o'clock. Thank you for riding with MTA New York City Transit."
Gap fillers are used in stations with highly curved tracks, such as South Ferry, to bridge the space between the platform and the train car doors.
34
The Works
Moving People
Subway Beginning in the late 1990s, the MTA placed a series of orders for new subway cars to replace what subway followers know as the "redbird" fleet—some of which had been in operation for 50 years. Built by Kawasaki and Bombardier respectively in Yonkers
Dissecting the New Subway Car
and upstate New York, the first trains were placed into passenger service in 2000. To date, more than 1,500 new cars have been ordered; deliveries are expected to continue through 2006. The purchase of new trains is not as simple as it sounds. The maintenance shop
The t r a i n s cab is n o w wholly computerized. A single lever governs t r a c t i o n a n d braking; alongside it on the control stand are a reversing key, a keypad, and an LCD flat-panel display. These are used to control doors a n d display train data.
at East 180th St. in Manhattan had to be overhauled to accommodate new maintenance routines. Extensive testing of the cars was undertaken on the Dyre Avenue line in the Bronx before the cars could move into passenger service. And delivery of the cars themselves was complex: those in Yonkers moved by flatbed truck to the 207th St. yard in Manhattan, where they were loaded onto the track, while the Bombardier cars arrived from upstate New York by train over the Hell Gate Bridge to the New York and Atlantic Railway's Fresh Pond Yard in Queens.
The new cars have slightly squarer ends and feature clear windows, which allow passengers to see into the next car.
Cars have been designed with nothing below the seats, for easy sweeping and maintenance. A dark p a t t e r n — black with speckles—was chosen for the floor, to hide dirt.
While the new car is slightly smaller t h a n the old due to thicker walls, new lighting a n d the removal 0/ the backlit advertisements make it feel bigger. Shiny floors and the new color scheme also contribute to the feeling of a bigger space.
35
To improve access for wheelchairs, vertical poles between seats have been removed and a lift-up seat for wheelchair parking has been introduced. A ceiling-mounted bar was added to encourage taller people to hold on there, leaving room on the vertical poles for children and shorter people.
New LED signage appears both inside and outside of the cars. The outside signs indicate both t r a i n number and destination; on the inside, variable message signs and next-stop indicators provide useful in/ormation t o passengers.
Car bodies are all stainless steel. Passenger e n t r y doors a r e a full foot wider than they are in the preexisting fleet.
Retired Subway Cars
Subway
cars, once retired, are stripped of all asbestos and small metal items; handholds are removed and sold as memorabilia t o collectors. The hollowed-out car then meets an unusual fate: it moves by barge south along the Atlantic Coast to be dumped on artificial reefs off the coast of Delaware, S o u t h Carolina, Virginia, or Georgia. Bright-colored benches have replaced the traditional "scoop" seats. Front- and hack-facing seats are now opposite benches t h a t are parallel to the sides of the train.
Commercial fishermen are all too happy t o get the cars: the reefs—piles of armored personnel carriers, tanks, and demolition d e b r i s — a t t r a c t small sea mollusks and, in t u r n , increasingly large game fish.
Stainless steel cars, introduced in the 1980s to combat graffiti, scratched easily. Mélanine, a /ormicalike material, was reintroduced to hide scratches. In addition, a protective layer of replaceable film has been placed on window glass to prevent permanent scratching.
The Works
Moving People
Subway Signals and Interlocking
The subway-
train will the signal turn to green, enabling the next train
relies on a
to move on to that portion of track.
century-old system of signals, known as "wayside color-light
Control lengths and signal placements almost always
block signaling." Signals are located to the sides of the
overlap beyond the next signal, and are designed so that an
tracks and rely—much like traffic lights—on a system of red,
out-of-control train will stop before hitting something.
yellow, and green signals to determine safe passage. Unlike
Stopping relies on a system of automatic train stops, which
the street system, which relies on traffic lights changing
trip a train violating a signal. The trip stop is a T-shaped
on a predetermined schedule, subway signals are determined
metal rod, painted yellow, which goes up when a train runs
by a system of track circuits and blocks, which detect the
a signal. It engages a trip cock on the wheel frame of
presence of trains on various portions of track. And while
the train, which in turn cuts power abruptly to the engine
streetlights turn from green to yellow to red, subway signals
and applies the train's brakes in an emergency position.
go in reverse: from red to yellow, and from yellow to green.
All cars, not just the lead car of a train, are equipped with
There are essentially two types of signals that govern the operation of subway trains: automatic and approach
trip stops. Approach signals, in contrast, control the movement
signals. Automatic signals, the ones most frequently glimpsed
of trains across switches. They are generally characterized
by passengers riding on the system, are determined
by two sets of vertical displays—one stacked above the
"automatically" by the presence or absence of a train on a
other. These signals are not automatic: they are set at red by
length of track ahead. The distance along the track
a terminal operator in a remote control tower until he
measured by the automatic signal is its "control length."
or she determines that it is safe for the train to proceed
Only when the control length is fully clear of a previous
through an area where tracks merge.
Proceed: the next signal is clear.
Proceed with caution: prepare to stop a t next signal.
Stop: operate a u t o m a t i c
Approach a t the posted speed; continue on the main route. (A double signal generally has two sets of signal lights which control the movement of trains through switches and which are normally red until cleared by the tower operator.)
release, then proceed with caution a n d be prepared to stop within
Gap filler is extended. Stop a n d stay.
Gap f i l e r retracted. Proceed.
vision.
Wheel detector is on for the route. The switch is set t o the diverging route and the train speed is within the speed limit required. X LI4
37
These areas where tracks meet, join, or switch—known as "interlockings"—are among the most complicated parts of the subway's signal system. Historically, the operation of interlocking was done by machines with mechanical levers that remotely controlled track switches and signals; these levers were designed to physically "interlock" with one another to avoid unsafe track configurations. Levers that related to a particular set of switches at a crossover could be thrown from the normal position (go straight) to the reverse position (switch track) by an operator. Other levers could force signals to red, to accommodate a crossing train, but an operator could not force them to green: the lever could instead be set to "permit the signal to clear," if the automatic signal did not detect the presence of a train on nearby track. Interlocking technology remains at the heart of today's subway. Dozens of satellite towers house interlocking machines; in most cases, they are accompanied by a large model board displaying the track layout and featuring red lights to indicate the presence of trains on particular sections of track. To this day, tower operators have no automatic method of knowing which train is represented by the lights; train operators must push a "Train Identification Pushbutton" at the station located before an interlocking to request safe passage through the interlocking that lies ahead.
A Network of Control Towers Satellite offices, or " t o w e r s , " are responsible for controlling the subway's local switches and signals. Inside the towers, t r a n s i t personnel monitor train movement with the help of electronic maps linked directly to the subway's signal system.
A M a s t e r towers K Interlocking towers O Satellites
38
The Works
Moving People
Subway The subway system is, perhaps not surprisingly,
In general, subway
New York City's largest single electricity
trains are crewed
customer. Each year, it consumes some 1.8 billion kilowatt
by two people: a motorman, or operator, and
hours of power—enough to light the city of Buffalo for a
a conductor. The operator rides in the
year. Most power is provided by the New York Power
cab at the front of the train and governs the
Authority, which draws it from hydroelectric, nuclear, and
movement of the train along the tracks
fossil-fuel plants in New York State; a small amount is
and through stations. He or she is entirely
provided by the Long Island Power Authority for the part of
responsible for the safe operation of the
the subway system that operates on the Rockaway Peninsula.
train when it is moving.
Like the signal system, power delivery to the subway has changed little in concept since the system opened in 1904.
The conductor, in contrast, rides in the middle of the train. He or she is responsible
Alternating current is sent from generators along high-
for the opening and closing of the doors
tension cable to 214 substations along the various routes.
of the train at stations and announcements.
There it is changed from alternating current to direct
The conductor indicates to the operator
current (625V) and fed—via 900 miles of heavy traction
when the train is appropriately aligned upon
power cables and 1700 circuit breakers—onto the third rail.
arrival at a station and is in charge of
Every train has a "shoe" connected to the third rail,
announcements relating to the boarding and
which picks up the electricity and allows the train to move.
exiting of passengers.
A separate system of power, involving an additional 1,600 miles of cable, provides alternating current to signals, ventilation and line equipment, and station and tunnel lighting. By separating the two systems, the lights remain on when power to the third rail is cut off and vice versa. The amount of power provided to the system is largely
Making It as a Motorman Only recently has anyone other than a subway employee been able to apply to drive
a function of the distance covered by a particular line. Trains
an NYC subway train. A t a t e s t given in
draw power according to their operational needs. Express
November 2 0 0 3 , some 1 4 , 0 0 0 people showed
trains generally travel at speeds averaging 25 miles per hour.
up a t 1 4 locations across the city to
Local trains operate at approximately 15 miles per hour
compete for about 3 0 0 train operator jobs.
on average below 96th St., and at 18 miles per hour above it
The t e s t itself had 7 0 questions and
due to the greater distance between stations.
took about three and a half hours to complete. Sample questions included:
Daily Power Usage 1 . Safety rules are most M a x i m u m power demand 8:30 a.m.
useful because they: a. Make it unnecessary to think b. Prevent carelessness c. A r e a guide to avoiding common dangers d. Make the worker responsible for any
39
Inside the cab The train status panel, located in front of the operator in the cab, provides information about all aspects of the tram's operation, including location, all aspects of maintenance, the status of communication and signage, power and braking systems, and trouble indicators. The control panel includes a lever t h a t governs the train's movement.
2. The maximum speed permitted when a t r a i n is passing through a passenger station without stopping is: a. 5 mph b. 1 0 mph c. 1 5 mph d. Series speed
3. Third rail power is used to operate the: a. Compressors b. Emergency car lights c. Motorman's indication d. Conductor's signal lights
•e •£
'o -g
' 3 'l
:SJ3AASU\/
Subway For a century-old system, New York's subways are pretty reliable. The "mean distance between failures"—the distance
The Emergency Brake
a car travels on average between
There are a number of situations t h a t
breakdowns—averages over 100,000 miles.
can trigger deployment of a train's
Nevertheless, there is hardly a subway rider
emergency brake. In any of these
who has not experienced at least one
cases, a vent is opened, leading to a
breakdown in his or her mass transit career.
reduction in brake pipe pressure
When such an incident occurs, a standard
(normally at 1 1 0 psi); this triggers
set of procedures is followed:
the immediate application of
1. The Subways Control Center is notified,
The train operator can manually t u r n the brake valve to the emergency position.
electropneumatic friction brakes.
generally by a portable radio carried by train staff. The notification would include the train's "call signs" (e.g., "1427 C 168th St./Euclid" is the call sign for a train that departed 168th St. at 2:27 p.m. and is destined to terminate at Euclid Ave.), its location, and a description of the problem (often coded). 2 . Subways Control Center notifies the local satellite tower and the tower begins rerouting service around the
Emergency Codes
delayed train. Rerouting directions are
conditions are readily identified by subway radio code:
A t least 1 1 emergency
a function both of the layout of the tracks in the area around the incident
12-1
Emergency—clear the air
and of the location of switches
12-2
Fire or smoke on train or roadbed
enabling diversion from one set of
12-3
Flood or serious water condition
tracks to another.
12-5
Stalled train
For many problems, particularly
12-6
Derailment
in heavily trafficked corridors, there are
12-7
Request for assistance
predetermined detour routes. For
12-8
Armed passenger
example, a problem on the A or C line
12-9
Passenger under train
in lower Manhattan would result in
12-10
Unauthorized person on track
all A and C trains being diverted to the
12-11
Serious vandalism
F line between J a y St. in Brooklyn
12-12
Disorderly passengers
and West 4th St. in Manhattan.
41
/
The passengers or conductor can
The t r a i n operator could become
The trip cocks on an individual
pull the emergency brake cord located
incapacitated and fail to keep
could strike an object on the tracks.
inside each car.
the master controller lever depressed (the "dead man's"
Rerouting a Train
feature).
New York is
fortunate to have a subway system generally comprised of three or four tracks. Should there be a problem on the C line, for example ("Control 1 4 2 7 Charlie 1 6 8 to Euclid is at 8 1 s t S t . experiencing a door malfunction"), the nearest switches—in this case at W e s t 1 2 5 t h S t . and W e s t 5 9 t h St.—would be identified. The local tower, at 5 9 t h S t . , would reroute all service from the local track to the express track at 1 2 5 t h S t . A t 5 9 t h S t . , local trains would switch back to the local track.
car
42
The Works
Moving People
Subway
'
2 4 0 t h St,
Pelham
Shops and Yards In
1 7
Keeping subway cars moving around the
Z
2 3 9 t h St.
207th
clock requires a far-flung network of support
Westchester(
services, including subway storage yards and maintenance shops. Thousands of Transit Authority employees in the Car Maintenance Department are responsible for regular inspection of the cars at the 13
addition to repair shops, the system features 21 subway yards spread out across the network. Some of these are near or adjacent to shops; others are situated remotely but serve as staging or parking areas for subway cars not in use.
maintenance shops in Manhattan, Brooklyn, Queens, and the Bronx. Cleaning and repair also occur at these shops. In addition, two overhaul shops are used for major repairs and car rebuilding: the Coney Island shop in Brooklyn and the 207th St. shop in Manhattan. The overhaul shop at Coney Island, for example, operates 24 hours a day to provide repair services to both the Transit Authority and to the Staten Island Rapid Transit Fleet.
Keeping subway tracks dry is key to the smooth running of the system. Each day, 309 pump plants—with a total of 748 pumps—remove up to 13 million gallons of rain and other water from the subway system. Fed by a system of drains running under the tracks, they pump water into a manhole under the street that empties into the city's storm-water system. Flooding can, however, occur for a variety of reasons. Sometimes debris blocks the drain along the tracks. Other times the pipes leading from the drains to the pump rooms are overwhelmed with the volume of water that builds up on the track. To minimize failures, the TA is in the process of installing wider inlet pipes and placing slatted boxes over the track drains to better protect them from blockage.
/
43
Passenger cars make up the bulk
through stations to provide basic collection services. Others,
of the Transit Authority's fleet—
like snow blowers and tank cars, are rarely seen inside
close to 6,000 in all. But there are another 350 or so rail cars
the tunneled portion of the network. And still others—weld
that are largely hidden from public view, without which
cars, crane cars, and signal supply cars, among others—
the entire system would come to a screeching halt. Some of
are part of the fleet responsible for repair and maintenance
them—for example the refuse and revenue cars—move
across the system.
Revenue Collection Cars There
Crane Cars These cars are
generally
are 10 two-car trains that move
used to carry, lift, or unload
sections
through the stations collecting
fares
Flat Cars These cars generally
haul
machinery and other equipment to
of track being replaced but also may
and from work sites. They can carry
from the station booths.
be used to lift equipment such as
loads up to 3 0 tons.
These trains will soon be phased out
generators and track ties. They are
and replaced by armored
trucks.
Signal Supply Cars These cars are equipped with cranes to remove existing signals from the track and install new signals, and are generally
generally
pulled by locomotives.
Tank Cars These cars are used t o carry liquids a r o u n d t h e subway system. They are
generally
pulled by locomotives.
pulled by passenger cars.
The Vacuum Car Among the most unique of the specialized subway cars is the vacuum car. Weighing several tons and costing roughly $ 1 5 million, it sucks in 7 0 , 0 0 0 cubic feet of air per minute in a never-ending battle to keep the subway tracks clean. Carefully
Weld Cars These are retired passenger cars t h a t are designed to
Locomotives Locomotives pull nonpowered
cars and crane cars, to and from
transport them to areas where they
job sites. Sixty-two are diesel electric
will he installed on the track.
designed to steer clear of small,
work cars, such as flat
carry eight 3 9 0 / o o t rails and
locomotives, and ten are
electric.
heavy objects Clike track ballast), it is estimated to have picked up more than five million pounds of debris in the last two years alone. B u t even a s m a r t machine like this one needs help at times: an advance team is sent out along the track ahead of the vacuum to pick up larger
Snow Blowers These cars
Ballast Regulators These cars
items, such as shoes, cell phones,
are equipped with a jet engine to blow
spread ballast on the tracks after
snow off the tracks. They require
it is dumped. They feature a rotating
and cosmetic bags, t h a t might
two locomotive escorts as the u n i t is
broom which distributes ballast
not be so easily digested by it.
too short for the signal system t o
and sweeps excess ballast onto a
recognize its presence on the track.
conveyor for removal.
44
The Works
the Port Authority of New York and New Jersey, the Metropolitan Transportation Authority (MTA), DOT, New York State Department of Transportation, New York City Department of Environmental Protection (DEP), Amtrak, and the New York City Department of Parks.
New York's fabulous harbor and multiple waterways once made it a center of trade, but
Nearly all of the city's major bridges—and several of its tunnels—have broken or set records. The Holland Tunnel was the world's first vehicular tunnel, when it opened in 1927. The George Washington and Verrazano Narrows
today they make it a city of bridges
bridges were the world's longest suspension
and tunnels. Over 2,000 of them provide
bridges when they opened in 1931 and 1964
uninterrupted vehicular movement
respectively; likewise, the Bayonne Bridge,
throughout the region. Seven agencies claim
a steel arch structure connecting Staten
jurisdiction over this web of crossings:
Island with Bayonne, New Jersey, was very briefly the longest of its type.
Bridges & Tunnels
New York's crossings date back to 1693, when its first bridge—known as the King's Bridge—was constructed over Spuyten Duyvil Creek between Manhattan and the Bronx. Composed of stone abutments and a timber deck, it was demolished in 1917. The oldest crossing still standing is Highbridge, which connects Manhattan to the Bronx over the Harlem River. Never designed to carry vehicles, it was opened in 1843 to carry water to the city as part of the new Croton Aqueduct system. Ten bridges and one tunnel serving New York City have been awarded some degree of landmark status. The Holland Tunnel, operated by the Port Authority of New York and New Jersey, was designated a National Historic Landmark in 1993 in recognition of its pioneering role in vehicular tunnel technology. The George Washington Bridge (another Port Authority facility), Highbridge
In 1927, after seven years of construction, the Holland Tunnel— the first mechanically ventilated vehicular underwater tunnel—opened. The toll w a s 5 0 cents.
More t h a n 1 4 , 4 0 0 miles of steel cable
(operated by DEP), and the Hell Gate
were used in the construction of
Bridge (operated by Amtrak) have also been
the Brooklyn Bridge, which opened to
made landmarks. So too have seven other
great fanfare in 1883.
bridges under the control of New York City
Manhattan's Crossings
DOT: the Queensboro, Brooklyn, Manhattan, Macombs Dam, Carroll Street, University
Henry Hudson Bridge
Heights, and Washington bridges. Today, the 14 major bridge and tunnel crossings that connect the city to its neighbors account for millions of vehicle passages each day. The busiest—the George Washington Bridge, the Verrazano, and
The Alexander Hamilton Bridge, which forms part of Interstate 95, handles more t h a n twice the vehicular traffic of any other Harlem River crossing.
Broadway Bridge
University Heights Bridge
the Triborough—were all designed by one man: an engineer named Othmar Amman.
Washington Bridge
(Amman also designed the Whitestone and Throgs Neck bridges and the Lincoln Tunnel—making him something of
Macombs Dam Bridge
The George Washington
a father figure in New York City civil engineering circles.)
Bridge handles roughly 3 2 0 , 0 0 0 vehicles each day—more than any other crossing in the region—and takes in approximately $ 1 million per day in tolls.
145th Street Bridge ^ HI
Madison Avenue Bridge Third Avenue Bridge Willis Avenue Bridge Triborough Bridge
The Lincoln Tunnel
ii
E-ZPass
Jj
J
carries roughly 50 percent more traffic than the Holland, offering 13 toll lanes to the Holland s nine.
With close to 2 0 0 , 0 0 0 vehicles each day, the ^ Queensboro Bridge is the busiest East River crossing.
Queens Midtown Tunnel E-ZPass is an electronic toll
collection system now operating in eleven states in the Northeast and Midwest. Participating vehicles are equipped with a small electronic tag t h a t transmits data Williamsburg Bridge
to a remote computer at a customer service Holland Tunnel
center in S t a t e n Island. The data are processed and a toll is automatically deducted from the driver's prepaid account.
Manhattan Bridge
E-ZPass has been wildly successful since its introduction in 1 9 9 3 and is now in operation at all MTA and P o r t
Authority
bridges and tunnels in the region.
Inbound
Outbound
The Brooklyn Bridge is the oldest, and by far
over 1 0 0 , 0 0 0
the busiest, of the four
80,000-100,000 60,000-79,999 40,000-59,999 20,000-39,999 10,000-19,999 below 1 0 , 0 0 0
lower M a n h a t t a n bridge Brooklyn Battery Tunnel
crossings to Brooklyn.
46
The Works
Mouing People
Bridges & Tunnels Bridge Types
Cantilever bridges exhibit a lacy superstructure of rods, plates, girders, and cross braces to support the bridge deck. The Queensboro Bridge is a notable example of a cantilever truss bridge here in New York.
Girder span bridges are used to bridge relatively short distances. The steel girders carry the roadway load to supports a t each end of the bridge.
Suspension bridges depend on large cables t h a t are s t r u n g over a
Trestle bridges are supported by a series of connected pilings or beams.
pair of towers and anchored to shoreside blocks of concrete. Suspender cables are hung from the primary cables to hold the roadway. The George Washington, Verrazano, Brooklyn, M a n h a t t a n , and Williamsburg bridges are all notable New York City suspension bridges.
Steel arch bridges are made up of one or more arches made out of concrete or steel. Only one steel arch bridge is under city control: the
Truss bridges are characterized by road decks supported by steel trusses t h a t rest on piers and abutments.
Washington Bridge over the Harlem River, which is constructed / r o m twin steel arches.
New York features a variety of bridges—
functional. Consider the Williamsburg Bridge, for example:
of all lengths and types, carrying everything
its two heavy rail transit tracks carry tens of thousands
from cars, trucks, and subway trains to bicycles and
of people each day on the J , M, and Z subway lines; its eight
pedestrians. Technically, a bridge is denned as a structure
traffic lanes support over 140,000 vehicles a day, and its
that spans a distance greater than 20 feet. According to
sidewalk provides service to about 500 pedestrians each day.
this definition, the longest municipally owned bridge is the
In total, roughly 2,000 bridges dot the landscape of
Gowanus; the longest railroad-owned bridge is the elevated
the city, over 700 of them under the responsibility of New
tracks in the Bronx by Yankee Stadium.
York City's DOT. Twenty of these connect boroughs; the
But the bridges that New York City is famous for are not
remainder are somewhat evenly distributed across them.
those over land, but rather those that connect its islands. The
Within this total are 25 movable bridges whose openings
Verrazano Narrows Bridge, the George Washington Bridge,
are governed by Coast Guard regulations and organized by
and the Brooklyn Bridge are considered among the most
means of two-way radios or a telephone call to the DOT's
beautiful in the world. Others fall into the category of the most
Division of Bridges.
47
Movable Bridges
Retractile bridges are mounted on tracks alongside a navigable waterway and are "retracted" when a ship needs passage. They were popular in the nineteenth century for narrow crossings requiring maximum horizontal clearance. The Barden Avenue and Carroll Street bridges are examples of retractile bridges.
Swing bridges are supported by a central pier situated in the water. The bridge is opened by r o t a t i n g it horizontally along wheels on a circular track, and in its open position it forms two separate channels for passing vessels. The Third Avenue, Madison Avenue, and Macombs Dam bridges are all examples of this type.
/
L
r/M/M/M/M
\
l/l\l/!\l/M7FJ Bascule bridges, also known as drawbridges, rely on counterweights to vertically lift two spans. The Pelham, Hamilton Avenue, and Greenpoint Avenue bridges are all bascule bridges.
Vertical lift bridges are movable bridges with roadways t h a t can be raised in an elevatorlike fashion. This is accomplished through a system of attaching supporting end cables to rotary drums in towers on the sides of the waterway. The 103rd Street Bridge, Ward's Island Foot Bridge, and Roosevelt Island Bridge to Queens are examples of vertical lift bridges.
Most Frequently Opened Bridges (1988-2002) £
Shore Road-Pelham Parkway (B
Q
Hamilton Avenue (Brooklyn)
Q
Ninth Street (Brooklyn)
Q
Greenpoint Avenue (Brooklyn/Queens,
Q
Metropolitan Avenue (Brooklyn)
0
Bruckner Expressway (Bronx)
Q
Pulaski (Brooklyn/Queen
Q
Third Street (Brooklyn)
0
Mill Basin (Brooklyn)
^
Carroll Street (Brooklyn)
• •
land bridge waterway brit
•
railroad bridge
•
movable bridge
New York City's Bridges
48
The Works
Moving People
Bridges & Tunnels Brooklyn Bridge The Brooklyn Bridge is the oldest suspension bridge in the harbor. When built, its towers were the tallest structures in lower M a n h a t t a n . I t opened to g r e a t fanfare
in 1883, having cost
j u s t over $ 1 5 million and 20 lives.
l 8 9 0
Williamsburg Bridge In contrast to the Brooklyn Bridge, which took 13 years to build, t h e Williamsburg Bridge was built in seven—opening to traffic in 1 9 0 3 . I t s main span l
(1,600 feet) and height (135 feet above
9°^
mean high water) are almost precisely those of its sister to the south.
Queensboro Bridge The Queensboro Bridge, the only major cantilever bridge in the region, was opened in 1909. It was originally
I 9 I (
j
configured
to accommodate two elevated railway lines and two trolley lines— both 0 / w h i c h were eventually removed—as well as a marketplace on the M a n h a t t a n side tiled in Gustavino tile, the same tile found in Grand Central Terminal's famed Oyster Bar.
Bayonne Bridge The Bayonne Bridge is one of the longest steel arch bridges in the world, with a midspan clearance of 151 feet. The hyperbolic
193°,
1,675' •
curve arch over the roadway is complemented by steel trusses placed in a triangular
pattern.
George Washington Bridge The George Washington Bridge opened in 1931 with one deck, though it
I
9
4
-
1
9
5
-
was designed to handle a second level to c a r r y either rail traffic or additional road traffic. In 1962, t h e second level was eventually completed—for vehicular traffic only. Today, its 14 lanes make it one of the world's busiest suspension bridges.
Verrazano Narrows Bridge When it was opened in 1964, t h e Verrazano Narrows Bridge w a s t h e longest suspension bridge in t h e world. At 228 feet above the water, it
I 9
6o
also s a t higher t h a n a n y other bridge in the harbor; indeed, its towers were so high and so widely
spaced
t h a t its builders had to account for the c u r v a t u r e of the e a r t h s sur/ace, which is w h y the t o w e r s ' tops a r e 1 5 / 8 " / a r t h e r a p a r t t h a n their bases.
I 9 7 G
1 1I 1 1 1 1
1,000'
I
1 1 1 1I 1 1 1 1
2,000'
I
1 1 1 1I 1 1 1 1
3,000'
I
1 1 1 1I 1 1 1 1
4,000'
I
1 1 1 1I 1 1 1 1
5,000'
I
1 1 1 1I 1 1 1 1
6,000'
I
1 1 1 1
7,000'
49
Screen shot of George Washington Bridge a n d approach road speeds
Bridge Operations
Few New Yorkers appreciate how complex operating
a bridge can be. Take the George Washington Bridge, for example. Its operations center collects information from • 159 radar detectors, which detect vehicle volume, occupancy of portions of the road, and speed; • 39 cameras, which provide a real-time look at the bridge's roadway conditions; • pavement sensors in the asphalt, which show
The Naked Bridge
Although the George
Washington Bridge is by no means t h e longest suspension bridge in the world, it remains among the most robust. It contains 1 1 3 , 0 0 0 tons of fabricated steel and 1 0 6 , 0 0 0 miles of steel cable wire— almost half the distance to the moon. But the most unusual fact about the George, as she is affectionately called, is not her size or her strength; it is her appearance, which is something of a historical accident. The original design for the
temperature, icing conditions, freeze point, and road surface information; • wind speed, air temperature, and visibility sensors, which indicate dangerous conditions; • Highway Advisory Telephones and call boxes, which provide highway and roadway information; • Variable Message Sign (VMS) sensors, which show travel times but also indicate which of the signs' pixels and fans are (or are not) working. In addition to staff at the bridge's Operations Center,
bridge saw her towers cloaked in masonry. But once
84 full-time and 23 part-time toll collectors are on hand to
partially built, the awesome skeletal beauty of
collect tolls from drivers who don't use E-ZPass. In total,
the s t r u c t u r e — a s well as t h e cost of continuing
it takes 300 people to keep the elegant bridge working.
construction—staved off the concrete cladding. By 1 9 3 1 , the Depression was in full force and the bridge's sponsor—the P o r t Authority—opted to leave the bridge half dressed, bringing construction in under the original $ 6 0 million cost.
The Works
Moving People
Bridges & Tunnels Bridge Maintenance
Just like
pedestrian and railroad bridges, state law requires that all vehicular bridges be
Bridge Cleaning and Maintenance
inspected every two years. Inspection is largely visual: technicians ride along the bridge undersides in motorized "travelers" looking for cracks, rusting, and corrosion or, alternatively, watch from the ground as trucks traverse the bridge. They may also strike the bridge with hammers, listening to vibrations from the concrete or steel. More sophisticated instruments—such as X-ray, laser, and acoustic devices—may be used to identify particular problems. Inspection of a major bridge can involve as many as 50 people and take up to three months. Each inspection results in a bridge rating on a scale of 1 to 7; a rating of lower than 4 justifies inclusion in DOT's capital plan. A "flag system" is used to identify the existence of conditions that pose or could present a danger:
Cleaning of expansion joints Expansion joints, located a t a bridges surface level, are subject to a variety of elements: water, ozone, dust, and dirt, as well as to chemicals in salt products a n d gasoline. Preventing penetration of these is achieved by using compressed air and water to remove debris before cleaning a n d resealing the joints.
Snooper truck A snooper truck, which remains on the bridge deck, has a mechanical boom with a bucket or platform and is used to give access to the underside of a bridge in situations where a ladder or bucket truck are insufficient.
• A red flag is used to report the immediate failure of a critical structural component. Red flags must be addressed within six weeks. In 1988, for example, inspectors found the Williamsburg Bridge so crippled with rust that it was closed for two months for emergency repairs. • A yellow flag is used to report a hazardous condition or the imminent failure of a noncritical component (one whose failure would not result in structural collapse). • A safety flag is used to report a condition that presents a vehicle or pedestrian hazard, but that is not likely to result in any loss of reserve capacity or redundancy for the bridge. A missing railing or loose piece of concrete, for example, would warrant a safety flag.
Bucket truck To get a close look a t a bridge's underside, maintenance crews use a specialized truck with a n articulated a r m t h a t can curve u n d e r n e a t h the s t r u c t u r e .
Debris removal Debris can cause hazardous conditions on bridges; it also traps moisture and salt on the structure a n d can block proper drainage. Debris ranges from rocks to mufflers and wheel covers to paper, bottles, and cans.
Paint removal and repainting Paint removal is accomplished through abrasive blasting, but a containment area (including tarps, sca//olding, and cables) must be set up first. Three coats of lead-free paint are generally applied: t h e primer, intermediate, and top coats.
Cleaning of drainage systems The cleaning of surface gratings, gutters, and downspouts calls for brooms, brushes, and a variety of other hand tools. Occasionally a n air compressor will be needed to thoroughly empty certain g u t t e r s .
Paving Wbrn surfaces, which are usually made of a two-inch slab of bituminous concrete, are replaced and the roadways
repaved.
Spot painting Surface contamination
Mechanical sweeper Mechanical
De-icing De-icing trucks are used to
due to corrosive objects such as de-icing salts, bird excrement, or
sweepers move along the curb of the
spread abrasives and chemicals on road surfaces to prevent them from freezing over and causing unsafe driving conditions.
sea salt is generally removed by power washing with clean w a t e r or steam. Areas containing deteriorated paint are generally cleaned with hand tools.
bridge deck to remove dust and debris.
The Works
Moving People
Bridges & Tunnels In contrast to New York's bridges, lauded
first trans-Hudson rail tunnel had opened as early as 1910,
in song and poetry, New York City's
the larger size demanded by vehicular tunnels, coupled
tunnels merit little attention.Yet the four vehicle tunnels
with the need to remove vehicle exhaust, presented more
that connect Manhattan with Long Island and New Jersey
substantial challenges to builders. The system developed
—the Brooklyn Battery, the Queens Midtown, Holland,
for the Holland Tunnel in the late 1920s—a two-duct system
and Lincoln tunnels—are a critical part of managing the
that relies on one duct to draw in fresh air and the other
flow of people into and out of the city every day. The tunnels that run under the East and Hudson rivers
to suck out exhaust—would be adopted by vehicular tunnels worldwide and is still in operation today.
were marvels of engineering in their day. Although the
Tunnel Profiles length in feet
^
I The Brooklyn Battery Tunnel When it opened in 1950, the Brooklyn Battery Tunnel was, a t 9,117 feet, the longest continuous u n d e r w a t e r vehicular tunnel in the world— a title it still holds. Two ventilation buildings in lower M a n h a t t a n , one in Brooklyn, and a fourth off Governors Island change the air in the tunnel every 90 minutes.
) The Queens Midtown Tunnel The Queens Midtown Tunnel was opened in 1940 to relieve congestion on the city's East River bridges. Each of its tubes was designed one and a half feet wider than the Holland Tunnel in order to accommodate the wider cars of that period, and its m a x i m u m roadway gradient is 4%. The tunnel serves as the westbound terminus of the Long Island Expressway.
) The Holland Tunnel The oldest of the region s vehicular tunnels, the Holland Tunnel connects Canal St. in M a n h a t t a n with 12th and 14th streets in Jersey City. Opened to great fanfare in 1927 as the first mechanically ventilated underwater vehicular tunnel, it was designated a National Historic l a n d m a r k in 1993.
53
The Brooklyn Battery Bridge Proposals for a tunnel between B a t t e r y Park and the Red Hook section of Brooklyn were approved by the city in 1 9 3 0 , but were put on hold with the onset of the Depression. Very keen to see the tunnel built, M a y o r LaGuardia turned to Robert Moses—whose Triborough Bridge A u t h o r i t y was running a surplus—to fund, construct, and operate the new crossing. N o t nearly as passionate about tunnels as he was about bridges, M o s e s changed the plan for a six-lane tunnel to a six-lane bridge crossing; it would be cheaper to build and operate, carry more traffic, and almost certainly be more monumental. The new Brooklyn B a t t e r y Bridge would be a twin suspension bridge, held together by a central anchorage at Governors Island and connecting with the W e s t Side Highway via a low-level causeway near Battery Park. Notwithstanding the support of the City Planning Commission, Moses's bridge proposal ran into strong opposition both locally and in W a s h i n g t o n . In July 1 9 3 9 , Franklin Roosevelt's secretary of war put an end to the project, claiming t h a t the proposed bridge would be vulnerable to attack and would block access to the Brooklyn Navy Yard, ^
The Lincoln Tunnel The Lincoln Tunnel consists of three tubes t h a t link midtown M a n h a t t a n with Routes i and 9, Route 3, and t h e New jersey Turnpike in New Jersey. The three-tube con/iguration o//ers the /lexibility to provide / o u r lanes in one direction during rush hour or three lanes in each direction.
giving life once again to the idea of a tunnel.
54
The Works
Moving People
Bridges & Tunnels
Inside the Holland Tunnel
Exhaust a i r moves through a duct on the tunnel ceiling. The air is changed every 90 minutes.
The tile finish requires c o n s t a n t cleaning. An estimated / o u r million tiles were installed when the tunnel's ceiling was replaced in t h e late 1980s.
Ventilation buildings, the most visible parts of New York tunnels, are generally located on land on either side of the tunnel. The Holland Tunnel has / o u r , which together contain 4 2 / a n s (28 0/which are in operation a t any one time) responsible for blowing fresh air into the tunnel through a duct below the roadway. Each fan is 80 feet in diameter.
The tunnel's outer ring is composed of 1 4 - 1 5 cast iron sections—18"x 3 ' — bolted together. The seams are staggered for greater strength.
Water moves out of the t u n n e l roadway through a system of curb drains. .Most w a t e r leaks in the tunnel occur on land as a result of g r o u n d w a t e r penetration or broken w a t e r mains.
The Exclusive Bus Lane (XBL) Perhaps no
^
•A
-i
~-r:... .
4C4DEMY
M. » JÊÈM
•
IHHG3B1
the New Jersey Turnpike, converted to eastbound use during weekday
aspect of regional traffic management
morning peak periods. Over 1 0 0
is as unfamiliar to New Yorkers
different bus lines, numbering 1,700
as the Exclusive Bus Lane (XBL),
or so buses, use the lane each day.
which provides access to the Lincoln
An estimated 6 0 , 0 0 0 commuters
Tunnel for city-bound commuters
save somewhere between 1 5 - 2 0
from New Jersey. The XBL is actually
minutes in travel time, compared with
a 2.5-mile-long s t r e t c h of a
the normal congested Route 4 9 5
westbound lane, from the tunnel to
approach to the tunnel.
55
Tunnel Maintenance
New York State law does
looking for cracks or missing chunks of concrete, broken
not require specific
bolts, and water seepage or leaks. Inspectors will tap
repair or maintenance procedures for tunnels. However,
the concrete with a hammer, called "sounding," and listen
tunnels coming into the city are regularly inspected for
to the echo. Inspections go beyond the tunnel itself to
structural integrity by either the MTA or the Port Authority.
include ventilation and service buildings as well as ancillary
In the case of the Port Authority, comprehensive tunnel
structures such as retaining walls and pump rooms.
inspections are undertaken by outside consultants every
In addition to inspections, the tunnels require a sizable
two years to ensure structural integrity and as a
retinue of maintenance staff who carry out daily cleaning,
supplement to annual routine inspections. Deficiencies
repair, and maintenance work. The Holland Tunnel,
are generally classified as high priority, priority, routine
for example, maintains a staff of 83; the Lincoln requires 79.
priority, or routine—and addressed accordingly. To inspect tunnels, inspectors crawl through the system
Personnel service costs for each of these tunnels on an annual basis exceed $4 million.
Tunnels need to be cleaned regularly; the Holland Tunnel, with one of the lowest clearances, will t u r n black from truck exhaust in j u s t two days. Giant electrical toothbrush trucks, sporting arms with rotating brushes, move through the tunnel three to four times a week. They rely primarily on w a t e r for cleaning, to avoid any environmental concerns.
Cities are great consumers of goods, and nowhere is that more true than New York. Each day, hundreds of millions of dollars' worth of goods moves into the region by ship, rail, air, or truck—much of it destined for the city Though largely taken for granted, trade is as important to life in New York today as it was when the city was founded. Yet the physical manifestations of trade are now all but invisible to most New Yorkers; gone are the docks and wharves pulsing with exotic cargos. Today, trade moves much more quietly—and much more efficiently— through the region's port and airport facilities, through half a dozen rail freight yards, and through a handful of wholesale markets. The occasional sight of a cargo ship steaming into port or a freight train running down the Hudson belies a complex system of transportation logistics that underpins the commercial life of the city
another, the "merchandise trains" destined for New York contain a mix of commodities coming from numerous producers and earmarked for dozens of consumers. These freight trains—some up to 120 cars in length—are environmentally friendly.
Each week, roughly 1,750 railcars move through the metropolitan regiona small but important
On average, each train replaces 280 trucks that would otherwise be making the same journey. Unfortunately there are not more of them: rail cargo today makes up only about 5.6 percent
part of the regions freight lifeline. Each of
of the freight moving through the region,
these railcars represents a shipment loaded
down from a high of roughly 40 percent
hundreds or thousands of miles away
in the early 1940s. The drop in rail traffic is
and destined for consumers in the New York
in part a reflection of the region's appetite
area. Unlike "unit trains" made up of a
for imports, but also a function of
single commodity moving from one place to
increased competition from long-distance trucking industries. The fact that rail has survived at all is due
Rail Freight Reinventing the High Line One of the most talked-about relics of New York's rail freight era is M a n h a t t a n ' s High Line, a 1.5-mileîong, 3 0 / o o t - w i d e elevated rail deck r u n n i n g from West 34th St. to Gansevoort St. Now due to become a linear park, it was built in the 1930s as a n attempt to reduce congestion on 10th Ave. For 3 0 years, the High line brought food and merchandise into M a n h a t t a n — u n t i l improvements in highways led to a falloff in rail freight in the early 1960s.
in part to a largely successful intervention on the part of the federal government over 25 years ago. Once the primary means of moving goods from the west, rail service had deteriorated so badly by 1976 that Washington, D.C., stepped in to create the Consolidated Rail Corporation (Conrail) out of the bankrupt Penn Central Railroad and five other struggling lines in the Northeast. Roughly $7 billion of taxpayers' money was invested in trains and track repair, and in 1987—after some reasonable success—Conrail was sold to the public. With a monopoly on freight traffic into and out of the metropolitan region, the company proved an attractive target for both Norfolk Southern and CSX railroads and the two railroads jointly purchased Conrail in 1999 for $10.3 billion. Although Conrail continues to exist today as a subsidiary of both companies performing switching services at local yards, most Conrail assets were divided up between the two railroads.
•ak Point Yard
Harlem River Yard
Fresh Pond Yard
South Brooklyn Marine Terminal
\
65th Street Yard
Brancn
Today, the New York-New Jersey region
serving businesses requiring carfloat service;
supports more than a dozen rail terminals,
the South Brooklyn Railway, serving NYC
served by three major railroads: the
Transit's needs; the Providence £r Worcester
Canadian Pacific, handling traffic to and
Railroad, running from the region to
from eastern Canada, and CSX and Norfolk
parts of Connecticut, Rhode Island, and
Southern, both of whose routes lie
Massachusetts; the New York Susquehanna
primarily to the south and Midwest. They
and Western, serving traffic between
are supported by seven smaller regional
upstate New York and New England and the
or terminal railroads: the New York and
mid-Atlantic region via a connecting line
Atlantic, serving Long Island's freight
around New York City; and the Port Jersey
customers; Express Rail, serving port users;
Railroad, providing local switching
the New York Cross-Harbor Railroad,
services in northern New Jersey.
Rail Freight There are roughly 1.3 million railcars in the United States, of varying shapes and sizes. Many are highly specialized, designed to carry lumber, chemicals, forest products,
Boxcar A boxcar is a fully enclosed car used to t r a n s p o r t commodities.
or autos, for example. Others are variations
Gondola car A gondola car is a low freight car with a flat bottom, fixed sides, and no roof. It generally carries bulk goods such as
on standard "hopper" or "gondola" cars.
stone or steel.
Hopper cars generally handle dry bulk commodities impervious to weather conditions—stone, gravel, or coal, for example; gondola cars, either covered or open, are used to ship heavy or bulk products such as scrap metal, steel, wood chips, and aggregates. Refrigerated cars, with diesel-powered cooling units, are used
Tank car Tank cars are used to t r a n s p o r t liquids, compressed or liquefied gases, or solids t h a t are liquefied before unloading.
to meet the long-distance travel
Covered hopper car Covered hopper cars are used for handling bulk commodities t h a t can't get wet. They have openings for either top or side loading.
requirements of fresh or frozen products. Regardless of type, all railcars carry markings on their flanks. Generally these will include the car number, the railroad
::::::
trademark or logo, and the name or initials
\ "7
of the car s owner. They will also carry abbreviations referring to their cubic and weight capacity, length, width, height, and date built.
Trilevel auto car A trilevel a u t o car consists of a three-level steel rack t h a t holds 12 standard sedans or 15 compact cars.
Floats No More
Prior to
Refrigerator car Also known as a "reefer, " a refrigerated car is used to move goods needing refrigeration. Before the era of gas-powered coolers, these cars were loaded with ice.
2 , 0 0 0 cars each year between
the opening of the Holland Tunnel
South Brooklyn and Greenville Yards
in 1 9 2 7 , nearly all domestic freight
in Jersey City—about the same
destined for New York terminated
amount t h a t was handled each day in
its rail journey in New Jersey. From
1 9 6 5 . Between 15 and 2 0 railcars
there, it crossed the river on cargo
can be ramped from the shore onto
ferries or on carfloats, barges
tracks on a waiting barge, which
specially outfitted with rail tracks
is hauled by a tug across the river to
for cargo moving from one rail system
an unloading yard.
to another. A t one time, dozens
M o s t cargo, primarily for Long
of carfloat bridges existed along
Island customers, is of the "not in a
Brooklyn's shoreline.
r u s h " variety: the journey takes
Today, in an age of multiple truck
longer but is cheaper than the
routes across New York Harbor,
alternative rail journey up the Hudson
only one carfloat operation remains.
and across the river at Selkirk,
Known as the New York Cross-
near Albany.
Harbor Railroad, it moves roughly
Intermodal Cargo
M I M MI
The lion's share
of rail cargo into and out of the New York region is what's known as "intermodal" cargo;
Center beam bulkhead flatcar
COFC Container-on-flatcar
(COFC)
These cars are often used to transport
service is a common sight on
lumber or sheets of drywall,
freight trains rumbling down both
which are stacked on either side of a
sides of the Hudson River.
i.e., cargo moving by more than one means of transportation. Truck trailers, for instance, may
be loaded on rail flatcars and taken
center beam. long distances by train. Containers may travel the same way, moving easily between any combination of ship, rail, and truck. A t least one specialized vehicle—the RoadRailer— can move on both road and rail. Special-purpose depressed
Double-stack Double-stacked
center flatcar These flatcars
containers are placed on specially
are generally used to haul extremely
designed low-level chassis to meet t h e
oversized items.
22-feet clearances common on rail lines in parts of the United States.
Increasingly, however, intermodal traffic moves in containers. Thanks to special low-level rail chassis, containers can be stacked on top of each other for long journeys across the country. Known as "double-stack" trains, this mode of rail travel has proved so efficient t h a t Asian cargo headed for the New York region is often dropped off on the W e s t Coast and completes its journey to the East Coast this way—in what has become
RoadRailer The RoadRailer is a specialized trailer vehicle designed to move over the highway, b u t also to be pulled in a t r a i n . Originally designed in 1952, it is used by a number of railroads, including Amtrak for mail service.
TOFC Trailer-on-/latcar (TOFC)
known as the "mini-landbridge" system.
service consists of truck trailers riding on flatcars.
This system is generally
referred to as "piggybacking."
Double-stack trains are also loaded here at the port, and in other northern New Jersey terminals, with imports bound for eastern Canada and the Midwest as well as exports.
W h a t ' s în a train?
As anyone who has ever
waited at a grade crossing for a freight t r a i n t o pass knows, these trains can be very long indeed. And t h a t is precisely the economics t h a t underpin rail freight: link as many different cars as possible going roughly to the same location, pulled by the same locomotive. The unusual mix of commodities t h a t can result is represented here by the lineup of a train delivered to the New York & Atlantic Railway on August 2 6 , 2 0 0 3 .
Wine
x
x-
Pulpboard
62
The Works
Moving Freight
Rail Freight Classification Yards
Railroads' advantage over trucking turns on
their ability to move many diverse shipments over a
of the yard; the switch engine pushes the car over the hump and gravity accelerates it onto its predetermined track. Automatically operated retarders brake each car's wheels so
relatively long distance on one train. But making up a train
that it couples at just the right speed to the cars already
is a cumbersome process, as no two cars may have the
lined up on the track.
same origin and destination. Here's where the classification yard comes in: cars are collected from shippers and
Within the New York-New Jersey region, several classification yards act as part of the regional rail network.
assembled into trains for travel to a second yard, where they
Oak Island, just north of Port Newark, New Jersey, is
are broken up and sorted for delivery to customers.
operated by Norfolk Southern and CSX. Oak Point Yard, in
Two kinds of classification yards predominate—flat yards
the Bronx, is the largest classification yard within New York
and hump yards. Flat yards consist of a set of parallel tracks
City. It serves as a classification and staging yard for
interconnected by switches, and rely on switch engines
freight rail traffic to and from Long Island over the Hell Gate
to move cars in blocks or individually. Hump yards, in
Bridge. Most traffic bound for New York City from the
contrast, are characterized by a track raised above the rest
west moves over Selkirk Yard, just south of Albany.
Selkirk Yard
Nearly all freight moving
directly into New York City comes through the Selkirk Yard, located eight miles south of Albany and operated by CSX. W i t h 7 0 tracks— the longest will hold 7 0 cars and the
shortest
37—Selkirk is the largest classification yard on the East Coast.
Receiving yard After the engine is removed from the train, the remaining cars are inspected for mechanical defects.
Pulpboard
Engine house The engine house is where the engines are inspected a n d m a i n t e n a n c e and repairs are undertaken. It is often located a t the center of the yard, so as not to disrupt the humping activity.
Propane
Corn Feed
63
Car repair yard The car repair yard is the location of light repair. Maintenance men will be dispatched throughout the yard, generally to tracks designated by type: hopper, a, etc.
For Local Delivery
Perhaps the closest
thing New York has to a local railroad is the New
York & Atlantic (NY&A), which operates a
269-mile system t h a t primarily serves customers on Long Island. It is a recent phenomenon: until 1 9 9 7 , the rail freight business on Long Island (including Queens and Brooklyn) had been the purview of the Long Island Rail Road or its predecessors. A t t h a t time, N Y S A , a subsidiary of the Anacostia and Pacific Railroad holding company, was awarded a 20-year concession from the MTA with the goal of reversing a 2 5 - y e a r decline in Long Island rail freight volume. Employing only 3 0 people, it runs eight trains a day
(six days a week) along t r a c k s it shares
with the commuter railroad. Its 1 8 , 0 0 0 annual carloads consist primarily of aggregates, scrap paper and metal, forest products, chemicals, and food products.
Departure yard Blocks move j r o m the classification yard to t h e departure yard, where they are made up into t r a i n s . Car inspectors look over the t r a i n , a t t a c h the air hoses, and couple the engines.
Pulpboard
^
Rice
^
Flour, Bagged
m w ijjijjH W H I N I J J I J J H WLLIHI imjjHi iimmmiu
The Works
Moving Freight
Rail Freight
How
a Hump Yard Works
Hump yards are most efficiently used to classify trains made up of cars going to many different destinations. The hump locomotive travels only one train length in order to "classify" or segregate the entire t r a i n .
Pit As a train leaves a receiving yard and moves toward the hump t h a t signals its entrance into the dassi/ication yard, the train rolls over a glassed-in pit under the track. An inspector will examine the couplers, gears, and brakes among other things.
Hump The h u m p is a n artificial hill, generally about 2 0 - 3 0 feet high. A hump engine is attached to the train and pushes the cars over the h u m p a t a rate of 3 - 4 per minute, down a grade 0/between 2% and 4%. Some humps include a scale and inspection pit.
"Do Not Hump" Occasionally freight cars rumbling through the New York region carry the admonition "do not hump." These are generally cars carrying fragile or high-value loads—liquor, bricks, glass, or delicate food products, for example. Sending these trains "over the hump" could damage the goods—hence the warning.
Classification yard Once over the hump, cars roll into the classification yard, where each track is assigned a destination. As cars accumulate in the yard, blocks of similarly destined cars are built. Yards are often called "bowls," as most track slopes to the center. Retarder Speed meters monitor the cars' speed once over the hump, and this information is passed to the retarder operator. This indicates j u s t how much to slow the train (via mechanical retarders t h a t grip each car's wheel flanges) so that coupling speed does not exceed 4 mph.
Building a train Power-operated switches control the track routes from the classification yard to the pullout leads. One or more leads feed the departure yard or yards, where trains are made up based on destination.
66
The Works
Moving Freight
Rail Freight Transcontinental Freight
Not all that long ago, produce
moving from the West Coast to New York was shipped
But transcontinental rail freight is trying to make a comeback, with clean, refrigerated cars ("reefers") and— most important—more reliable train scheduling. Though
almost exclusively by rail: potatoes and onions from the
cross-country rail transit times are roughly double those
Northwest, fruit from California, for example. However,
by road, the cost of moving by reefer is roughly half that of
as trucking became more competitive and efficient (in part
truck thanks to labor shortages, rising fuels costs, and
due to the interstate highway system) and rail service
increasing highway congestion. As a result, rail is making
deteriorated, the tables began to turn. Today, only a minority
inroads with the more durable types of western produce:
of produce moves into the New York region by rail:
carrots, onions, celery, potatoes, broccoli, and citrus fruit.
Sunkist, for example, used to load more railcars in a day than it does now in a year.
The Journey of a Carrot
i. At a packing shed n e a r Bakers/ield, California, workers for Grimmway—the world's largest carrot grower— hand-load over 2,500 50-pound bags of carrots into a refrigerated railcar a b o u t to begin its eight-day journey to the Bronx.
Plastic Pellets
Plywood
2. Once packed, a local train collects the car and brings it to a classification yard in Fresno. Along with refrigerated trains collected elsewhere a n d several cars carrying nonperishables, it leaves for the Union Pacific's N o r t h e r n California h u b , Roseville Yard, where it is coupled with another block of refrigerated cars.
Potatoes, Fresh
Oak Flooring
3. At Roseville, engines are added and the train, limited to 85 cars to enable it to manage the steep grade of the Sierra Nevada, departs for Bailey Yard in North Platte, Nebraska — t h e largest classification yard in the world. At N o r t h Platte, the refrigerated cars will be combined with reefer loads from Idaho and Oregon and sorted into two new trains — o n e headed for Selkirk, New York, a n d the other for Waycross, Georgia.
Beer
4. The Selkirk-bound train arrives at Union Pacific's Proviso Yard west of Chicago and is then moved by a local switching railroad to a CSX yard nearby. The Union Pacific crew is replaced by a CSX crew, although the Union Pacific's engine will continue on the t r a i n t h r o u g h o u t its j o u r n e y to Selkirk.
67
"Big Milk"
To this day, rail freight
buffs remember with fondness the "milk trains" —the trains t h a t brought nearly a million gallons of milk each day into the region from farms in upstate New York. These trains carried cans of milk in special insulated cars (packed with ice in the summer) to "milk y a r d s " in the region. Three terminated at the 6 0 t h S t . Milkyard on the west side of M a n h a t t a n , dropping off cars at the Bronx Terminal M a r k e t and the 1 3 0 t h S t . Milkyard in M a n h a t t a n en route; a fourth terminated in Weehawken, New Jersey. The trains generally began their rural runs in the afternoon, arriving in the city during the wee hours of the night. Tank cars for milk replaced cans around the t u r n of the last century: precooled milk was pumped into the 6,000-gallon car at the origin of the journey and pumped out into waiting t r u c k s a t the receiving end, where it was moved t o pasteurization plants. 6. The carrot car, along with 1 9 other reefers, arrives a t Oak Point Yard and is moved alongside a shed a t nearby Hunts Point M a r k e t , the largest wholesale produce complex in the nation.
Though the tank cars brought greater levels of efficiency than the can cars, they proved no match for the truck. By the 1 9 5 0 s , trucks traveling on improved state highways offered a more direct and faster haul from the country milk station to distribution
7. Here, the car is unloaded and its contents distributed to the u l t i m a t e consignees. The car will r e t u r n to the West Coast either empty or loaded with westbound cargo.
Pulpboard
^
Onions, Fresh
Corn Starch
points in t h e city and "Big M i l k " ' s days were numbered.
Lumber
The Works
Moving Freight
epicenter of this trade. Initially, it was the docks and wharves of South Street that bustled with mail and other cargo ships. Businesses sprang up along the piers to serve the trade, and longshoremen settled their families in adjacent
By almost any account, New York owes its origins as a commercial center to its advantageous location
neighborhoods. Soon, the network of shipping activity— and the intricate web of finger piers it required—spread to Manhattan's West Side, as well as to the Brooklyn, Hoboken,
on maritime trade lanes. With one of the world's great natural harbors at its front door and a mighty river at its back, maritime
and Jersey City waterfronts. These finger piers served as the lifeblood of the city and—in times of war—the nation.
trade gave rise to the young city in the
During World War II, there were roughly
eighteenth century and propelled it
750 active piers in the port—able to berth
to national prominence in the nineteenth.
425 oceangoing vessels simultaneously.
The opening of the Erie Canal in 1825 served
Within two generations, however, nearly
to cement its commercial position and
all of them disappeared. No event was more
by i860 nearly half of the nation's trade
responsible for that transformation than
moved through the Port of New York.
the invention of the container in the 1950s,
For a century or so, Manhattan was the
which offered tremendous efficiencies and greatly expanded maritime trade. Its
Maritime Freight
demands for large tracts of open space found an outlet in the swampy backwaters of New Jersey, and within a generation the din of the working waterfront was but a memory to most New Yorkers. In the years since then, New York's maritime trade has grown dramatically— more than 80 million metric tons of cargo move through the port each year—but it is also less visible. Much of it moves over docks at the Port Newark/Elizabeth Marine Terminal in New Jersey, whose 2,100 acres sit just east of Newark Airport. Supplemented by New York Container Terminal on Staten Island, Red Hook Container Terminal in Brooklyn, and a number of private marine terminals in New Jersey, the littleheralded complex serves in many ways as the economic lifeline of the region.
The West Side waterfront, circa 1869.
69
Today, New York Harbor remains among the city's greatest assets. It covers 650 miles of shoreline, reaching from the banks of Sandy Hook in New Jersey around Staten Island and northward along the contours of Newark Bay and the Hudson and East rivers. Although it is a natural harbor, it is not a naturally deep one—silty deposits from the Hudson, Hackensack, and Passaic rivers give it a natural depth of between 18 and 21 feet. As a result, harbor traffic must stick carefully to a predetermined set of man-made and wellmaintained navigation channels and anchorages.
Port Newark/Elizabeth, the destination for much of the region s cargo, is accessed via the narrow Kill van Kull located on the n o r t h side 0/Staten Island.
Brooklyn Marine/Red Hook Container Terminal is located opposite Governors Island in t h e Red Hook section of Brooklyn.
The Statue of Liberty is the official center of the port, with the "port d i s t r i c t " radiating out 25 miles in each direction.
New York Container Terminal, formerly known as Howland Hook Marine Terminal, is on the n o r t h \ shore of Staten Island and handles both containerized and noncontainerized traffic.
70
The Works
Moving Freight
Maritime Freight Entering the Harbor
Each year,
unofficial gateway to New York Harbor. The passage under the Verrazano is but
more than 12,000 ships enter or leave New
one of several tricky maneuvers todays
York Harbor. Roughly 40 percent of them
cargo vessels must make before reaching port.
are tankers or "drugstore ships," carrying
In some places, the harbor bottom is made
refined products or crude oil. Another
up of soft material like sand, silt, or clay; in
45 percent are laden with containers,
other places, the seabed is rock—a less
destined for warehouses and distribution
forgiving matter. The combination of sharp
centers in the region. The rest are bulk or
turns, wild currents, and a preponderance
break-bulk (cargo consolidated into smaller,
of reefs and shoals means that only a
noncontainerized units) vessels, often
trained harbor pilot is allowed to guide large
carrying single products such as iron, steel,
ships into port: even the most experienced
or forest products. With the exception of
ship captain must relinquish the wheel
tankers headed for terminals along the
to a Sandy Hook pilot when his or her ship
Arthur Kill, nearly all of them pass under
reaches New York waters.
the Verrazano Narrows Bridge, the
Making for P o r t
The captain of the ship cedes contra! to t h e Sandy Hook pilot, who takes the ship through the Narrows and into t h e harbor.
A skiff from the pilot boat moored offshore approaches the ship, and a Sandy Hook pilot climbs up a rope ladder to board the vessel entering the harbor.
Ships major (from east),
approach from one of the three shipping lanes—Barnegat the s o u t h ) , Hudson (from the or Nantucket (from the n o r t h ) .
71
P o r t Newark/Elizabeth
A docking pilot takes over a s the ship approaches Port Newark. He or she will guide the ship into her berth a t the port.
The Invisible Pilots
Since 1 6 9 4 ,
when the Colonial Assembly commissioned a group of local sea captains to aid ship masters entering New York Harbor, pilots have been Tugs come alongside the ship,
responsible for navigating ships through New
to assist in making the sharp t u r n s necessary t o travel t h r o u g h t h e
York Harbor's treacherous waters. Relying
Kill van Kull between Bayonne and
initially on oars and sail, local pilot groups in
Staten Island.
New
York and New Jersey competed for
the patronage of the incoming vessels. A tragic accident in 1 8 8 8 forced New York Monitoring Waves and Tides
State to act to combine local pilot companies;
Current velocities and depths in New York H a r b o r v a r y
widely,
across the harbor and over the course of a day. The National
Ocean
Service, part of the Department of Commerce, m a i n t a i n s a model to provide mariners with in/ormation t h a t can help them time their j o u r n e y
seven years later, the New York and New
Jersey pilots groups merged and the
Sandy Hook Pilots Association was born. Today, a full century later, the Sandy Hook Pilots still have a monopoly on this business.
or decide which r o u t e t o take. I t
Some 7 6 pilots take t u r n s manning one
is three dimensional a n d relies on
of two large pilot boats stationed around the
real-time wind and water-level d a t a t o predict water levels and c u r r e n t s a t t h o u s a n d s of locations across the harbor. • • • •
< 0 . 3 knots 0 . 3 - 0 . 6 knots 0 . 6 - 1 . 0 knots 1.0—1.3 knots > 1.3 knots
clock off Sandy Hook, assisting on average 3 5 - 4 0 incoming or outgoing ships each day. And they are well t r a i n e d : a seven-year apprenticeship must be followed by seven more years of work as a deputy pilot.
Maritime Freight Managing Harbor Traffic
The U.S. Coast
• Channel
12 serves the Arthur Kill and East River and
is used by the Coast Guard to administer the harbor's
Guard, once part
anchorages.
of the Department of Transportation and now part of the Department of Homeland Security, is responsible for
• Channel
14 covers boats steaming through the main
shipping channel, including the Lower and Upper
monitoring and coordinating New York's harbor traffic. It does this largely through its 24-hour Vessel Traffic Service
Bay, the Kill v a n Kull, Newark and Raritan bays, and
(VTS), based at Fort Wadsworth on Staten Island. Staffed
Sandy Hook Channel.
by a mix of civilian and military personnel, the service
In addition to coordinating vessel movements, the Coast
gathers and disseminates real-time information about marine
Guard monitors and administers boat "parking" in the harbor
movements via three radio frequencies:
at the three federally designated anchorages at Bay Ridge and Gravesend, off Brooklyn, and at Stapleton, off Staten
11 is provided for initial check-in, when a
• Channel
Island. Vessels are required to provide four-day advance
boat is getting under way from a mooring or entering
notice before arriving at an anchorage and are permitted to
the harbor.
stay for a limited period of time—generally 30 days.
NEXT: 5031-5331
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commercial buildings and delivered to |
recyclers, exporters, or paper manufacturers. The remainder, often referred to as "putrescible waste," is delivered to many
transportation £r warehousing £
information
1 pro/essional, technical {/scientific H state £r/ederal government j administrative support services
of the same transfer stations now handling much of the city's residential waste— primarily in New Jersey, the Hunts Point
H arts, entertainment {/recreation accommodation irfood services HI other services
area of the Bronx, the Greenpoint/ Williamsburg area of Brooklyn, or in Jamaica, Queens. Both collections typically occur at night, when the streets are quietest. In addition to commercial waste, New York produces over seven million tons
Waste and " t h e M o b "
of construction and demolition debris
Until the middle of the twentieth
each year. Some 30 to 40 percent of it is
century, the city bore responsibility
effort on the p a r t of law
one or another form of building waste
for collecting commercial waste
enforcement agencies, indictments were handed down against the
much they paid for waste removal. In t h e m i d - 1 9 9 0 s , after much
(plasterboard, plumbing, etc.) and moves
as well as residential waste. That
to transfer stations permitted to handle
changed in 1 9 5 7 , when t h e city
leaders of the trash cartel in the
this kind of waste, many of them in the outer
withdrew from the commercial
city. A t the same time a new
boroughs or New Jersey. The remainder
waste business and t h e private
local entity, t h e Trade W a s t e
is often referred to as "clean fill" and consists
carting industry—and organized
Commission, was set up to regulate
of gravel, dirt, rock, concrete, and stone
crime—took over. Some private
the commercial waste haulers
that is largely the result of site excavation
c a r t e r s found themselves members
by licensing valid businesses and
and building demolition. It is crushed and
of t r a d e associations controlled
setting maximum and minimum
milled at a "clean fill" milling operation
by organized crime, and individual
rates for waste collection and
and used by both public and private
businesses found themselves with
disposal. A l t h o u g h its name has
sectors as soil cover in a variety of places.
little choice of provider: specific
been changed t o t h e Business
locations were "owned" by specific
Integrity Commission, the
haulers and the local business
organization's oversight role
owner had little or no say in how
continues today.
199
Roosevelt Island
With one exception, New-
pull the garbage at 60 mph through a vacuum to a central
York City's garbage collection
facility for collection, compaction, and containerization.
is pretty low-tech—trucks, cans, and a lot of manual
Manned by nine Department of Sanitation employees, the
labor. The exception is Roosevelt Island's "Automated vacuum
system has the capacity to collect trash from 20,000
Assisted Collection" system—otherwise known as AVAC.
people, making it the largest of only 10 such systems operating
Designed to handle refuse in densely populated areas, it
in the country (DisneyWorld has one as well). Currently
relies on a series of chutes which run vertically through the
it processes eight tons each day, though expansion to nine
island's high-rise buildings and are connected to a 20-
new apartment buildings on the island is planned.
inch pipe running under the island. Centrifugal turbines
The AVAC in Action 1. Residents deposit trash in chutes located on each floor of the island s residential buildings.
2. A dozen times a d a y — a n d more jrequently on weekends—the system switches itself on, and all accumulated garbage is sucked through a 20-inch pipe a t speeds up to 60 mph.
3. Material moves into a hopper a t the central AVAC building, from which it drops into a container on large rollers.
4. The container fits inside a giant compactor, which reduces the garbage to roughly one-fifth of its original size. When full, it is rolled away for removal.
5. A Sanitation Department truck carries the container away— currently to the Tully transfer station in College Point, Queens—for disposal. Five or six of these large, compacted c o n t a i n e r s a r e removed from the island each week.
Garbage Most New Yorkers know little
per hour. Each sweeper holds 5.5 yards of debris, and will
about street cleaning other
dump into collection trucks—generally twice a day, but more
than that it's one of the main reasons they can't leave their car parked on a street for days at a time. Few recognize
in leaf season. The key to a successful sweep is water, and each of the
how important a role the mechanical street sweepers and
sweeper vehicles holds 240 gallons of it. When they run out
their drivers play in keeping city streets clean.
of water en route, drivers will refill their tanks at
Each day, the Sanitation Department sends out roughly 325
predetermined hydrants with special magnetic caps on them.
sweepers. Though the machines travel slowly, generally
Like the Fire Department, the street sweeper is guardian
covering between six and 20 miles a day, they are actually
of a special wrench that gives him or her the ability to open
capable of moving much faster if necessary: thanks to
the designated hydrants.
a Mercedes-Benz engine, their top speed is a swift 37 miles
Underneath the S t r e e t Sweeper
The vehicle s hydraulics allow the sweeper to automatically shift balance when the brooms get worn down.
Street sweepers have two g u t t e r brooms, which r o t a t e and t h u s sweep inward.
A rubber conveyor tosses anything picked up into a hopper.
There is also a long, t u b u l a r , pickup broom which r u n s across the bottom of the vehicle.
201
How
Clean Is Clean?
Policing the Streets
businesses comply with health and
The Sanitation Police are a part of
sanitary laws governing both waste
the department's enforcement
disposal, including recycling, and
division, whose white cars are not
s t r e e t cleanliness. The division also
uncommon sights on New York
operates an Illegal Dumping Task
City s t r e e t s . The division's job is to
Force and a bounty program to reward
ensure t h a t both residents and
people who report illegal dumping.
Street Cleanliness Ratings 1980-2003
S t r e e t cleanliness is
measured by the Mayor's Office of Operations, and ratings are based on rigorous photographic standards of cleanliness. Inspectors are trained to assess conditions based on a scale of I (cleanest) to 3 (dirtiest), with ratings below 1.5 considered "acceptably clean." Inspections may occur before or after street cleaning activities, and not all s t r e e t s are visited: sample s t r e e t s are statistically and geographically representative of a given district. The information produced is provided to Community Boards, Business Improvement Districts (BIDs), and other public interest groups interested in local conditions. Fiscal Year
Acceptably clean: 1.0 a clean
Acceptably clean: 1.2 a clean
street, with no litter
street, with just a few traces of litter
Filthy: 1.8 litter is
Filthy: 2.0 litter is concentrated,
Filthy: 3.0 litter is very
concentrated in spots, w i t h gaps
with gaps between piles
concentrated, both in a straight line
between piles or pieces of litter
Not acceptably clean: 1.5 la gaps between pieces of litter
along and running over the curb
202
The UUorks
Keeping It Clean
Garbage Snow Removal
Although most of its day-to-day resources are devoted to garbage
To deal with particularly large snowstorms, the department relies on snow melters—diesel-powered machines that
removal and street cleaning, the Department of Sanitation
are towed into place by a tractor cab and can melt as many
endears itself most to New Yorkers during snowstorms.
as 60 tons an hour. The machines are relatively new—
With the first hint of snow, the department readies itself for
a response to the late 1990s ban on dumping salty snow into
action. Depending on the forecast, a certain number of
the river—and have proved effective at tackling the
sanitation trucks are "dressed"—fitted with plows in the front
larger mounds that can clog intersections and streets. Built
and chains on the back tires. Once two inches cover the
with extra-large holding tanks, the machines melt the
ground (they can't plow less than that due to a mount on the
snow and direct the water runoff into nearby storm drains.
vehicle which protects them from uneven manhole covers and other obstacles), they hit the streets.
Let It Snow. mm*
= 1 0 trucks
With only one inch of snow, only salt
When there is a snow/all of between
A t / o u r to six inches, between two-
A big snow/all, more t h a n six inches,
spreaders—350 of them, as well
two a n d / o u r inches, all spreaders
thirds and three-quarters of the fleet
will involve equipping 1 0 0 percent
as 60 small pickup/salt spreaders—
are used a n d one-quarter of t h e
will he used—over 7 0 0 trucks.
of the fleet (1,335 f u c k s ) with plows.
are used.
Sanitation truck fleet—roughly
380
vehicles—is equipped with plows and sent o u t .
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Mapping the Salt Domes The city has a total of 3 4 salt dome sites, 16 of which are covered, 13 of which are uncovered, and nine of which are strictly seasonal. They house salt until it is needed for placement on roadways, generally during the winter.
Salt Dome Type M Dome ft Shed Tarp w
Uncovered
Snow melters A diesel-powered
Salt spreaders Salt spreaders use
burner heats water in t h e holding
a conveyor to move salt to the back of
t a n k . The hot w a t e r is sprayed
the truck, where it is sent down a
over snow as it is added to t h e t a n k
chute. A gate, located adjacent to t h e
by a front-end loader. The liquid
chute, is adjusted to allow a certain
sinks to the bottom, passes t h r o u g h
a m o u n t of salt through a t a time. The
a filter, and is piped directly into
salt hits a spinner, which can
city storm drains.
spread it anywhere from four to eight feet, depending on the type of road being salted.
HE F U T U R E
Looking back over the last century, it is fair to say that the layers of New York's infrastructure took form haphazardly in response to discrete civic needs and at different times—for streets and clean water in the nineteenth century, for efficient transport at the dawn of the twentieth, for speedier means of trade by the middle of that century. It is not surprising, then, that the systems portrayed here operate almost entirely independently
commitment to its upstate watershed delivery system.
of one another and share little or nothing in the way of
New freight rail routes will open, but they will
physical infrastructure.
support—rather than supplant—vehicular tunnels and
As we look to the future, however, it is likely that
will rely almost exclusively on rail lines laid out
connections between forms of infrastructure will
generations ago. Channels will be dug and blasted deeper,
become more routine—in New York and elsewhere.
but they represent almost precisely the maritime
Telecom lines may well run through sewers, solar
trade lanes that ships have plied for centuries.
power will be used at sewage plants, wastewater can
Over the past two centuries, New York's infrastructure
replace freshwater for industrial uses, and garbage
has successfully supported the growth of the city
may be among the fastest growing rail freight
around it. The durability and longevity of the region's
commodities. And as parts of New York are reimagined
infrastructure is a testament to the vision of those
in their entirety—lower Manhattan and the West
w h o laid it down in some cases more t h a n a century
Side yards above all—so too will be the infrastructure
ago—who saw the need for express tracks on the
that supports them: green power, gray (reused)
subway, for open stretches of swamp for containers,
water, new subway lines and tunnels, and possibly the
and for upstate land for clean water. But it is also a
first expansion of the city's steam system in decades.
tribute to the thousands of municipal and private sector
To the casual observer, these changes are relatively
workers who, for generations, have toiled around
minor. A third water tunnel will facilitate local
the clock to maintain the way of life that New Yorkers
water distribution, but it only reinforces the city's
have come to expect.
The Works
The Future
Moving People
As we look to the future, it is hard to imagine traffic not moving faster on the region s roads: tollbooths and E-ZPass
Second Avenue Subway There are many projects on the drawing board in the headquarters of the Metropolitan Transportation Authority, but none awaited so eagerly—or for so long—as the Second Avenue Subway. One quick glance at a New York City subway
will become relics of the past, as electronic
map suggests why: while the West Side of
identification is built into individual cars;
Manhattan has multiple lines running
traffic warnings will become more precise
south from the Bronx, the East Side has only
and timely, as new ways to monitor data
one: the notoriously overcrowded
about road conditions become available; and
Lexington Avenue line.
low-tech improvements to mitigate traffic in the most congested areas of the city will continue to be made by city DOT. But while roadway congestion may be the focus of daily life in Los Angeles,
As early as the 1920s, when it was proposed as phase two of the plan for the new city-owned IND system, there was strong public support for the Second Avenue line. But plans for the project were shelved
Dallas, or Miami, in New York it is rail
due to the tight fiscal environment following
transportation that—more than any
the Depression and did not reappear until
other mode of travel—knits together people
after World War II.
and their workplaces. And it is changes to that system in the future that will
In the early 1950s, $500 million in New York State bonds were issued to support
contribute most to more efficient movement
construction of the line, but the proceeds
of people in the future.
were spent on more urgent capital
Three new initiatives are likely to improve
projects required by the then-aging system.
regional rail connections. The first, the
Plans for the line were revived with
Second Avenue Subway, will relieve the
the establishment of the Metropolitan
severe overcrowding on the numbers 4, 5,
Transportation Authority in the late
and 6 lines that are the sole north-south
1960s, and small portions of the subway
subways on the East Side of Manhattan. The
were subsequently constructed in
next, the proposed subway to JFK, would
East Harlem and the Lower East Side, but
offer direct rail access to the airport as well
the project once again fell victim to
as dramatically improve travel times for
New York City's financial woes.
Long Island commuters who work in lower Manhattan. The third, a proposed new
With the recent allocation of federal funding, the project has returned to
tunnel to increase direct rail service from
life. The current plan is to build a new
New Jersey into midtown Manhattan, is
line along the length of Second Ave.,
likewise aimed at improving the commuter
from 125th St. to Hanover Square, although
experience—in this case for those living
the speed at which this occurs will be
west of the Hudson.
determined by the availability of additional local funding.
207
Direct Rail to JFK For almost two decades, the MTA operated
Access to the Region s Core (ARC)
the "train to the plane": an hour-long
A new passenger rail tunnel entering
journey on the A train to the Howard Beach
Manhattan from the east could well
station in Queens, where a bus would
be matched by one from the west, if bistate
wait to shuttle riders to their terminals. So
transportation planners have their way.
light was traffic on the line that no
A comprehensive study of a new two-track
one complained, and few even noticed, when
tunnel under the Hudson River from
the service was scrapped by the MTA in 1990. The idea of a direct rail link to John F.
Secaucus into Penn Station was recently completed under the supervision of the
Kennedy Airport from Manhattan was
Port Authority and New Jersey Transit. The
revived after September 11, 2001, more
study suggests that completion of a new
as a component of an economic development
tunnel, along with new passenger facilities
strategy for lower Manhattan than as a
near Penn Station, could double west-of-
solution to any particular
transportation
problem. A new rail link between the
Hudson rail capacity, speeding up travel times and providing nearly all
airport and lower Manhattan would not
commuters from New Jersey, as
only make the latter a more attractive
well as those from Orange and Rockland
office location for business travelers, but
counties in New York, with a one-seat
by connecting at Jamaica with the Long
ride into midtown Manhattan.
Island Railroad would facilitate the journeys of hundreds of thousands of Long Island
The tunnel would operate much the same way the existing Penn Station tunnel
commuters destined for lower Manhattan,
operates today: diesel-electric locomotives
who today must switch to a downtown-
would operate
bound subway at Penn Station. Forty alternative routes were evaluated
under diesel on the branch lines
during the course of 2004 by consultants
in the suburbs
hired by the Lower Manhattan Development
but switch to
Corporation, the Port Authority, the MTA,
electric power to
and New York City. Ultimately, a route that
travel through
involves extending the existing Air Train
the new tunnel
line (which runs from JFK to Jamaica Station)
into Penn Station.
along the Atlantic branch of the LIRR
Although the
and through a new tunnel between
precise alignment
Newark Penn Station
downtown Brooklyn and lower Manhattan
of the new line
was recommended. Although the projected
has not been
cost of the tunnel is considerable
determined, it is expected to run under the
(approximately six billion dollars), and the
Palisades, very close to the existing
public review process extensive, moves
Northeast Corridor track that carries
are afoot to secure a large share of federal
Amtrak trains into Penn Station today.
monies for the project.
The estimated cost of the tunnel is a whopping three to five billion dollars. Should funding be secured, groundbreaking for the tunnel could occur as early as 2006, with completion possible in 2015.
The Works
The Future
Mowing Freight
In some respects, the technology used to move goods—as opposed to people—has changed only modestly over the course of
Cross-Harbor Tunnel The idea of a cross-harbor freight tunnel is not a new one; planners as far back as the turn of the last century saw a freightonly tunnel under the harbor as the ideal way to reduce congestion on waterways in the harbor. But with the opening
centuries. The bulk of international
of the Holland and Lincoln tunnels for
trade still moves in ships, much as it did at
vehicles, cargo found a new, speedier
the time New York City was founded. The
way to cross the river, and the idea of a
ships are bigger, faster, and more reliable—
rail freight tunnel was shelved.
and much of the cargo is stuffed inside
Today, trucks crossing the Hudson
containers for ease of handling along the
continue to carry the bulk of the region's
shore—but the mode of transportation is
cargo: less than 2 percent of all freight
essentially the same. Somewhat more change
enters areas east of the Hudson by rail. Rail
has occurred with respect to the inland
freight coming to the region from the
portion of the move, where trucks and trains
west and south must travel over a crossing
have largely replaced stagecoaches and
at Selkirk, 140 miles to the north of the
canals, but the overall pace of change has
city, or make use of the limited carfloat
been slow—and is likely to remain that
service operating between Greenville
way for the foreseeable future.
Yards in New Jersey and Brooklyn.
There are nevertheless a handful of
Keen to reduce reliance on trucking and
projects afoot in the metropolitan area that
increase rail freight options, the federal
will, if they come to fruition, facilitate
government recently funded a major study
and potentially reconfigure local freight
on the impact of a freight rail tunnel
handling. Two of them—the Cross-Harbor
between Brooklyn and New Jersey. The
Tunnel and the Staten Island Railroad—are
proposed tunnel—consisting of either
rail projects, aimed at taking trucks off
one or two tubes—would connect the
the congested local highways and expanding
Greenville Yards in Jersey City to the Bay
activity on the region's underutilized
Ridge Line in Brooklyn, and terminate
rail infrastructure. The tunnel is much more
at an intermodal yard in Queens, from which
speculative, and much more costly, than
the rail cargo would be distributed by
the railroad—which is fully funded and
truck. The cost of the proposed tunnel is
likely to be completed as early as 2006.
high (between five and seven billion
The third freight project highlighted here
dollars) and local community opposition
involves the Bayonne Bridge. As container
is strong, making it likely that the rail
ships continue to increase in size, both harbor
tunnel will continue to be the subject of
depths and bridge clearances will need to
discussion for many years to come.
accommodate them. Considerable resources have been put into ensuring deep water in local shipping channels, but as of yet no formal commitments have been made to address the first of the harbor's bridgeclearance problems: the Bayonne Bridge.
209
Staten Island Railroad
Bayonne Bridge
New York is getting a new freight railroad.
The Bayonne Bridge, which connects
Abandoned by its previous operator a
Bayonne to the north shore of Staten Island
decade ago, the Staten Island Railroad—
remains one of the world's longest steel
which spans the Arthur Kill and
arch bridges—its
connects industrial businesses in Staten
central arch spans
Island with the domestic rail system in
1,675 f - Although it
New Jersey—is being brought back to
won an award soon
eet
life in a joint venture of the Port Authority
after its opening in
and the City of New York.
1931 as the most
Acquired by New York City from CSX
beautiful steel arch
Railroad, the railroad will provide
bridge, today the
direct rail service to the expanding New
bridge is something
York Container Terminal at Howland
of a stepchild to the
Hook, to the Department of Sanitation's
region's busier and
new containerization facility at Fresh
better known suspension bridges—the
Kills, and to industrial businesses on the
George Washington, the Brooklyn, and the
railroad's Travis branch, which runs
Verrazano, among others. It has geography
down the western shore of Staten Island.
to thank for that: located in something
Reconstruction involves not only new track
of a metropolitan backwater, it handles only
and replacement of rotting wooden-
about 20,000 vehicles each day and is
trestle creek bridges, but the completion of
largely invisible to the great majority of
improvements to the Arthur Kill lift
New Yorkers.
bridge, one of the region's few rail bridges
But the bridge is anything but invisible to
over water. The bridge will be painted
the pilots and captains of cargo vessels
cobalt blue—the color of the original railroad
calling at the Port of New York and New
serving that part of Staten Island.
Jersey. At 151 feet above sea level at
Reactivation of the railroad will do more
midspan, the bridge is a navigational hazard
than meet the needs of Staten Island's
to the larger container ships that make
freight-dependent businesses. It is expected
their w a y through the Kill v a n Kull off
to reduce truck traffic on the island by
Staten Island en route to Port Newark/
roughly 100,000 trips a year when it opens,
Elizabeth. To date, several have collided
in 2006.
with the bridge, forcing its temporary closure but not resulting in any serious structural damage. To minimize conflicts in the future, the Port Authority of New York and New Jersey is evaluating the options for raising the bridge. The most likely plan involves leaving the bridge structure intact, but raising the roadway to provide greater clearance to ships. However, the estimated cost of such a plan could be several hundred million dollars, a sum unlikely to be paid back by fees from the relatively small number of cargo ships that stand to benefit from the removal of this rather unusual navigational hazard.
The Works
The Future
Power
Over the next several decades, the technologies used to produce electric power are likely to change relatively little.
Hydro Turbines The world's first bank of tide-powered turbines is likely to be developed here in New York City—in the middle of the East River. The plan is for six electricity turbines owned by Verdant Power, a Virginia-based energy company, to be attached to concrete
However, as power plants get harder to
piles driven into bedrock some 30 feet
locate within city boundaries, transmission
below the surface of the river. The heads
projects bringing power generated
of the turbines will move to face the current,
outside of the region to the city are likely
and the blades will spin according to the
to become more attractive. So too are
ebb and flow
alternative energy sources, which
of the tides,
should prove more competitive as the
producing a
technologies mature and the cost of reliance
modest 200
on traditional fossil-fuel sources increases.
kilowatts
Two projects under consideration
of power—
involve renewable energy sources. The
enough to
first relies on water power, an important
provide energy
source of energy for the state as a whole
to roughly 200
but one that is largely absent, to date, from
houses—at
the city's energy mix. Another proposal
their peak. Initially, the power produced
focuses on wind power. Open stretches of
will be delivered to two Con Edison
ocean off the south coast of Long Island
customers on Roosevelt Island.
would be used to harness the wind's energy,
If the pilot is successful, however, the field
delivering relatively modest amounts of
of turbines could grow significantly.
power to the New York State grid or, possibly,
New York State has articulated a target of
to particular local facilities.
25 percent reliance on renewable energy
A third project addresses the region s
sources statewide by 2013, and tide power
need for natural gas. Existing pipelines often
would join hydroelectric, wind, solar, and
operate at capacity, and a variety of new
geothermal as means to that end. Verdant
proposals to expand pipeline capacity are
envisions a field of 200-500 turbines
making their way through the regulatory
in the East River between Manhattan and
process. But r a t h e r than building a new
Roosevelt Island.
pipeline, at least one company has
Tide projects to date—most of them
proposed expanding the use of liquefied
overseas—have generally acted more like
natural gas (LNG) to meet the region's
dams, relying on barriers to hold back
growing need for gas. The proposal to moor
tidal waters to power generators. Only a few
an LNG delivery vessel in the middle of
tidal mills have ever been put into use:
Long Island Sound, if successful, would
the first 300-kilowatt turbine was installed
mark a departure from the region's historic
off the coast of Devon in England in 2003
reluctance to locate infrastructure
and another, of similar size, was located near
facilities offshore.
Hammerfest, Norway.
The Long Island Offshore Wind Initiative
Nearly all of the natural gas used by the
Long Island is also the site of an ambitious
region's power plants, homes, and businesses
Liquefied Natural Gas
proposal to harness the region's wind
is imported from the Gulf or western
power. Known as the Long Island Offshore
Canada via transcontinental pipeline. But
Wind Initiative, the plan—initiated by
reliance on the busy pipelines could be
the Long Island Power Authority (LIPA) under
dramatically reduced if Broadwater
a power purchase agreement with
Technologies—a joint venture of Royal
developer Florida Power and Light Energy—
Dutch Shell and TransCanada—succeeds in
involves the placement of 40 wind
constructing and mooring a Floating
turbines in an eight-square-mile area to
Storage and Regasification Unit in the
the southwest of Robert Moses State
middle of Long Island Sound.
Park, on the island's southern shore. If it
The shiplike terminal, roughly the size
moves ahead, the project could produce
of the Queen Mary 2 ocean liner, would
up to 140 megawatts each day as early as
receive liquefied natural gas shipments—
2007—enough to power 42,000 homes
natural gas "frozen" into a liquid
in the service area.
state and kept at 260 degrees below zero
Wind energy is the world's fastest-growing source of energy, in part because the
Fahrenheit. At the terminal, the LNG would be warmed back into a gas
costs of producing it have dropped roughly
and pumped into the existing Iroquois
80 percent in the last three decades.
pipeline, which runs from Milford,
While the UK and continental Europe have
Connecticut, to Northport on Long Island.
relied on wind power much more
The double-hulled vessel-cum-terminal
extensively than the United States to date,
would be able to store the equivalent of
states like California have successfully
about eight billion cubic feet of natural gas.
harnessed wind power since the 1970s and
The proposed siting area is in the widest
the federal government has articulated a
part of Long Island Sound, roughly 10
goal of relying on wind power for 5 percent
miles off the coasts of New Haven and
of the country's energy needs by 2020. A successful offshore wind power project
Riverhead, in water 70-90 feet deep. From here, a 25-mile long line would run
requires high winds, of course, but also
west along the seabed to meet the
relatively shallow water. Long Island's south
existing Iroquois pipeline.
shore is ideal in this regard, as it features
Though the idea of an offshore facility
shallow water (up to 70 feet is acceptable for
is new, the use of LNG in New York
wind turbines) as far as six miles out—
is not. Both Con Edison and KeySpan
meaning that the windmills, which extend
maintain supplies of LNG locally, to meet
up to 200 feet above sea level—might
peak demand during the coldest winter
not be visible from the shore.
periods. When temperatures fall below 10 or 15 degrees Fahrenheit, LNG from onsite storage tanks is vaporized and sent out to meet system needs.
The Works
The Future
Communications
The world of communications, and telecommunications in particular, is evolving so rapidly that it is difficult to envision how residents and businesses will
Wireless on Pole Tops In an effort to improve mobile telephone services to city residents, New York City is planning to make available a variety of streetside poles under its control for transmission of mobile telecom services. This marks a departure from the evolution of the cellular market to date, which has largely
communicate with each other two decades
relied on locating transmission equipment
from now. It is much easier to identify a
on private property—with no oversight by
handful of projects that will expand either
the Department of Information Technology
the accessibility or the reliability of
and Telecommunications (DoITT).
telecommunications services throughout the city in the shorter-term future. One project, placing wireless transponders
To facilitate this process, DoITT issued a Request for Proposals in early 2004. Six companies were subsequently granted
on street pole tops, is actually part of a
franchises, including one company that
broader city initiative aimed at expanding
will be providing telephone access over the
wireless coverage throughout the city. In
Internet—which should provide a lower
addition to pole tops, the city is actively
cost alternative for phone service to low-
identifying other property it owns or controls,
income families. The franchises themselves
such as schools, office buildings, and garages,
run for a period of up to 15 years, and
that may be made available to wireless
provide the company with the right to install
carriers that desire expanded coverage. Another two projects are wholly private sector initiatives. One, broadband over power lines, is a technology that has been
and use telecommunications equipment on streetlights, traffic signals, and highway sign support poles. Installation of the antennas is
employed to a limited extent by utilities
expected to begin in 2005. In addition to
here and elsewhere for some time, but has
street-based poles, DoITT is also
yet to find a sizable commercial market.
working with other agencies to identify
The concept is simple: take advantage
other city facilities—including office
of existing power lines as channels for
buildings, schools, and garages—that may
information communication. The execution
serve as useful transmission points to
is more difficult. In contrast, the other private sector
improve and expand cellular coverage across the city. A previous effort to locate cell
project—the antenna proposed for the top
phone antennas on schools ran into
of the new Freedom Tower in lower
significant community opposition and
Manhattan—involves an old and proven
was withdrawn.
technology: radio transmission. Once built, the project would simply involve the relocation of radio transmission activity from one place in the region—in most cases the Empire State Building—to another.
Broadband over Power Lines
Freedom Tower Broadcasting
The concept of using power lines for
The Freedom Tower, which will rise 1,776
communication purposes is not new: utility
feet above the ground at the former
companies have for years been using their
World Trade Center site, is intended to be
own lines for various relay and control
the centerpiece of the rebuilding of
tasks. These applications require minimal
lower Manhattan. It will also be the world's
bandwidth and low frequency and have
tallest building, or at
been largely successful. However, the use of
least the world's tallest
power lines for high-bandwidth, two-way
freestanding structure,
transmission involving retail customers has
taking into account the
remained illusive—until now.
broadcast antenna that
There are signs that the concept may soon come of age. Advances in chip design and electronics technology have improved
will rise to 2,000 feet. The antenna is designed to do more than
delivery, and the explosion in demand for
simply pierce a height
consumer broadband services has produced
record. It is intended to
a stronger market. Equally important,
be home to New York
deregulation in the electricity industry
City broadcasters who
has taken firms like Con Edison out of the
historically relied on the
generation business entirely, leaving
antenna on the south
only their distribution and transmission
tower of the World Trade
assets as core businesses. Increasing
Center. In specific, the
the value of those assets by devising new
Metropolitan Television
revenue sources from them is more
Alliance—which includes city channels 2,
important than ever.
4, 5, 7, 9,11, and 13—signed a Memorandum
Only one utility, in Cincinnati, has rolled
of Understanding (MOU) with Larry
out broadband over power line technology
Silverstein, the Freedom Tower's developer,
on a commercial basis in the United States.
in 2003. The intention was to relocate
Here in New York, a trial program is
their transmissions from their temporary
currently under way involving Con Edison
home atop the Empire State Building.
and Ambient power line broadband
The MOU marked a departure from the
systems: a number of electronic devices have
alliance's earlier plans—which was to
been deployed at points within the power
build a 200-foot freestanding broadcast mast
distribution system to overlay a separate
in Bayonne, New Jersey. Relying on the
communications network on the power
Freedom Tower would theoretically save
lines. This network is delivering broadband
money and effort, but it is not without
services to a limited number of residences
its technical unknowns—most of them
and a government facility. The trial has been
a function of the off-center location of the
successful to date, opening the door for
spire on the building's roof. Questions
commercialization of the technology at
raised about the spire include how it might
some point in the future.
behave in high winds, what kind of material it should be made of so as not to interfere with broadcast signals, and whether the signal sent out from it would be blocked in any way by the building's shadow.
The Works
The Future
Keeping It Clean
The capital budgets of the Department of Environmental Protection and the Department of Sanitation are among the
The Lloyd Aquifer For a number of years, the city's Department of Environmental Protection has been looking at ways of storing water underground to minimize the impact of droughts. Among the most promising technologies being explored is something known as
largest in city government, though much
"ARS"—aquifer recovery systems. The idea
of what they build is not particularly
is to inject potable water from the
new or interesting and is simply replacement
upstate system into the Lloyd Aquifer—
for facilities that have grown too old or
layers of porous rock deep beneath
too decrepit to carry out their original
Brooklyn and Queens—during periods of
mission effectively. But there are now on the table a number
surplus, and pump it out during times of need. The aquifer would serve as a sort
of novel and challenging projects aimed
of underground reservoir, able to provide
at improving the health of the city. Two
water to a much larger audience than
relate to improved management of the
the barrier beach communities that it
city's water supply. The Lloyd Aquifer project
serves today.
involves an experiment with "water banking" as a way to expand the city's ability
Subterranean banking of water is a wellestablished practice in dry regions, such
to provide water to consumers in times
as California and Nevada, and in New
of water shortage or drought.
Jersey—where the rock formations are not
The Croton filtration plant project is less notable for its proposed technology than
dissimilar to those existing in Brooklyn and Queens. Although it has never been used
for the fact that it is being built at all. Its
in the city, engineers are optimistic about
opening will mark the first time that
its prospects: the clay cap of the Lloyd Aquifer
New York's water supply has been subject
would likely protect the water in the
to the filtering requirements that have
aquifer from sources of land contamination,
applied across the country for years, and
and the freshwater would inhibit
will signal an end to a bitter battle over
saltwater intrusion.
the siting of the facility in Van Cortlandt Park in the Bronx. Another new initiative involves the city's
The ARS concept is expected to undergo a 14-month pilot test beginning in 2005: four observation wells will monitor the
garbage. For the first time since the
aquifer's performance, and injected water
announcement of the closure of Fresh Kills,
will be tested for research purposes before
the city is on the verge of embracing
being discharged into the sewer system.
a new and relatively sophisticated system of waste disposal—one that relies on existing marine facilities to containerize the city's municipal waste and, in doing so, transform it from an environmental problem to a readily transportable export commodity.
The Croton Filtration Plant
Containerized Garbage
After a decade of battling, first with federal
Like every county in the state, New York City
environmental agencies and then with
is required to have a 20-year plan for
local activists, the city is at last moving ahead
disposing of its solid waste—but it doesn't.
with plans to build a water filtration
The relatively sudden closure of its
plant under the Mosholu Golf Course in Van
historic landfill in Staten Island left it with
Cortlandt Park in the Bronx. This plant
a network of marine transfer stations
would filter the relatively small percentage—
and barges, but no destination for the waste.
10 percent—of city water coming from
Since 2001, its marine transfer stations
the Croton system.
have lain dormant and most of its residential
In most places across the country,
waste has been hauled to transfer
federal law requires that drinking water be
stations in the outer boroughs, where it
filtered to screen out impurities. While
is shifted to larger tractor trailers for
New York City has historically been granted
delivery to landfills in neighboring states.
a waiver from this mandate for its Catskill
All that will change if the city is
and Delaware water on account of their
successful in implementing its new 20-
purity, the Croton system—located in a more
year plan for waste disposal. It envisions a
developed and faster growing suburban
network of reactivated marine transfer
area—does not meet the more stringent
stations exporting containerized garbage by
criteria for filtration avoidance. Since
barge or rail to landfills in the Midwest
1998, when the city was forced to enter into
and South. Containers of waste
a consent decree with federal
packed at the rebuilt transfer
EPA requiring the completion of the plant
stations would be barged
on a certain timetable, it has been fined
to either on-dock rail facilities
more than $400,000 for its failure to meet
in the harbor, where they
federal standards for drinking water.
would move to railcars for their
The project is an expensive one, made
journey to a disposal site, or
more so by the stiff opposition the
to normal berths in the harbor,
project aroused from neighborhood and
where they would be loaded
environmental interests in the Bronx.
onto oceangoing coastal barges.
To placate these interests, the city agreed to spend $220 million on unrelated
The idea of containerized waste is not entirely new: a facility run by Waste
improvements to parks in the Bronx—
Management operates at Harlem River
for playgrounds, running tracks,
Yards in the Bronx. But by embracing the
landscaping, equipment, and waterfront
concept of containerized waste so
access—in addition to the estimated
enthusiastically, the city is expecting to
$1.2 billion cost of constructing the
take an estimated three million truck
underground filtration plant itself.
miles off the road each year—a boon both to environmentalists and to residents in the communities now home to the transfer stations.
The Works
Acknowledgments
Acknowledgments There are many people who have contributed facts or information to this book, but only a handful responsible for what sets it apart from so many others. Having struggled for more than a year with book designers who couldn't fully grasp the idea of interweaving graphics and text, the partnership with Alexander Isley and his team has been more than serendipitous—it has been an honor and a pleasure. Their professionalism and enthusiasm over the past few months could not have been greater, and the book reflects both. Among Alex's worthy crew, one name stands out above the others: George Kokkinidis. On the back of a one-day course with Edward Tufte, the dean of information graphics, George was able to conceptualize each and every section of this book— in ways that bordered on the spectacular. His ability to digest my conceptual vision for this book and translate it into a series of more than a hundred distinct and compelling spreads, while managing a far-flung team of graphic artists, has been an inspiration to us all. What George has been to graphics, Wendy Marech has been to text—providing first-class research support over a period of two years. Although the research process may at times have been fun for her, it has been anything but easy. For all the people who cooperated in providing information or who took her on behind-the-scenes facility tours, there have been an equal number who refused to take her calls or answer her questions. Without her persistence and
commitment—and there are very few cases
Kelly, Don Lotz, Louis Menno, Ken Philmus,
in which it did not pay off—there would
Joe Sardo, Joe Seebode, and Ken Spahn.
have been no book to write. Myriad organizations and individuals
Many other individuals contributed their expertise, including Ken Stigner of
provided information along the way. The
Vollmer Associates, Bruce Lieberman of
Department of Environmental Protection;
the New York £r Atlantic Railroad, Sal
the Department of Information
Catucci of American Stevedoring, Captain
Technology and Telecommunications; the
W. W. Sherwood of the Sandy Hook
Department of Sanitation; the Department
Pilots Association, Matthew D'Arrigo of
of Transportation; the Department of
Hunts Point Cooperative Market, John
City Planning and the Economic Development
Arrowsmith and Rich Wolf of ABC, Creighton
Corporation—all of the City of New York—
Pritzlaff of Seagrave, Tom Peitz of
provided ongoing assistance. Among
FedEx, Ron Fridman of Duncan Parking
others, thanks are due to Marty Bellew,
Meters, Peter Scorziello of Synagro,
Mike Bellew, Tanessa Cabe, Agostino Cangemi,
Ellen Neises of Field Operations, Sam
Alice Cheng, Tom Cocola, Ed Corbett,
Schwartz of Sam Schwartz Engineering,
Walter Czwartacky, Rocco DiRico, Anthony
Tom Schulze, Ted Olcott, David Lazecko,
Etergineoso, Magdi Farag, Renzo Ferrari,
Jim Larsen, and the staff of the New-York
Salome Freud, Andrew Genn, Doug Greeley,
Historical Society.
Robert Kuhl, Venetia Lannon, Peter
To those who helped get this idea out
McKeon, Jeff Manzer, Ralph Mondella,
of the starting block—Silvio da Silva, Sloan
Michael Mucci, David Nati, Henry Perahia,
Harris at I CM, and above all Ann Godoff
Gil Quiniones, Bruce Regal, Andrew
at Penguin Press—I am most grateful. I am
Salkin, Jack Schmidt, Girish Shelat, Tom
thankful, too, to those at Penguin who
Simpson, Gerard Soffian, Harry Szarpanski,
helped bring it over the finish line in what
and John Tipaldo.
I consider record time, in particular Liza
Other public agencies, including the Port
Darnton. But the largest debt of all is
Authority of New York and New Jersey,
owed to those who patiently watched the
the New York State Department of
marathon itself from the dining room
Transportation; the U.S. Coast Guard, the
sidelines—to my daughter Rebecca, who
MTA; the U.S. Army Corps of Engineers,
loves to write, and to my son Ned, who
the United States Postal Service, and
is passionate about how things work. For
Transcom also proved tremendously helpful.
your good-natured acceptance of yet
In particular, I am grateful for input
another adult activity in our busy home, I
provided by Bob Beard, Mike Bednarz,
can say only the biggest of thank-yous—
Amrah Cardoso, Jamie Cohen, Doug Currey,
and hope that one day you get as much
Bob Durando, Matthew Edelman, Bob
pleasure in reading The Works as I have had
Glantzberg, Lt. Michael Keane, Victoria Cross
in writing it.
The Works
C o n t r i b u t i n g A r t i s t s I a m also i n d e b t e d t o
Image C r e d i t s Pages 2, 44 (right), 68, 86, 116, 124,
a n u m b e r of s u p e r b i l l u s t r a t o r s a n d p h o t o g r a p h e r s
136, 153 (two i m a g e s ) : Collection of T h e New-York
w h o a r e r e s p o n s i b l e for t h e a r t t h a t i n m a n y
H i s t o r i c a l S o c i e t y ( n e g a t i v e n o . 42616, n e g a t i v e n o .
w a y s f o r m s t h e b a c k b o n e of t h i s b o o k . T h e y s t r u g g l e d
77578d, n e g a t i v e n o . 72507, n e g a t i v e n o . 50756,
mightily to meet our ambitious deadlines a n d
n e g a t i v e n o . 77582d, n e g a t i v e n o . 77577d, n e g a t i v e
ultimately performed well beyond our admittedly
n o . 50739, a c c e s s i o n n o . X.47, n o . 74563).
high expectations.
4 (left): T r a n s c o m . 9 (bottom), 10, 20 ( e v o l u t i o n of a s t r e e t sign), 47 ( m a p ) :
A a r o n A s h l e y 6, 9, 12, 18, 78, 84, 96, 1 0 0 , 1 0 6 , 1 0 8 ,
N e w York City D e p a r t m e n t of T r a n s p o r t a t i o n , Division
1 1 5 , 1 1 7 , 1 2 0 , 1 2 7 , 1 2 9 , 1 3 0 , 1 4 6 , 1 6 0 , 1 6 6 , 167, 172, 173,175,
of Traffic P l a n n i n g , 2005. P e r m i s s i o n g r a n t e d b y
175, 178, 193, 196
t h e N e w York City D e p a r t m e n t of T r a n s p o r t a t i o n .
M i c h a e l F o r n a l s k i 23, 39, 40, 52, 55, 66, 70, 84, 9 4 , 1 0 5 ,
15 (bottom): © 1998, 2001, F u n d for t h e City of N e w York.
126,127,138,147,177,180,187,190,197
22 (top): C o u r t e s y of t h e N e w York City D e p a r t m e n t
Roger G a r b o w 1 1 , 14, 36, 49, 183
of Design a n d C o n s t r u c t i o n , i l l u s t r a t i o n b y Charles
H y p e r a k t Design G r o u p 24, 47, 71, 76, 87, 88, 89, 93, 98,
Hearn, Jr.
1 0 2 , 1 0 3 , 109, i n , 1 1 3 , 1 1 8 , 1 3 7 , 1 4 1 , 143, 147, 148, 154, 158,
22 (bottom): Courtesy of t h e N e w York City D e p a r t m e n t
165, 168, 169, 171, 174, 177, 179, 183, 186, 188, 191, 194, 203
of Design a n d C o n s t r u c t i o n .
J i m Kopp 12, 18, 30, 54, 58, 62, 67, 77, 83, 96, 102, 104,
24 USDA Forest Service N o r t h e a s t e r n Research S t a t i o n
106, 114, 128, 129, 137, 159, 163, 164, 176, 186, 199, 201, 203
a n d N o r t h e a s t e r n A r e a S t a t e a n d P r i v a t e Forestry.
J a s o n Lee 5, 7, 9, 19, 20, 41, 43, 50, 64, 72, 73, 74, 85,
(Available f r o m Open Accessible Space I n f o r m a t i o n
88, 95, 1 0 7 , 1 2 5 , 1 3 0 , 140, 143, 149, 189, 202
S y s t e m (OASIS), w w w . o a s i s n y c . n e t )
M g m t . Design 3, 5, 8, 1 5 , 20, 27, 28, 29, 3 1 , 37, 38, 42,
26 (two), 44 (left): Science, I n d u s t r y & Business Library,
45, 59, 69, 72, 78, 81, 82, 95, 99, 133, 134, 147. 148, 155.
T h e N e w York Public Library, Astor, Lenox a n d Tilden
161, 162, 181, 182, 198, 201
Foundations.
A r t h u r M o u n t 19, 21, 25, 32, 155
49 ( s c r e e n s h o t ) , 54 (bottom), 77 (right): Courtesy of t h e
R a n d y O'Rourke 4 5 , 1 4 0 , 1 4 3 , 1 6 0 , 1 7 9 , 201, 209
P o r t A u t h o r i t y of N e w York a n d N e w Jersey.
S e y m o u r S c h a c h t e r 14, 32,161
49 (bottom): The N a t i o n a l City Company, d r a w i n g by
Chris S c h a p p e r t 7 , 1 3 , 23, 5 4 , 1 2 9 , 1 3 2 , 1 3 5 , 1 3 8
Cass Gilbert, 1926.
M a r k S c h r o e d e r 144, 145
53 (right): Courtesy of t h e MTA Bridges a n d T u n n e l s
M a r t y S m i t h 23, 33, 34, 60, 61, 74, 119, 200
Special A r c h i v e .
Steve S t a n k i e w i c z 1 0 , 1 5 , 16, 17, 22, 42, 46, 48, 79, 1 0 5 ,
60 (bottom): N e w York Regional Railroad, J e r s e y City,
112, 1 1 5 , 121, 129, 132, 156, 165, 167, 192
N e w Jersey.
63 (right): J o s e p h A. Tischner.
145 (top): Courtesy of P a n a s o n i c Broadcasting.
67 P h o t o g r a p h b y P r e s t o n S. J o h n s o n , collection of
147 (left): N e w York City D e p a r t m e n t of I n f o r m a t i o n
W a y n e D. Hills.
Technology a n d T e l e c o m m u n i c a t i o n s .
71 P h o t o g r a p h b y A. McGovern.
152 F i f t h A v e n u e , l o o k i n g s o u t h f r o m 42nd S t r e e t ,
72 (screen s h o t ) : Courtesy of t h e U n i t e d States Coast
c. 1880. M u s e u m of t h e City of N e w York.
Guard Activities, New York.
164 (bottom): Local U n i o n #147 L.I.U.N.A.
75 (screen s h o t ) : © Great Lakes Dredge & Dock Co.
169 (right), 179 (bottom): R e p r o d u c e d w i t h
79 (left), 98 (bottom left): N e w York City Economic
p e r m i s s i o n of t h e N e w York City D e p a r t m e n t of
Development Corporation.
Environmental Protection.
80 Cradle of Aviation M u s e u m , G a r d e n City, N e w York.
170 P h o t o g r a p h b y C. S m i t h & K. Stigner, Vollmer
92 (left): Edison u n d e r g r o u n d system i n 1883, M u s e u m
Associates LLP.
of t h e City of New York; (right): Edison's l a r g e d y n a m o -
185 P i c t u r e C o l l e c t i o n , T h e B r a n c h L i b r a r i e s ,
e l e c t r i c g e n e r a t o r , 1881, M u s e u m of t h e City of
T h e N e w York P u b l i c Library, Astor, L e n o x a n d
New York.
Tilden Foundations.
98 (top): E n t e r g y C o r p o r a t i o n .
191 (top): W a s t e M a n a g e m e n t of N e w York, LLC.
98 (bottom right), 113 (right): KeySpan C o r p o r a t i o n .
192 (bottom): Field O p e r a t i o n s .
99 (right): Used b y p e r m i s s i o n of t h e N e w York
195 Hugo N e u C o r p o r a t i o n .
I n d e p e n d e n t System Operator.
207 Design b y NJ T r a n s i t / S y s t r a C o n s u l t i n g , I n c .
106 (bottom left): T h e Blizzard of 1888, N e w S t r e e t
210 © 2004 V e r d a n t Power, LLC.
looking t o w a r d Wall Street. Photograph: Brown Brothers.
213 Lower M a n h a t t a n D e v e l o p m e n t Corp.
M u s e u m of t h e City of N e w York.
215 C o u r t e s y of t h e N e w York City D e p a r t m e n t
110 S t r e e t l a m p , s t a n d a r d t y p e . M u s e u m of t h e City
of S a n i t a t i o n . Greely a n d H a n s e n , LLC a n d
of New York.
Dattner Architects.
m (bottom): E n e r g y I n f o r m a t i o n A d m i n i s t r a t i o n , Office of Oil & Gas. 118 (right): Courtesy of Con Edison. 125 (bottom): Courtesy of t h e E m p i r e City S u b w a y Company, L i m i t e d . 133 ( p h o t o g r a p h ) : K i m b e r l e e H e w i t t . 142 P h o t o g r a p h y Collection, M i r i a m a n d I r a D. W a l l a c h Division of A r t , P r i n t s a n d P h o t o g r a p h s , T h e N e w York Public Library, Astor, Lenox a n d Tilden F o u n d a t i o n s .
The Works
A
A t r a i n 27, 29, 30
e x p a n s i o n j o i n t s 50
sewage s y s t e m i n 170, 174
AA t r a i n 27
AT&T 124-25, 127
first 44
s t e a m p l a n t s i n 119
ABC TV 144, 149
automated vacuum-assisted
l o n g e s t 46
s u b w a y s y s t e m i n 27
m a i n t e n a n c e a n d r e p a i r of
w a t e r s y s t e m i n 164, 214
c o l l e c t i o n (AVAC) 199
a c c i d e n t s , t r a f f i c 4-5, 6
a u t o m o b i l e c a r r i e r s 73, 77
ACS 190-91
50-51
B r o o k l y n B a t t e r y T u n n e l 45, 52-53
m a p of 47
B r o o k l y n Bridge 44, 45, 46, 48
n u m b e r of 92
B
m o s t f r e q u e n t l y o p e n e d 47
B r o o k l y n N a v y Yard 119
w a t t a g e u s e d b y 95
b a n a n a s , d i s t r i b u t i o n of 87
m o v a b l e 46-47
B r o o k l y n T e r m i n a l M a r k e t 86, 88
B a n k of t h e M a n h a t t a n
n u m b e r of 46
B r o o k l y n U n i o n Gas 113
o l d e s t 44
Brooklyn Wholesale Meat Market
air conditioners
aircraft
84
Air E x p r e s s I n t e r n a t i o n a l air freight
83
80-85
Air T r a i n 207
C o m p a n y 153
86, 88
B a n k St. 13
o p e r a t i o n of 49
barges
p a i n t i n g of 51
B R T l i n e 27 B t r a i n 27, 29, 30
a i r w a v e s 142-49, 212-13
g a r b a g e 192
p e d e s t r i a n 19
Albany, N e w York 104
power
p e d e s t r i a n access to 46
B u i l d i n g s , D e p a r t m e n t of 18
A l e x a n d e r H a m i l t o n Bridge 45
s l u d g e 179
r a i l r o a d - o w n e d 46, 47, 209
b u l k e r s 73
98
t y p e s of 46-47
Allis C h a l m e r s C o r p o r a t i o n 98
B a r n e g a t s h i p p i n g l a n e 70
a l u m i n u m 168
b a s k e t s , l i t t e r 186
b r o a d b a n d 213
A m b i e n t 213
B a t t e r y P a r k 12
broadcasting
A m b r o s e C h a n n e l 69, 74
B a y o n n e Bridge 44, 48, 209
f u t u r e of 212-13
American Broadcasting
Bay Ridge, B r o o k l y n 72
r a d i o 148-49
C o r p o r a t i o n . See ABC TV
B e a c h , Alfred
26
Burr, A a r o n 153 bus(es) b u l b s 10 h i g h w a y l a n e s for 54 B u s i n e s s I m p r o v e m e n t Districts (BIDs) 186
s a t e l l i t e 145, 147
Business I n t e g r i t y Commission 198
Bell A t l a n t i c 125
B r o a d St. 170
Bell o p e r a t i n g c o m p a n i e s 125
B r o a d w a t e r T e c h n o l o g i e s 211
B u t t e r m i l k C h a n n e l 182
Bell T e l e p h o n e 124
B r o a d w a y Bridge 45
b u t t o n s , traffic l i g h t 7
Amfels S h i p y a r d 177
Berlin Airlift
Bronx, t h e
A m t r a k 44, 207
b i c y c l e l a n e s 10
cable t e l e v i s i o n i n 147
c
Big Allis 98
g a r b a g e r e m o v a l i n 191
cables
A m e r i c a n P n e u m a t i c Service C o m p a n y 136 A m e r i c a n Ref-Fuel
AM t r a n s m i s s i o n
190-91
148, 149
80
A n a c o s t i a a n d Pacific R a i l r o a d 63
b i o m a s s e n e r g y 100
m a r k e t s i n 86, 88, 89
c o a x i a l 146
A n c h o r a g e C h a n n e l 74
b i o s o l i d s . See s l u d g e
p a y p h o n e s i n 132
e l e c t r i c a l 92, 106-7
a n t i q u e s 82
b l a c k o u t s 38, 108-9, 182
p o w e r p l a n t s i n 98
B l i z z a r d of 1888 106, 124, 185
r a i l f r e i g h t i n 62
cable t e l e v i s i o n 146-47
appliances
94-95
aqueducts
156-57
t e l e p h o n e 128-29
BMT l i n e 27, 3 1 , 32
s u b w a y s y s t e m i n 27
Cablevision 146, 147
a q u i f e r r e c o v e r y s y s t e m 214
Bombardier
w a t e r s y s t e m i n 215
Cable & W i r e l e s s 127
A r k a n s a s , r e c y c l i n g i n 180
B o n d St. 13
B r o n x T e r m i n a l M a r k e t 67, 86, 88
A r m y Corps of E n g i n e e r s 74, 182
B o s t o n Post Road 136
B r o o k l y n 53
a r t , i m p o r t a n d e x p o r t of 82
boxes
A r t h u r Kill 74
call 49
a s b e s t o s 119 A s h o k a n R e s e r v o i r 153, 156, 168 a s p h a l t 12
34
cable t e l e v i s i o n i n 147
California w i n d p o w e r 211 z i p codes 140
m a r i t i m e t r a d e i n 68, 72
call b o x e s 49
fire a l a r m 135
m a r k e t s i n 86, 88
calls, t e l e p h o n e 126, 129, 130-31
r e l a y 49
p a y p h o n e s i n 132
cameras
B r a z i l , m a r i t i m e t r a d e w i t h 76
p o w e r p l a n t s i n 98
b r i d g e ( s ) 44-51. See also specific
r a i l f r e i g h t i n 60
bridges
b r i d g e 49 traffic l i g h t 8-9 Canada
b u s i e s t 45
n a t u r a l gas from
c a m e r a s o n 49
911 access 134
d e f i n i t i o n of 46
no
221
C a n a d i a n Pacific 59
f u t u r e of s e r v i c e 212
c o m p o s t i n g 197
D
C a n a r s i e B r o o k l y n 86
l o w f r e q u e n c i e s for 142
c o m p r e s s o r s , g a s 112
d e a d l e t t e r office 139
computers
d e - i c i n g b r i d g e s 51
C a n n o n s v i l l e Reservoir 168
m a r k e t for 130
carfloats 6o, 208
n u m b e r of u n i t s 92
n u m b e r of 92
D e l a w a r e A q u e d u c t 156-57, 162-63
cargo
p a t h of call 130-31
w a t t a g e u s e d b y 94
D e l a w a r e County, N e w York
a i r 82
s u b s c r i b e r s , n u m b e r of 124
c o n c r e t e 1 2 , 18, 51
!54.155
m a r i t i m e 68, 76-77
C e n t r a l P a r k 152, 192
c o n d u c t o r , s u b w a y 32, 38
D e l a w a r e R i v e r 155
r a i l , i n t e r m o d a l 61-67
C h a n i n B u i l d i n g 140
Con E d i s o n 12, 22, 92, 93, 98,
D e l a w a r e w a t e r s y s t e m 154-55,
cargo s h i p s . See vessels, cargo
Chase M a n h a t t a n 153
99,107, 108, n o , 113, 115, 116,
c a r r i e r h o t e l s 127
Chelsea p u m p i n g s t a t i o n 161
118-19, 1 2 0 , 211, 213
156-57, 159, 162-63, 165, 215 d e m o l i t i o n d e b r i s 198
Carroll St. Bridge 45
Chicago, I l l i n o i s 135, 143
c a r r o t s , t r a n s p o r t of 66-67
c h i c a n e s 10
e l e c t r i c i t y c o n s u m e r s 93
Protection, Department
c a r s . See a u t o m o b i l e s ; r a i l c a r s
C h i n a 76
e n v i r o n m e n t a l l a w s u i t s b y 182
of (DEP)
cars, subway
Connecticut
c h l o r i n e 168
C o n r a i l 58
b r e a k d o w n s of 40
C h r i s t m a s t r e e s 188, 197
c o n s t r u c t i o n 198
cabs 39
C h r y s l e r B u i l d i n g 140
containers
DEP. See E n v i r o n m e n t a l
Design a n d C o n s t r u c t i o n D e p a r t m e n t of 22 Devon, E n g l a n d 210
d i s s e c t i o n of 34-35
C i n c i n n a t i , Ohio 213
a i r 80-81, 84
graffitiproof
35
City H a l l 26, 31
m a r i t i m e 68, 76-79
i n s p e c t i o n of 42
City I s l a n d 149
c o n t a i n e r s h i p s 72, 73
d i s a b l e d access, i n s u b w a y 35 dishwashers
d i a m o n d s , i m p o r t a t i o n of 82 d i e s e l e m i s s i o n s 186
City W a t e r T u n n e l No. 1 158
c o p p e r cable 128
City W a t e r T u n n e l No. 2 158, 161
Corcraft b a s k e t s 186
w a t e r u s e d b y 167
n e w 34
City W a t e r T u n n e l No. 3 158
Cormorant 177
w a t t a g e u s e d b y 95
n u m b e r of 26, 28
c l e a n fill 198
c r a n e s , c o n t a i n e r 79
r e d b i r d 34
c l e a r c h a n n e l f r e q u e n c i e s 149
g a n t r y 79
d i v e r t e r s , traffic 10
clocks 94
r a i l - m o u n t e d 79
DOT. See T r a n s p o r t a t i o n ,
coal
s h i p - t o - s h o r e 79
m a i n t e n a n c e a n d r e p a i r of 34. 42
r e t i r e d 35 signage 35 s t a t u s p a n e l 39
no
Coast G u a r d , U.S. 46, 72
D i s n e y W o r l d 199
D e p a r t m e n t of (DOT)
s t i c k 79
D o u g l a s t o n , Q u e e n s 159
s t o p p i n g m e c h a n i s m s 36
c o a x i a l cable 146
Cross-Harbor T u n n e l
s u p p o r t 43
c o b b l e s t o n e s 12-13
c r o s s w a l k s , r a i s e d 10
d r o u g h t s 214
v a c u u m 43
c o b r a s t r e e t l i g h t s 22
C r o t o n Falls R e s e r v o i r 168
d r y c l e a n e r s 117
c a t c h b a s i n s 176
Collect P o n d 152
C r o t o n R i v e r 152
D t r a i n 27, 29, 30
Catskill A q u e d u c t 156-57
c o m b i n e d s e w e r o v e r f l o w 174-77
C r o t o n w a t e r s y s t e m 152-55, 159,
Catskills, e l e c t r i c i t y g r i d 104
c o m m e r c i a l gas
Catskill w a t e r s y s t e m 12, 153-55,
c o m m e r c i a l w a s t e 184, 185, 190,
156-57, 159, 165, 215
no
191, 198
208
168, 214, 215 CSX R a i l r o a d 58, 59, 62, 66, 191, 209
d r e d g e r s 73, 74-75
E E a s t e r n I n t e r c o n n e c t i o n 102 East R i v e r 182, 184, 210
c a u s t i c soda 168
C o m m i s s i o n e r s ' P l a n of 1811 2
C t r a i n 27, 29, 30
East River S t a t i o n 118-19
cave-ins, s t r e e t 14
c o m m u n i c a t i o n s . See also specific
cultural institutions, electric
E d i s o n , T h o m a s 92, 106
CBS TV 143, 144, 149
forms of communications
c o n s u m p t i o n b y 95
cellar d o o r s , s t r e e t 18
e m e r g e n c y 134-35
c u r b s 1 2 , 18
cell p h o n e ( s )
f u t u r e of 212-13
c u r r e n t , e l e c t r i c a l 97
e n h a n c e d 911 134
m a n h o l e s for 125, 129 C o m m u n i c a t i o n s Act of 1934 142 C o m m u n i t y E n e r g y 100
811 T e n t h Ave. 127 e l e c t r i c i t y 92-109 b l a c k o u t s 38, 108-9, 182 c o n s u m p t i o n of 93-95 d e l i v e r y of 92 d i s t r i b u t i o n of 102-7 g e n e r a t i o n of 95-98
The Works
Index
f l o o d i n g , s u b w a y 42
r e c y c l i n g 194-96
m e t e r i n g 105
D e p a r t m e n t of (DEP) 44, 161,
Florida Power a n d Light Energy 211
r e s i d e n t i a l 184-97
N e w York S t a t e g r i d 98-99
167, 169, 171, 176-77, 180, 182, 214
f l u o r i d e 168
a f t e r s p e c i a l e v e n t s 189
f l u s h t r u c k s 106
t o n n a g e 184
g r i d s 102
p e a k c o n s u m p t i o n 94, 99
Environmental Protection,
E n v i r o n m e n t a l Protection Agency (EPA) 215
p o w e r p l a n t s 96-98 r e s e r v e m a r g i n 99 street lighting consumption 22, 95 for s u b w a y s y s t e m 38
e q u i p m e n t h u t , t e l e p h o n e 128
food w a s t e 197
g a r b a g e b a r g e s 192
Erie C a n a l 68
F o r m s a n d S u r f a c e s b a s k e t s 186
g a r b a g e t r a i n 191
e s c a l a t o r s , s u b w a y 28
F o r t W a d s w o r t h 72
gas. See c o m m e r c i a l gas; n a t u r a l gas
Essex R e s o u r c e R e c o v e r y F a c i l i t y
4 t r a i n 27, 29, 206
gaslight
Fox TV 149
gas m a i n s 114-15
E t r a i n 27, 29, 30
F r a n k l i n St. 152
gas m e t e r s 115
E u r o p e , w i n d p o w e r i n 211
F r e e d o m Tower 212, 213
e x c l u s i v e b u s l a n e 54
f r e i g h t e r s (cargo a i r c r a f t )
e x p r e s s c a r r i e r s . See i n t e g r a t e d
f r e i g h t t r a i n s . See r a i l f r e i g h t
GE B u i l d i n g 141
F r e s h Kills
g e n e r a t o r , e l e c t r i c a l , first 92
190, 191
u n d e r g r o u n d w i r i n g for 106-7 w h o l e s a l e m a r k e t for 99 E l e c t r i c R e l i a b i l i t y C o u n c i l of Texas 102 e l e v a t o r s , s u b w a y 28
t r a n s f e r s t a t i o n s 190, 215
FM t r a n s m i s s i o n 148-49
air carriers
E l m h u r s t , Q u e e n s 113
no
gas p l a n t s n o 84
g a t e w a y t r e a t m e n t s , traffic 10
e m e r g e n c y b r a k e s , s u b w a y 40-41
E x p r e s s r a i l 59
C h r i s t m a s t r e e r e c y c l i n g 188
g e o m e m b r a n e 193
emergency(ies)
e x p r e s s s u b w a y s e r v i c e 29, 38
c o n t a i n e r i z a t i o n f a c i l i t y 209
George W a s h i n g t o n Bridge 44-45,
E-ZPass 45
l a n d f i l l 185, 190, 192-93, 197
s u b w a y codes 40 telephone communications 134-35 Emergency Medical Service (EMS) 134-35
46, 48-49
f r u i t 87
g e o t h e r m a l e n e r g y 101
F
FSM East River A s s o c a t e s 118
G e r m a n y 76
FAA. See F e d e r a l A v i a t i o n
F t r a i n 27, 29, 30
Global Crossing 127
A d m i n i s t r a t i o n (FAA)
fuel cells 100-101
Global E n e r g y 12
E m p i r e City S u b w a y C o m p a n y 125
f a r m e r s ' m a r k e t s 86
F u l t o n F i s h M a r k e t 88-89
Global M a r i n e T e r m i n a l 69
E m p i r e S t a t e B u i l d i n g 95, 116, 117,
f a u c e t s 167
F u l t o n St. 86
g o n d o l a c a r s 60
141, 149, 213 Empire State Development C o r p o r a t i o n 140 employees b r i d g e s 49 p o s t a l 138 s a n i t a t i o n 184
G o v e r n o r s I s l a n d 69, 78, 184
FDR Drive 16-17 Federal Aviation A d m i n i s t r a t i o n (FAA) 113 Federal Communications C o m m i s s i o n (FCC) 142-43, 149 Federal Energy Regulatory C o m m i s s i o n 112
G o w a n u s Bridge 46
G G a n s e v o o r t M e a t M a r k e t 86, 88
G o w a n u s Canal 98, 182
g a n t r y c r a n e s 79
g r a f f i t i 35
garbage a n d garbage removal
g r a n i t e 13
c o l l e c t i o n r o u t e s 188
G r a v e s e n d , B r o o k l y n 72
c o m m e r c i a l 184, 185, 190,191, 198
g r a v i t y 159, 172
s u b w a y 26, 32, 38
FedEx 81, 83, 85
c o m p o s t i n g 197
G r e a t L a w n 152
311 s y s t e m 133
ferries
c o n t a i n e r i z a t i o n of 214, 215
G r e e n County, N e w York 154
t u n n e l s 55 EMS. See E m e r g e n c y M e d i c a l S e r v i c e (EMS) energy. See also specific forms of energy alternative sources, c o n s u m p t i o n of 100-101
c a r g o 60
d e s t i n a t i o n s for 191
G r e e n e St. 13
p a s s e n g e r 72
e q u i p m e n t for 186-87
Green Heron 177
f e r t i l i z e r 180-81, 197
e x p o r t a t i o n of 190-91
G r e e n p o i n t , B r o o k l y n 113
F i f t h Ave. 12
m a p s 190-91, 194
G r e e n v i l l e Yards 60, 208
f i l t r a t i o n 169
marine transfer stations
Grid P l a n 2-3
fire a l a r m b o x e s 135
190, 215
Grimes/Todt Hill, S t a t e n Island 159
Fire D e p a r t m e n t 1 3 , 134-35
o c e a n d u m p i n g 184, 194
G r i m m w a y 66
E n t e r g y C o r p o r a t i o n 98
firefighting
p u b l i c v e r s u s p r i v a t e 198
g r o u n d w a t e r 161, 169
Environmental Conservation,
fish 182-83
GTE 125, 127
5 t r a i n 27, 29, 206
G t r a i n 29
flat y a r d s 62
Gulf of Mexico, n a t u r a l gas from n o
r e n e w a b l e 210
D e p a r t m e n t of (DEC) 174, 182
159, 160, 200
floatables 176
223
K
M
H a c k e n s a c k River 69
c o m p o s t i n g i n 197
K a w a s a k i 34
M c A l l i s t e r T o w i n g 73
h a i r d r y e r s 94
r e c y c l i n g i n 194
Kensico R e s e r v o i r 156, 164, 168
M c L e a n , M a l c o l m 78
H a l m a r Cargo C e n t e r 83
solid w a s t e t r e a t m e n t i n
K e y S p a n 98, i n , 211
M a c o m b s D a m Bridge 45
Kill v a n Kull 69, 71, 74, 209
M a d i s o n Ave. Bridge 45
H u n t s P o i n t m a r k e t s 67, 86, 87, 89
King's Bridge 44
M a d i s o n W i n d Project 100
h a r b o r p i l o t s 70-71
h y d r a n t s , fire 159, 160, 200
K o r e a n A i r l i n e s 83
m a i l a n d m a i l s y s t e m 136-41
H a r l e m River Yards 190, 191, 215
h y d r o c a r b o n g a s e s . See n a t u r a l gas
Hartsfield A t l a n t a I n t e r n a t i o n a l
h y d r o e l e c t r i c p o w e r 100, 1 0 1 , 104
L
b o x e s 138
H y d r o - Q u é b e c 103
L a G u a r d i a , F i o r e l l o 53
d i s t r i b u t i o n of 138-39
h y d r o t u r b i n e s 210
L a G u a r d i a A i r p o r t 83
p n e u m a t i c 136-37
H e l m s l e y B u i l d i n g 140
lamps
s o r t i n g 138-39
H e n r y H u d s o n Bridge 45
l a n d f i l l s 185, 190, 192-93, 197
Hunts Point
H
179, 180
H a m m e r f e s t , N o r w a y 210 Hanover Square
206
A i r p o r t 80, 81 Hell Gate Bridge 44, 62
a u t o m a t i o n i n 138-39, 140
94
u n d e l i v e r a b l e 139 Manhattan
Ibis 177
l a w n s p r i n k l e r s 167
H e r o d o t u s 140
IESI 190-91
l e a c h a t e 193
b r i d g e s a n d t u n n e l s i n t o 45
Highbridge
Illegal D u m p i n g Task Force 201
l e a v e s , r e c y c l i n g 188, 197
cable t e l e v i s i o n i n 147
H i g h Line 58
i m p o r t s a n d e x p o r t s 82, 87
L i b e r t y St. 160
earliest streets 2
H i l l v i e w R e s e r v o i r 154, 156, 158,
i n c i n e r a t o r s 184, 185, 191
libraries, electricity
g a r b a g e r e m o v a l i n 190
H e r a l d S q u a r e 30
44
161, 164, 168
I n d e p e n d e n t Electricity Market
(HARS) 74 H o b o k e n , N e w J e r s e y 68
H o m e l a n d Security, D e p a r t m e n t of 72
Grid P l a n 2 m a r i t i m e t r a d e i n 68
I n d i a 76
l i q u e f i e d n a t u r a l gas 210, 211
p a y p h o n e s i n 132
Indianapolis International
l i t t e r b a s k e t s 186
pneumatic tube network,
Lloyd A q u i f e r 214
A i r p o r t 81
H o l l a n d T u n n e l 44, 45, 52-53, 54, 60, 164
c o n s u m p t i o n b y 95 L i n c o l n T u n n e l 45, 52-53, 54, 55
O p e r a t o r of O n t a r i o 103
H i s t o r i c A r e a R e m e d i a t i o n Site
m a p of 137
I n d i a n P o i n t 98
l o b s t e r s 82
s e w a g e s y s t e m i n 179
IND l i n e 27, 3 1 , 32, 206
local s u b w a y s e r v i c e 29, 38
s t e a m p l a n t s i n 119
Information Technology a n d
L o n d o n s u b w a y s y s t e m 28
s u b w a y s y s t e m i n 27
Long I s l a n d
traffic v o l u m e , i n - a n d
H o n e y b e e 120
Telecommunications,
h o o d s , sewage s y s t e m 176
D e p a r t m e n t of (DoITT) 1 3 2 ,
r a i l f r e i g h t for 60, 62-63
h o p p e r c a r s 60
146, 212
w i n d p o w e r o n 210
outbound
45
w a t e r s y s t e m i n 164
h o r s e m a n u r e 184-85
i n t e g r a t e d a i r c a r r i e r s 81, 83, 85
Long I s l a n d City 194
M a n h a t t a n B r i d g e 45
h o s p i t a l s 117
i n t e r s e c t i o n s , s t r e e t 6-7, 10
Long Island Power A u t h o r i t y 38, 211
M a n h a t t a n C o m p a n y , t h e 152
H o u s i n g A u t h o r i t y , N e w York
I r o q u o i s Gas i n
Long I s l a n d R a i l r o a d 63
m a n h o l e c o v e r s 12-13, 14, 172
I r o q u o i s p i p e l i n e 211
Long I s l a n d S o u n d 182, 210, 211
manholes
City 95, 188 H o w l a n d Hook M a r i n e T e r m i n a l 69,78
1
IRT l i n e 26-27, 3 - 3
2
I t a l y 76
Long I s l a n d S o u n d k e e p e r 182 Los A n g e l e s , C a l i f o r n i a 143 Los A n g e l e s I n t e r n a t i o n a l
H u d s o n River 69, 157, 161, 179, 182
c o m m u n i c a t i o n s services 125, 129 e l e c t r i c a l 1 0 3 , 106-7 s e w e r 172
A i r p o r t 81
H u d s o n River S t a t i o n 118
J
H u d s o n s h i p p i n g l a n e 70
J a m a i c a Bay 182
Louisville I n t e r n a t i o n a l A i r p o r t 81
Hugo N e u 194
J a m e s F a r l e y Post Office 140
Lower East Side 23
m a n u f a c t u r i n g , p o r t f a c i l i t i e s 77
h u m m o c k s 15
J a p a n Air Lines 83
Lower M a n h a t t a n D e v e l o p m e n t
maps
h u m p y a r d s 62, 64-65, 67
J e r o m e P a r k R e s e r v o i r 156, 168 J e r s e y City 68, 194
Corporation L t r a i n 27, 29
207
s t e a m 116
b l a c k o u t of 2003, 109 b r i d g e s 47
JFK A i r p o r t 80-81, 83, 206, 207
e l e c t r i c i t y g r i d 102-5
J. P. M o r g a n 153
gas p a t h w a y s
J t r a i n 27, 29, 46
JFK A i r p o r t c a r g o f a c i l i t i e s
in
m a i l s y s t e m 137, 141
83
m a p of 69
M e t Life B u i l d i n g 140
p a t h w a y s , m a p of
M e t r o C a r d 33
r e g u l a t i o n of i n d u s t r y 112
p n e u m a t i c m a i l n e t w o r k 137
M e t r o - N o r t h 67
r e p a i r a n d m a i n t e n a n c e of
power plants
M e t r o p o l i t a n M u s e u m of A r t
m a r i t i m e t r a d e 76 N e w York H a r b o r
69
98
s o u r c e s of 87
M e t r o p o l i t a n Television Alliance
r a d i o s t a t i o n l o c a t i o n s 148 r a i l f r e i g h t t e r m i n a l s 59
Metropolitan Transportation
s a n i t a t i o n s y s t e m 190-91, 194
A u t h o r i t y (MTA) 44, 95, 1 3 2 ,
s e w a g e s y s t e m 175, 179
206, 207
s t e a m s t a t i o n s 118
M i a m i I n t e r n a t i o n a l A i r p o r t 81
traffic i n 72-73
O p e r a t o r 99, 103 N e w York O r g a n i c F e r t i l i z e r
s t o r a g e a r e a s for 112-13
C o m p a n y 180
NBC TV 142, 143, 144, 149
213
sewage overflow i n t o 174
N e w York I n d e p e n d e n t S y s t e m
s y s t e m 120 s o u r c e s of n o , 112
116, 117
produce, international
in
N e w York P o w e r A u t h o r i t y 22,
n e c k d o w n s 10
38, 104
N e v e r s i n k R e s e r v o i r 168 N e w a r k , N e w J e r s e y 190
N e w York Public L i b r a r y 152
Newark International Airport
N e w York S t a t e alternative energy
80, 81, 83, 85
street network 3
M i c h i g a n , e l e c t r i c a l c o n s u m e r s 93
s t r e e t s m o o t h n e s s 15
m i c r o w a v e d i s h e s 145
N e w C r o t o n A q u e d u c t 156-57
s u b w a y s y s t e m 27, 3 1 , 37
microwaves, wattage
N e w E n g l a n d , e l e c t r i c i t y i n 103
e l e c t r i c a l g r i d 98-99
New Jersey
e n e r g y m a r k e t 103
traffic s y s t e m 8, 9, 72 w a t e r s y s t e m 1 5 3 , 154, 158, 165, 168, 169 z i p codes 141
c o n s u m e d b y 95 M i l f o r d , C o n n e c t i c u t 211
e n e r g y m a r k e t 103
m i l k t r a i n s 67
l a n d f i l l s i n 190, 191
M i n n e a p o l i s , d e a d l e t t e r office 139
l a w s u i t s b y 155, 185
m i l k f r o m 67 n a t u r a l gas c o n s u m p t i o n i n i n N e w York S t a t e D e p a r t m e n t of
M a r c y e l e c t r i c a l s u b s t a t i o n 104
M o r a n T o w i n g C o r p o r a t i o n 73
m a r i t i m e t r a d e i n 62, 68-69
m a r i n e t r a n s f e r s t a t i o n s 190, 215
Morgan Processing a n d
passenger rail t u n n e l from
m a r i t i m e f r e i g h t 68-79
D i s t r i b u t i o n C e n t e r 136
c o n s u m p t i o n i n 100
Transportation
44
N e w York S t e a m C o m p a n y 116 N e w York S u s q u e h a n n a a n d
206, 207
W e s t e r n R a i l r o a d 59
M o s c o w s u b w a y s y s t e m 28
r e c y c l i n g i n 194
i n t e r n a t i o n a l r o u t e s , m a p of 76
Moses, R o b e r t 53
solid w a s t e t r e a t m e n t i n 180
s h i p p i n g l a n e s 70
M o s h o l u Golf Course 215
New Jersey Transit
m o t o r m a n , s u b w a y 38
N e w J e r s e y T u r n p i k e 54
New York Times, The 92 N e w York W a t e r Q u a l i t y S u r v e y
c o n t a i n e r s 68, 76-79
m a r k e t s 86-89. See also s p e c i e
N e w York T e l e p h o n e C o m p a n y 124, 127
207
M o t o r V e h i c l e s , D e p a r t m e n t of 9
n e w s 144-45
M a r y l a n d , e l e c t r i c i t y i n 103
M t r a i n 27, 29, 46
n e w s t r u c k s 145
M a s p e t h , Q u e e n s 149, 186
m u n i c i p a l offices, e l e c t r i c i t y
N e w Year's Eve 189
911 s y s t e m 1 3 0 , 1 3 3 , 134-35
N e w York & A t l a n t i c R a i l w a y
9 t r a i n 27, 29, 30
markets
M a s p e t h H o l d e r s 113
c o n s u m p t i o n b y 95
183
N i p p o n Cargo Air Lines 83
59, 61, 63
m e a t m a r k e t s 86, 88, 89
munimeters
m e d i a n s 10
M u r r a y Hill R e s e r v o i r 152
N e w York C o n t a i n e r T e r m i n a l
M e r c e r St. 13
N
N e w York C r o s s - H a r b o r R a i l r o a d
m e t a l 194, 195
N a n t u c k e t s h i p p i n g l a n e 70
meters
National Broadcasting Company.
23
e l e c t r i c a l 105
p a r k i n g 23 w a t e r 167 methane
no
N e w York Gas C o m p a n y
b o t t o m of 70 c u r r e n t s 71
44,140
Norfolk S o u t h e r n R a i l r o a d 58, 59, 62
59, 60
N e w York H a r b o r
See NBC TV National Historic Landmarks
gas 115
n i t r o g e n t a n k s 129
68-69, 78-79» 87, 209
M e m p h i s I n t e r n a t i o n a l A i r p o r t 81
n i t r o g e n 182
no
N o r t h e a s t e r n U.S. e n e r g y m a r k e t 103 z i p codes 140 N o r t h River T r e a t m e n t P l a n t 178, 179
N a t i o n a l O c e a n S e r v i c e 71
d e p t h of 69, 71
n a t u r a l gas
d r e d g i n g of 74-75
N o r t h w e s t A i r l i n e Cargo 83
e n t e r i n g 70-71
NRG E n e r g y 98
d e l i v e r y of 110-15
floatables 176
N t r a i n 27, 29, 30
l e a k d e t e c t i o n 115
m a i n t e n a n c e of 74-75
c o m p o s i t i o n of
no
l i q u e f i e d 210, 211 o d o r a n t for 115
225
0
paving
Oak I s l a n d 62 Oakland International Airport 80, 81
Port Newark/Elizabeth Marine
b r i d g e s 51
T e r m i n a l 62, 68-69, 76-77, 209
s t r e e t s 12-13 pay phones
p o r t ( s ) , 68, 76-77. See also specific
132-33
ports
R r a d a r d e t e c t o r s 49 r a d i a t o r s , c l a n g i n g 121 radio
Oak P o i n t Yard 62, 67
PBS 149
o c e a n d u m p i n g 170, 171, 179,
P e a r l St. 92, 152
142 (USPS). See also m a i l a n d
f r e q u e n c i e s 72
p e d e s t r i a n ( s ) 3, 6-7
mail system
s t a t i o n s 143
184-85, 194
Postal S e r v i c e , U n i t e d S t a t e s 1 3 6 ,
b r o a d c a s t i n g 148-49
O'Hare I n t e r n a t i o n a l A i r p o r t 81
b r i d g e access for 46
p o t h o l e s 14-15
Ohio, landfills i n 190
b r i d g e s 19
p o w e r b a r g e s 98
oil 104, 106
d e a t h s of n
p o w e r l i n e s 102-5, 213
railcars 60-61 r a i l f r e i g h t 58-67
R a d i o C o r p o r a t i o n of A m e r i c a (RCA) 142, 143
Old Croton A q u e d u c t 156
r a m p s 18
p o w e r p l a n t s 96-98, 108-9
on-dock r a i l facilities 77
refuges 10
p r i m a r y f e e d e r s 1 0 3 , 104
c a r g o 61-67
1 t r a i n 27, 29, 30
traffic 19
p r o d u c e 66, 82, 86-87
classification y a r d s for 62-65, 67
130th St. M i l k y a r d 67
P e n n S t a t i o n 30
P r o d u c e E x c h a n g e 136
f u t u r e of 208, 209
140 West St. 127
Pennsylvania
Providence & Worcester
o n - d o c k f a c i l i t i e s 77
145th St. Bridge 45
c o m p o s t i n g i n 180
o p t i c a l fiber 128, 146
electricity i n 103
o r a n g e j u i c e 76, 77
l a n d f i l l s i n 190, 191
O r i e n t Overseas Line 79
Pennsylvania Station
R a i l r o a d 59 Public Broadcasting Service. See PBS p u b l i c t r a n s p o r t a t i o n 4, 26, 95.
t e r m i n a l s 59 transcontinental
66-67
R a n d a l l s I s l a n d 188, 197 R a s h i d , K a r i m 12
Osprey 183
Redevelopment Corporation
See also specific types of
R a v e n s w o o d , Q u e e n s 98
o v e n s , w a t t a g e c o n s u m e d b y 95
140
transportation
R a v e n s w o o d S t a t i o n 118
o v e r n i g h t c a r r i e r s . See i n t e g r a t e d air carriers Owls Head t r e a t m e n t p l a n t 179
P e p a c t o n R e s e r v o i r 168
P u b l i c W o r k s , D e p a r t m e n t of 13
p e r f u m e , i m p o r t a t i o n of 82
p u m p i n g s t a t i o n s , w a t e r 159, 161
P e r r y St. 13
P u t n a m C o u n t y 154, 155
r e c y c l i n g 188, 194-96. See also
Q
r e d b i r d s u b w a y c a r s 34
QB t r a i n 27
Red Hook, B r o o k l y n 53
Q t r a i n 27, 29, 30
Red Hook C o n t a i n e r T e r m i n a l
Philadelphia, Pennsylvania P
136, 143
p a i n t i n g b r i d g e s 51
p h o s p h o r i c a c i d 168 pigg g
Park Avenue Plaza 140
p i l o t s , h a r b o r 70-71
Québec 104
parking
p i p e l i n e s , g a s n o - i i , 112-13
Queens
t
n
e
p i p e 115
A m e r i c a (RCA)
specific items
p a p e r 194, 196, 198
i n
RCA. See R a d i o C o r p o r a t i o n of
68-69, 78 r e d - l i g h t e n f o r c e m e n t 8-9
a l t e r n a t e side of t h e s t r e e t 23
Piping Plover 177
a i r c a r g o c o m p a n i e s i n 81
r e e f e r s 73
m e t e r s 23
p l a n e s . See a i r c r a f t
AM t r a n s m i t t e r s i n 149
r e f r i g e r a t e d c a r s 60, 66
signs 20-21
p l u g uglies 160
cable t e l e v i s i o n i n 147
refrigerators, wattage
P a r k s , D e p a r t m e n t of 44, 132, 188
pneumatic tubes
Passaic River 69
Police D e p a r t m e n t 189
p o w e r p l a n t s i n 98
p a s s e n g e r b o a t s 72
p o n d i n g 14
s e w a g e s y s t e m i n 174
R e l i a n t 98
passengers, subway
population 3
s t e a m p l a n t s i n 119
r e m o t e c o n t r o l s 94
s u b w a y s y s t e m i n 27
r e s e r v o i r s 155, 162. See also
n u m b e r of 26, 28 p e r c a r p e r h o u r 29 p a v e m e n t s e n s o r s 49
136-37
P o r t A u t h o r i t y of N e w York a n d N e w J e r s e y 4, 44, 49, 55, 76, 78-79, 80, 95, 161, 207, 209
p a y p h o n e s i n 132
w a t e r s y s t e m i n 164, 214 Q u e e n s b o r o Bridge 45, 48
P o r t J e r s e y C h a n n e l 74
Q u e e n s B o u l e v a r d 6, n
P o r t J e r s e y R a i l r o a d 59
Q u e e n s M i d t o w n T u n n e l 45, 52-53 Qwest 127
c o n s u m e d b y 95 r e l a y b o x e s 138
specific reservoirs Rhode Island, electrical c o n s u m e r s 93
The Works
index
l o w e s t 30
R i c h m o n d T u n n e l 158, 161, 164
S e c a u c u s , N e w J e r s e y 207
60th St. S t a t i o n 118
R i k e r s I s l a n d 197
s e c o n d a r y f e e d e r s 103
60 H u d s o n S t r e e t 127
n u m b e r of 28, 30
R i v e r b a n k S t a t e P a r k 179
S e c o n d A v e n u e S u b w a y 206
s k i m m i n g vessels 177
S t a t u e of L i b e r t y 69 s t e a m a n d s t e a m s y s t e m 116-21
RJ t r a i n 27
s e e d s l u d g e 178
s l u d g e 171, 178, 180-81
r o a d w a y s . See s t r e e t ( s )
S e l k i r k Yard 62, 66, 208
s l u d g e b a r g e s 179
c o n s u m p t i o n of 116
robots, pipe inspection a n d
s e p t i c t a n k s 173
s n o o p e r t r u c k s 50
d i s t r i b u t i o n of 118-19
7 t r a i n 27, 29
s n o w m e l t e r s 203
e x p l o s i o n s 121
R o c k a w a y t r e a t m e n t p l a n t 179
74th St. S t a t i o n 118
snow removal
l e a k s 120
Rockefeller C e n t e r 117, 141, 143
s e w a g e a n d s e w a g e s y s t e m 170-83
repair
120,163
202-3
Snowy Egret 177
s t a t i o n s 118-19
R o n d o u t R e s e r v o i r 156, 168
b r e a k d o w n s 182
s o l a r p o w e r 1 0 0 , 101
w a t e r u s e d b y 116
Roosevelt, F r a n k l i n 53
c a t c h b a s i n s 176
Solid W a s t e 190-91
s t e a m m a i n s 119
Roosevelt I s l a n d 199
c o l l e c t i o n 172-73
South Brooklyn Marine Terminal
s t e r e o s , e l e c t r i c i t y u s e d b y 94
R o s e t o n , N e w York 162
c o m b i n e d sewer overflow
Roseville Yard 66
174-77
R o u t e 1 136
d e w a t e r i n g 171
Royal D u t c h S h e l l 211
m a n a g i n g effluent
R t r a i n 27, 29, 30
m a p s 175, 179
rush hour
p u m p i n g s t a t i o n s 178
l e n g t h of 3 i n t h e s u b w a y 29, 38 traffic s i g n a l s d u r i n g 6
182-83
s t o r m - w a t e r t r e a t m e n t 170, 172-73, 174 t r e a t m e n t a n d processing
t r e a t m e n t p l a n t s 170-71,
St. V i n c e n t ' s H o s p i t a l 117 s a l t d o m e s 203 s a l t s p r e a d e r s 203
178-79, 182 s e w a g e t r e a t m e n t p l a n t s 170-71,
s t o r m w a t e r 170, 172-73, 174
S o u t h St. 68
S t r e e t C l e a n i n g , D e p a r t m e n t of
S o u t h St. S e a p o r t 88
airwaves
185, 194 s t r e e t l i g h t s 22, n o s t r e e t ( s ) 2-23
s p e e d h u m p s 10
c l e a n i n g of 23, 200
speed limit 6
color 10
speed(s)
defects i n 14-15
s u b w a y 32, 38
e l e c t r i c a l w i r i n g of 106-7
traffic 9
h a r d w a r e for 15
split p h a s i n g 7
h i g h w a y c o m p o s i t i o n of 2, 3
S p r i n g f i e l d G a r d e n s , Q u e e n s 81
i n t e r s e c t i o n s of. See
S t a p l e t o n 72
178-79, 182
stick c r a n e s 79
S o u t h B r o o k l y n R a i l w a y 59
s p e c t r u m , e l e c t r o m a g n e t i c . See
178-81, 182 S
194,195
Staten Island
intersections, street l i g h t s . See s t r e e t l i g h t s
s a n d h o g s 164
S e w a r d P a r k h o u s i n g 117
S a n d y Hook, N e w J e r s e y 74
s e w e r p i p e s 12-13, 7
cable t e l e v i s i o n o n 146
m a p s 3, 8, 9
S a n d y Hook Pilots 70-71
s h a v e r s 94
E-ZPass c e n t e r o n 45
m a r k i n g s , r e p a i r 14
s a n i t a r y l a n d f i l l 192
s h i p p i n g . See m a r i t i m e f r e i g h t
m a n h o l e c o v e r s 12
m e d i a n s 10
S a n i t a t i o n , D e p a r t m e n t of 184,
s h i p p i n g l a n e s 70
m a r i t i m e t r a d e o n 68, 72, 78-79
m i l e s of 2
s h i p s . See v e s s e l s , c a r g o
p a y p h o n e s o n 132
n a r r o w i n g of 10
S a n i t a t i o n Police 201
s h o w e r s 167
p o w e r p l a n t s o n 98
o p e n c u t s 14
s a t e l l i t e b r o a d c a s t i n g 145, 147
s i d e w a l k s 1 2 , 18
r a i l w a y s y s t e m o n 28
p a v i n g m a t e r i a l s 12-13
s a t e l l i t e t o w e r s 37
S i e r r a B l a n c a , Texas 171
r e c y c l i n g o n 194
r e p a i r of 14-17
S c h o h a i r i e County, N e w York 154
signals
w a t e r s y s t e m o n 158, 161, 164
186, 202, 209, 214
schools e l e c t r i c i t y c o n s u m p t i o n b y 95 g a r b a g e c o l l e c t i o n f r o m 188
r
2
s u b w a y 36-37
S t a t e n I s l a n d R a i l r o a d 208, 209
traffic 6-7
stations, subway
signs a n d signage
signs 20-21 s m o o t h n e s s of 15 s y s t e m i z a t i o n of 2
a b a n d o n e d 31
t e x t u r e 10
seafood, i m p o r t a n d e x p o r t of 82
s t r e e t 20-21
e n t e r i n g 32-33
t h r u streets program 9
S e a g r a m B u i l d i n g 140
s u b w a y c a r 35
h i g h e s t 30
t y p e s of 2
S i l v e r L a k e , S t a t e n I s l a n d 161
u n d e r n e a t h t h e 12-13
6 t r a i n 27, 29, 206
w i d t h of 2
60th St. M i l k y a r d 67
street sweepers
200
s u b s t a t i o n s , e l e c t r i c a l 103, 104-5 S u b w a y s Control C e n t e r
40
s u b w a y s y s t e m 26-43
T
375 P e a r l St. 127
speeds 9
tall buildings
T h r o g s Neck Bridge 4, 45
violations
a i r t r a n s m i s s i o n a n d 146
t h r u streets program 9
w a t e r s u p p l y for 166
tide(s)
a n n o u n c e m e n t s i n 33
t a n k s h i p s 72, 73
breakdowns
telephone(s) and telephone
40-41
Car M a i n t e n a n c e D e p a r t m e n t 42
s y s t e m 124-35
8
train(s) f r e i g h t . See r a i l f r e i g h t
g a t e s 175
g a r b a g e 191
m o n i t o r i n g 71
to t h e p l a n e
p o w e r 210
subway, r e r o u t i n g 41
207
c a r s . See c a r s , s u b w a y
call b o x e s
disabled, access for 35
calls. See calls, t e l e p h o n e
N e w Year's Eve i n 189
Transcom
e l e v a t e d l i n e s 28
c a r r i e r h o t e l s 127
s u b w a y s t a t i o n 30-31
Transcontinental pipeline
e m p l o y e e s of 26, 32, 38
emergency communications
e x p r e s s service 29, 38
49
Times S q u a r e
infrastructure
first s u b w a y 26
125, 127, 128-29
local v e r s u s l o n g d i s t a n c e
flooding of 42
124-25
f u t u r e of 206-7
Time W a r n e r
Telecom 127
T r a n s p o r t a t i o n , D e p a r t m e n t of
t o k e n s , s u b w a y 32
JFK A i r p o r t l i n k
pay phones
Tokyo
r e p a i r s a n d m a i n t e n a n c e 129 i n s u b w a y s 132
toll c o l l e c t o r s
m a p s 27, 31, 37
s w i t c h i n g s t a t i o n s 127
track, subway
n u m b e r i n g of 27
u n d e r g r o u n d cables 128-29
cleaning
o t h e r s y s t e m s c o m p a r e d t o 28
underground infrastructure
c u r v e d 33
88
subway system
express
125, 128-29
(DOT) 4, 6, 14, 18, 22, 45, 46, 50
28
49
43
95
t r a v e l i n g s l u g 121 t r e e s 24-25, 188, 197 T-Rex 75 T r i b o r o u g h B r i d g e 45 Triborough Bridge a n d T u n n e l A u t h o r i t y 4, 53
29
g a p fillers 33
television
transportation, electricity consumption
m a i n t e n a n c e a n d r e p a i r 42-43
subway
30
fish e x c h a n g e
l o n g e s t l i n e 28
p a s s e n g e r s . See p a s s e n g e r s ,
6
t o i l e t s 167, 170
n u m b e r of 125 132-33
I Q
T r a n s i t A u t h o r i t y 27, 32, 59
h o u r s of o p e r a t i o n 28-29
p e n e t r a t i o n of 132
t r a n s f o r m e r s , e l e c t r i c a l 97, 1 0 3 , 104-5,
token booths
207
in
t o a s t e r s , w a t t a g e u s e d b y 95
N n codes 133-34
local service 29, 38
4-5
t r a n s f e r s t a t i o n s , g a r b a g e 190, 215
cable t e l e v i s i o n 146, 147
134-35
fare i n c r e a s e s 32
T r a n s C a n a d a 211
t r u c k i n g 58, 62, 6 6 , 1 9 0 , 208 t u g b o a t s 72, 73
p h o n e s i n 132
cable 146-47
g a u g e 29
Tully 190-91
p o w e r for 38
p e n e t r a t i o n of 143
i n t e r l o c k i n g s 37
t u n n e l - b o r i n g m a c h i n e s 164
sets 92, 94
local 29
t u n n e l ( s ) 44-45, 52-55. See also
t r a n s m i s s i o n s 213
m i l e s of 28
p r i v a t e l i n e s 26-27 p u m p r o o m s 42 r a i l y a r d s 42 s a t e l l i t e t o w e r s 37 Second A v e n u e S u b w a y
T r a d e W a s t e C o m m i s s i o n 198
T e n n e s s e e Gas i n , 112 tests, subway motor m a n 206
38-39
Texas E a s t e r n p i p e l i n e 112
specific tunnels b o r i n g m a c h i n e s 164
t r a f f i c , h a r b o r 72-73
cross-harbor freight
traffic, r o a d w a y
m a i n t e n a n c e a n d r e p a i r 55
208
signals 36-37
T h i r d Ave. Bridge 45
a c c i d e n t s 4-5, 6
new passenger rail
speeds i n 32, 38
30 Rockefeller C e n t e r 141
a m o u n t e n t e r i n g city 4
ventilation buildings
s t a t i o n s . See s t a t i o n s , s u b w a y
30 Rockefeller Plaza 143
c a l m i n g m e a s u r e s 10-11
w a t e r 158, 164-65
t r a c k . See t r a c k , s u b w a y S u l l i v a n County, N e w York 154, 155 Sunkist
66
207 54
33 T h o m a s St. 127
c a m e r a s 6, 8-9
turnstiles
T h o m a s P h i f e r a n d P a r t n e r s 22
f u t u r e of
26th W a r d t r e a t m e n t p l a n t 179
3 train
M a n h a t t a n in- a n d o u t b o u n d
27, 29, 30
311 s y s t e m 133
volume
206
45
S u n s e t Park, B r o o k l y n 194-95
m a p s 8, 9, 72
s w i t c h i n g s t a t i o n s 127
r e g i o n a l 4, 6 signals
6-7
30
2 t r a i n 27, 29, 30
The Works
u
V i c t o r S t a n l e y b a s k e t s 186
s a m p l i n g s i t e s 169
W o o l w o r t h B u i l d i n g 140, 141
U l s t e r County, N e w York 154, 155
Viele, E g b e r t L u d o v i c u s 153
s t e a m s y s t e m , u s e i n 116
W o o s t e r St. 13
U n i o n Pacific
violations, motorist 8
s t o r a g e 161
W o r l d F i n a n c i a l C e n t e r 140, 141
U n i t e d N a t i o n s 116, 117
V i r g i n i a , l a n d f i l l s i n 190, 191
t o w e r s 166
U.S. Lines 78
Visy P a p e r Mill 194, 196
treatment
U n i v e r s i t y H e i g h t s Bridge 45
v o l t a g e 97, 1 0 3 , 104, 105
w a t e r m a i n s 159, 162-63
UPN 149
V t r a i n 29
w a t e r s h e d s 155
66
W o r l d Trade C e n t e r 141, 149, 213 168-69
WQEW 149 W t r a i n 27, 29
W a t e r s i d e S t a t i o n 118
U p p e r East River 182 UPS 81, 83, 85
w
W a t e r T u n n e l No. 3 164-65
Y o n k e r s , N e w York 156
u p s t a t e N e w York. See N e w York
W a l l a b o u t M a r k e t 86
w a t e r w a y s . See also speci/ic waterways
Yorkville R e s e r v o i r 152
Wards Island t r e a t m e n t plant
State USPS. See Postal S e r v i c e , U n i t e d
g a r b a g e d u m p i n g i n 184
178, 179
S t a t e s (USPS)
sewage d u m p i n g a n d runoff
w a r e h o u s i n g 77, 80-81
I
u t i l i t i e s 12-13, 5- See also specific
171, 174-77- 179
W a r i n g , George 185, 194
utilities
vacuum cleaners, electricity
c l e a n l i n e s s of 182-83
W a r P r o d u c t i o n Board 98
w a t t s 94-95. 97
w a s h i n g m a c h i n e s 167
w a v e l e n g t h s 142
W a s h i n g t o n Bridge 45
Waverley, V i r g i n i a 191
W a s h i n g t o n H e i g h t s 159
w a v e s 71
W a s h i n g t o n M a r k e t 86
WCBS 149
v a l v e c h a m b e r s 164, 165
W a s h i n g t o n St. 86
W e e h a w k e n , N e w J e r s e y 67
V a n C o r t l a n d t P a r k Valve
W a s t e M a n a g e m e n t 190-91, 215
WEPN 149
W a s t e Service NY 190-91
West B r a n c h R e s e r v o i r 161
w a s t e s h e d s 190
W e s t c h e s t e r C o u n t y 93, n o ,
u s e d b y 95
C h a m b e r 164, 165 variable message sign sensors
49
154,156
v a u l t l i g h t s 18
w a s t e w a t e r 170
v a u l t s , s i d e w a l k 18
w a t e r a n d w a t e r s y s t e m 152-69
VCRs 94
Council I n t e r c o n n e c t i o n 102
a q u e d u c t s 156-57
vehicles, s a n i t a t i o n 186-87,
2 0 0
>
2
°3
Western Systems Coordinating
a q u i f e r r e c o v e r y s y s t e m 214
West Side H i g h w a y 6
c a p a c i t y , s t o r a g e 154
WFAN 149
V e r d a n t P o w e r 210
c o n s e r v a t i o n m e a s u r e s 167
W h e e l a b r a t o r T e c h n o l o g i e s 180
V e r i z o n 125, 127, 129
c o n s u m p t i o n 167
W h i t e s t o n e Bridge 4, 45
V e r r a z a n o N a r r o w s Bridge 4, 44,
f i l t r a t i o n 214, 215
w i l d l i f e 182-83
f u t u r e p r o j e c t s 214, 215
W i l l i a m s b u r g Bridge 45, 46, 48
g r o u n d w a t e r 161, 169
W i l l i a m St. 160
ventilation buildings
54
45, 46, 48, 70 V e s e y S t . 86
l e a k s 162-63
Willis Ave. Bridge 45
c r a n e s o n 79
l o c a l d i s t r i b u t i o n 158
w i n d p o w e r 1 0 0 , 101, 210, 211
h a r b o r e n t r y of 70-71
m a p s 153, 154, 158, 165, 168, 169
WISOR r o b o t 120
t y p e s of 73
m e t e r s 167
w o o d 166
v o l u m e of 72
p e o p l e d i s p l a c e d b y 153, 154, 155
Woods Hole O c é a n o g r a p h i e
vessels, cargo
209
I n s t i t u t e 163
v e s s e l s , s k i m m i n g 177
p r e s s u r e 159
Vessel Traffic Service 72
p u m p i n g s y s t e m s 159, 161, 166 r e g u l a t o r s 159 repair and maintenance r e s e r v o i r s 155
162-63
zip codes 140-41 Zone I m p r o v e m e n t P l a n 140 Z t r a i n 29, 46