People mover

Interior of Satellite Transit System, Seattle, Washington, USA. Opened in 1969, it is one of the first operational automated people mover systems in the world.
Yurikamome, Tokyo, Japan. More than 100,000 people a day use Yurikamome.
PHX Sky Train in Phoenix, USA, opened in 2013
Platform of Zhujiang New Town APM in Guangzhou, China
Innovia Monorail 300 in São Paulo, Brazil

A people mover or automated people mover (APM) is a type of grade-separated mass transit system. The term is generally used only to describe systems serving relatively small areas such as airports, downtown districts or theme parks, but is sometimes applied to considerably more complex automated systems.

The term was originally applied to three different systems, developed roughly at the same time. One was Skybus, an automated mass transit system prototyped by the Westinghouse Electric Corporation beginning in 1964.[1][2][3] The second, alternately called the People Mover and Minirail, opened in Montreal at Expo 67. Finally the last, called PeopleMover or WEDway PeopleMover, was an attraction that was originally presented by Goodyear Tire and Rubber Company and that opened at Disneyland in 1967.[4] Now, however, the term "people mover" is generic, and may use technologies such as monorail, duorail, automated guideway transit or maglev. Propulsion may involve conventional on-board electric motors, linear motors or cable traction.

Generally speaking, larger APMs are referred to by other names. The most generic is "automated guideway transit", which encompasses any automated system regardless of size. Some complex APMs deploy fleets of small vehicles over a track network with off-line stations, and supply near non-stop service to passengers. These taxi-like systems are more usually referred to as personal rapid transit (PRT). Larger systems, with vehicles with 20 to 40 passengers, are sometimes referred to as "group rapid transit" (GRT), although this term is not particularly common. Other complex APMs have similar characteristics to mass transit systems, and there is no clear cut distinction between a complex APM of this type and an automated mass transit system. Another term "Light Metro" is also applied to describe the system worldwide.[5][6][7]

History

Never-Stop Railway

One of the first automated systems for human transportation was the screw-driven 'Never-Stop-Railway',[8][9] constructed for the British Empire Exhibition at Wembley, London in 1924. This railway consisted of 88 unmanned carriages, on a continuous double track along the northern and eastern sides of the exhibition, with reversing loops at either end.

The carriages ran on two parallel concrete beams and were guided by pulleys running on the inner side of these concrete beams,[10][11] and were propelled by gripping a revolving screw thread running between the tracks in a pit; by adjusting the pitch of this thread at different points, the carriages could be sped up, or slowed down to a walking pace at stations, to allow passengers to join and leave. The railway ran reliably for the two years of the exhibition, and was then dismantled.[12]

Small sections of this track bed, and a nearby heavy rail track bed, have been proposed for reuse.[13]

Goodyear and Stephens-Adamson

In late 1949, Mike Kendall, chief engineer and Chairman of the Board of Stephens-Adamson Manufacturing Company, an Illinois-based manufacturer of conveyor belts and systems,[14] asked Al Neilson, an engineer in the Industrial Products Division of Goodyear Tire and Rubber Co., if Goodyear had ever considered working on People Movers. He felt that with Goodyear's ability to move materials in large quantities on conveyor belts they should consider moving batches of people.

Four years of engineering design, development and testing led to a joint patent being issued for three types of people movers, named Speedwalk, Speedramp, and Carveyor. Goodyear would sell the concept and Stephens-Adamson would manufacture and install the components.

A Speedwalk consisted of a flat conveyor belt riding on a series of rollers, or a flat slippery surface, moving at 1.5 mph (2.4 km/h) (approximately half the speed of walking). The passengers would walk onto the belt and could stand or walk to the exit point. They were supported by a moving handrail. Customers were expected to include airport terminals, ballparks, train stations, etc. Today, several manufacturers produce similar units called moving walkways.

A Speedramp was very similar to a Speedwalk but it was used to change elevations; up or down a floor level. This could have been accomplished by an escalator, but the Speedramp would allow wheeled luggage, small handcarts etc. to ride the belt at an operating cost predicted to be much lower than escalators or elevators. The first successful installation of a Speedramp was in the spring of 1954 at the Hudson and Manhattan Railroad Station in Jersey City, New Jersey to connect the Erie Railroad to the Hudson and Manhattan Tubes. This unit was 227 feet (69 m) long with a rise of 22 feet (6.7 m) on a 15 degree grade, and only cost $75,000.

A Carveyor consisted of many small cubicles or cars carrying ten people riding on a flat conveyor belt from point A to point B. The belt rode on a series of motorized rollers. The purpose of the motorized rollers was to facilitate the gradual acceleration and deceleration speeds on the conveyor belt and overcome the tendency of all belts to stretch at start up and during shutdown. At point "A" passengers would enter a Speedwalk running parallel to the belts and cars of the Carveyor. The cars would be moving at the same speed as the Speedwalk; the passengers would enter the cars and be seated, while the motorized rollers would increase the speed of the cars up to the traveling speed (which would be preset depending on the distance to be covered). At point B Passengers could disembark and by means of a series of flat slower belts (Speedwalks) go to other Carveyors to other destinations or out to the street. The cars at point B would continue on rollers around a semicircle and then reverse the process carrying passengers back to point A. The initial installation was to be the 42nd Street Shuttle in New York City between Times Square and Grand Central station.

The first mention of the Carveyor in a hardback book was in There's Adventure in Civil Engineering by Neil P. Ruzic (1958), one of a series of books published by Popular Mechanics in the 1950s in their "Career" series.[15] In the book the Carveyor was already installed and operational in downtown Los Angeles.

Colonel Sydney H. Bingham, Chairman of the New York City Board of Transportation, had several meetings with a group of architects who were trying to revamp the whole New York City Subway system in the heart of town to connect Pennsylvania Station, Madison Square Garden, Times Square, Grand Central and several new office complexes together. Several of these architects were involved in other programs, and in later years many variations of the Carveyor people movers were developed.

In November 1954 the New York City Transit Authority issued an order to Goodyear and Stephens-Adamson to build a complete Carveyor system between Times Square and Grand Central. A brief summary and confirmation can be found in Time magazine on November 15, 1954. under the heading "Subway of the Future".[16] The cost was to be under $4 million, but the order was never fulfilled due to political difficulties.

Chocolate World in Hershey, Pennsylvania, Disneyland in California, and Walt Disney World in Florida are among many locations that have used variations of the Carveyor concept.

Other developments

The term 'people mover' was used by Walt Disney, when he and his Imagineers were working on the new 1967 Tomorrowland at Disneyland. The name was used as a working title for a new attraction, the PeopleMover. According to Imagineer Bob Gurr, "the name got stuck," and it was no longer a working title.[17]

Starting in the late 1960s and into the 1970s, people movers were the topic of intense development around the world. Worried about the growing congestion and pollution in downtown areas due to the spread of cars, many countries started studying mass transit systems that would lower capital costs to the point where any city could afford to deploy them. Most of these systems used elevated guideways, which were much less expensive to deploy than underground tunnels. However, elevating the track causes problems with noise, so traditional steel-wheel-on-rail solutions were rare as they squealed when rounding bends in the rails. Rubber tired solutions were common, but some systems used hovercraft techniques or various magnetic levitation systems.

Two major government funded APM projects are notable. In Germany, Mannesmann Demag and Messerschmitt-Bölkow-Blohm developed a system known as Cabinentaxi during the 1970s. Cabinetaxi featured small cars with from four to eight seats that were called to pick up passengers on-demand and drove directly to their destination. The stations were "offline", allowing the cabs to stop by moving off the main lines while other cars continued to their destinations. The system was designed so the cars could be adapted to run on top or bottom of the track (but not easily converted from one to the other), allowing dual-track movements from a single elevated guideway only slightly wider than the cars. A test track was completed in 1975 and ran until development was completed in 1979, but no deployments followed and the companies abandoned the system shortly thereafter.

In the U.S., a 1966 federal bill provided funding that led to the development of APM systems under the Downtown People Mover Program. Four systems were developed, Rohr's ROMAG, LTV's AirTrans, Ford's APT and Otis Elevator's hovercraft design. A major presentation of the systems was organized as TRANSPO'72 at Dulles Airport where the various systems were presented to delegations from numerous cities in the US. Prototype systems and test tracks were built during the 1970s. One notable example was Pittsburgh's Skybus, which was proposed by the Port Authority of Allegheny County to replace its streetcar system, which, having large stretches of private right of way, was not suited for bus conversion. A short demonstration line was set up in South Park and large tracts of land were secured for its facilities. However, opposition arose to the notion that it would replace the streetcar system. This, combined with the immaturity of the technology and other factors, led the Port Authority to abandon the project and pursue alternatives. By the start of the 1980s most politicians had lost interest in the concept and the project was repeatedly de-funded in the early 1980s. Only two APMs were developed as a part of the People Mover Program in the US, the Metromover in Miami, and the Detroit People Mover. The Jacksonville Skyway was built in the late 1980s.

From development to implementation

Although many government-funded systems were generally considered failures, several APM systems developed by other groups have been much more successful. The first driverless public transport rail networks are the Port Island Line deployed in Kobe, Japan (1981) and the French Véhicule Automatique Léger or VAL, first deployed in Lille in 1983. The Vancouver SkyTrain system is the largest fully automated metro system in the world, with over 60 km of track. These systems are on the "heavy" end of the APM scale. Lighter systems with shorter tracks are widely deployed at airports; the world's first airport people mover was installed in 1971 at Tampa International Airport in the United States. APMs have now become common at large airports and hospitals in the United States.

Driver-less metros have become common in Europe and parts of Asia. The economics of automated trains tend to reduce the scale so tied to "mass" transit (the largest operating expense is the driver's salary, which is only affordable if very large numbers of passengers are paying fares), so that small-scale installations are feasible. Thus cities normally thought of as too small to build a metro (e.g. Rennes, Lausanne, Brescia, etc.) are now doing so.

On September 30, 2006, the Peachliner in Komaki, Aichi Prefecture, Japan became that nation's first people mover to cease operations.

EverLine Innovia ART 200 train in Yongin, South Korea
Two-car AirTrain JFK on elevated guideway

Manufacturers

Heavy APMs

Light APMs

Examples

Skytrain Canada Line, British Columbia, Canada
Docklands Light Railway, Docklands area of London
VAL Automated People mover
(Véhicule Automatique Léger)

Urban transit

Brazil

Canada

China

Denmark

France

Germany

Hong Kong

Italy

Automated MiniMetro in Perugia, Italy

Japan

Astram Line, Hiroshima, Japan

Malaysia

The Philippines

Portugal

Bukit Panjang LRT Line, Singapore
Sengkang LRT Line, A Mitsubishi Heavy Industries Crystal Mover on the East Loop, Singapore

Singapore

South Korea

South Africa

Taiwan

Thailand

United Arab Emirates

United Kingdom

United States

Metromover, Miami, Florida

Venezuela

Madagascar

Airport

Many large international airports around the world feature people mover systems to transport passengers between terminals or within a terminal itself. Some people mover systems at airports connect with other public transportation systems to allow passengers to travel into the airport's city.

Rural and suburban transit

Pillar-track Regional People Mover

The Pillar-track Regional People Mover is a concept of a people mover system, that is optimized for rural and suburban areas with lower population density. The aim of the system is to provide short intervals and appropriate riding and waiting times (including changing between lines) outside of urban areas.[18]

Other

See also

References

  1. "Skybus in Pittsburgh". Archived from the original on 2010-02-10. Retrieved 2010-04-17.
  2. Massey, Steve. "Who killed Westinghouse?". Pittsburgh Post-Gazette. Archived from the original on 2007-11-17. Retrieved 2007-11-12.
  3. "Westinghouse Company Timeline (1940–1979)". Westinghouse Electric Company, LLC. Archived from the original on 2007-08-19. Retrieved 2007-11-12.
  4. Weiss, Werner. "PeopleMover at Disneyland". Yesterland.com. Archived from the original on 2007-11-07. Retrieved 2007-11-12.
  5. Michael Taplin (March 2013). "A world of trams and urban transit - A complete listing of Light Rail, Light Railway, Tramway & Metro systems throughout the World". Light Rail Transit Association (LRTA). Retrieved 2014-11-28.
  6. "Korean city opens automatic light metro". Rail Journal.com. Archived from the original on 2014-11-06. Retrieved 2014-11-24.
  7. "BJP promises light metro in Bhopal and Indore". dnaindia.com. Archived from the original on 2014-12-05. Retrieved 2014-11-28.
  8. British Film Institute Never-Stop Railway
  9. British Pathe (agency) Archived 2011-06-11 at the Wayback Machine. Never-Stop Railway film (probably 1925)
  10. British Pathe (agency) Archived 2011-06-11 at the Wayback Machine. Never-Stop Railway film (probably 1925), see at 01:24 for analyzing the guiding system
  11. Hulton Archive:modified tractor running on the 'Never Stop Railway' Archived 2013-07-23 at the Wayback Machine.
  12. "Exhibiting the Empire". The Tribune. Chandigarh. Archived from the original on 2007-03-12. Retrieved 2006-11-06.
  13. The Times Archived 2009-09-25 at the Wayback Machine. Comment on light-rail proposal
  14. "About S-A". Stephens-Adamson. Archived from the original on 2013-03-18. Retrieved 2014-01-05.
  15. Ruzic, Neil (1958). There's Adventure in Civil Engineering. Popular Mechanics Press. ASIN B0007E9RTY.
  16. Subway of the Future. Time. November 15, 1954.
  17. Gurr, Robert (2005). Ford's Magic Skyway and the PeopleMover (Documentary). United States: Extinct Attractions Club.
  18. Buschbacher, Harald. "The Pillar-track Regional People Mover". Harald Buschbacher. Archived from the original on 2011-01-10. Retrieved 2010-12-12.
  19. Potter, John (12 July 2012). "A New Look at a Reno Classic: Downtown's Sky Shuttle". KTVN-TV. Archived from the original on 30 March 2017. Retrieved 29 March 2017.
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