Public transit operators may be the unsung experts of compressed air. Every day on the job, they have faith that compressed air systems will adjust pressure accordingly when brakes are applied.
Workers use similar systems to open and close car doors, as well as adjust co
Today, autonomous and manually-operated streetcars, subway trains, metros, monorails, and AGT vehicles to power many of their integral functionalities. Let鈥檚 explore some of the most popular applications:
Light rail transit systems often use compressed air to operate their braking systems. Pioneered by in the late 19th century, the system has been nearly universally adopted in rail transit. Unlike hydraulic braking systems, which require a finite supply of braking fluid, compressed air braking systems run on a regenerative system of pressurized air.
Compressed air brakes work in three stages:
1. Air is continually pumped into air tanks attached to each car, charging those tanks. The air is then pumped into the brake line, which toggles a valve separating the tank from the brake itself.
2. When the brake is applied, pressure to the brake line is cut off, opening the valve and causing the train to brake.
3. As soon as the air tank fills again, the system is prompted to release the brakes so the train can move again.
You鈥檝e almost certainly seen a pantograph before, even if you didn鈥檛 know what it was called. It鈥檚 the accordion-like device that connects light rail cars and larger trains with electrical wires 鈥 called catenary wires 鈥 overhead. Pantographs pull electrical currents from the catenary through a highly-conductive graphite 鈥榮hoe鈥, which maintains contact by drawing on the braking system鈥檚 compressed air supply. This system works well for above-ground trains, where use of a 鈥渢hird rail鈥 to conduct electricity would be dangerous and impractical.
The compression system powering the pantograph is crucial, as any pressure failure therein will result in power loss, and therefore commuter delays. In most cases, the pantograph runs off an auxiliary compressor, since the vehicle鈥檚 main compressors often can鈥檛 power up until the pantograph has made connection with the catenary wires.
Rail suspension systems once relied upon steel springs. Today, many suspension systems use compressed air 鈥搉ot only to insulate mechanical components from damage and ensure passenger comfort, but also to adjust vehicle ride height.
Air bladders situated between the car chassis and axles are inflated and deflated as necessary to achieve proper ride height. Operators must constantly account for deck height and capacity, adjusting pressure to the suspension system accordingly.
Power braking systems, pantographs, and air suspension are just three in a multitude of rail transit systems 鈥 including pneumatic doors and air purification 鈥 that rely on compressed air.
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