Straight air brake In the air brake's simplest form, referred to as a
straight air system,
compressed air is directed to a
brake cylinder, causing its
piston to apply force to mechanical linkage, which linkage is conventionally referred to as the
brake rigging (see illustration at right). The brake rigging, in turn, is connected to brake shoes that are pressed against the car's wheel treads (some types of passenger cars instead use
disc brakes). The resulting friction slows the car by dissipating its
kinetic energy as heat. The brake rigging is often quite elaborate, as it is designed to distribute the brake cylinder's force evenly across multiple wheels. The source of high-pressure air needed to operate the system is an
air compressor mounted in the locomotive, the compressor being driven by a
Diesel locomotive's
prime mover, or by a
cross-compound steam engine on a
steam locomotive. Compressors of
electric locomotives are usually driven by their own
electric motor. The output of the air compressor is stored in a tank, also mounted on the locomotive, referred to as the
main reservoir. Air from the main reservoir is
piped to a manually operated brake valve in the locomotive's cab. When the brake valve is opened to apply the brakes, pressurized air is conveyed to the brake mechanism. A critical weakness of the straight air braking system is that any failure in the piping, such as a blown
air hose, that causes a loss of pressure will render the brakes inoperative. For this reason, train brakes do not employ straight air for operation, as there is no redundancy in the event of such a failure. However, straight air is used to operate locomotive brakes, as redundancy is provided by the ability of a locomotive to come to a stop by reversing propulsion in an emergency, a procedure referred to as "plugging". An
independent brake valve controls locomotive brakes, so-named because the locomotive brakes may be applied or released independently from the train brakes.
Westinghouse air brake To design a braking system without the shortcomings of the straight air system,
Westinghouse invented an arrangement in which each piece of railroad
rolling stock was equipped with a
dual-compartment, compressed-air reservoir and a
triple valve, also known as a
control valve. A pipe referred to as the
brake pipe was fitted to each car to act as a passage for the
compressed air needed to make the system function. The brake pipes were fitted with
hoses at each end of each car and locomotive for creating a continuous brake pipe connection throughout the train. Unlike the previously described straight air system, the Westinghouse system uses a
reduction in brake pipe air pressure to apply the brakes indirectly. In his patent application, Westinghouse refers to his 'triple-valve device' because of its three component valvular parts: the diaphragm-operated
poppet valve feeding reservoir air to the brake cylinder, the reservoir charging valve, and the brake cylinder release valve. Westinghouse soon improved the device by removing the poppet valve action. These three components became the piston valve, the slide valve, and the graduating valve. The Westinghouse system functions as follows: • When brake pipe pressure is reduced below car reservoir pressure (referred to as a "service reduction", which is usually initiated by the train operator to slow or stop the train), the triple valve will close the brake cylinder exhaust port and open a port connecting the service compartment of the (dual-compartment) reservoir to the cylinder, charging the latter with air from the former and causing a brake application. Cylinder charging will continue until brake pipe and reservoir pressures have equalized. At that time, the triple valve will seal ("lap off") the reservoir-to-cylinder port to maintain cylinder pressure. • When brake pipe pressure is increased above the car reservoir pressure, the triple valve will open the brake cylinder exhaust port, venting the cylinder to the atmosphere and hence releasing the brakes. Simultaneously, the triple valve will open a port from the reservoir to the brake pipe, thereby recharging both reservoir compartments. When reservoir and brake pipe pressures have equalized, the triple valve will close the port connecting the brake pipe to the reservoir. The reservoir will be sealed off from both the brake pipe and the brake cylinder, and should be able to maintain pressure until needed again. • When brake pipe pressure is reduced below the car reservoir pressure , an emergency brake application will occur. The triple valve will open an unlapped port connecting the emergency compartment of the car's reservoir to the brake cylinder. The sudden application of full reservoir pressure to the brake cylinder will produce the maximum possible braking force (occasionally causing wheel slide). At the same time, the triple valve will locally vent the brake pipe to the atmosphere, which will increase the rate at which the sudden pressure loss propagates throughout the train. Local venting action is necessary because, without it, the rate at which brake pipe pressure can be reduced through the automatic brake valve (if the engineer (driver) initiated the emergency application) or a blown or disconnected air hose might not be fast enough to trigger an emergency response on more than a few cars. If the pressure loss was due to, for example, a blown air hose at the front of a 100-car freight train and there was no local venting, the triple valves on many cars farther back in the train might not trigger an emergency response, or the response might be significantly delayed. Cars nearest to the front would forcefully apply their brakes well before the cars farther back, causing a "run-in", an abrupt and violent bunching of train slack that could lead to a derailment. Due to its design, the Westinghouse system is inherently
fail-safe, in that any uncommanded loss of brake pipe pressure, such as the aforementioned blown air hose, will cause an immediate brake application.
Modern systems Modern air brake systems serve two functions: • braking applies and releases the brakes during normal operations. • braking rapidly applies the brakes in the event of a brake pipe failure or an emergency application by the engine operator or passenger emergency alarm/cord/handle. When the train brakes are applied during normal operation, the engine operator makes a "service application" or a "service rate reduction", which means that the brake pipe pressure reduces at a controlled rate. It takes several seconds for the brake pipe pressure to drop and, consequently, for the brakes to apply throughout the train. The speed of pressure changes during a service reduction is limited by the compressed air's ability to overcome the flow resistance of the relatively-small-diameter pipe and numerous elbows throughout the length of the train, and the relatively-small exhaust port on the head-end locomotive, which means the brakes of the rearmost cars will apply sometime after those of the forward-most cars apply, so some
slack run-in can be expected. The gradual reduction in brake pipe pressure will mitigate this effect. Modern locomotives employ two air brake systems. The system that controls the brake pipe is called the
automatic brake and provides service and emergency braking control for the entire train. The locomotive(s) at the head of the train (the "lead consist") have a secondary system called the
independent brake. The independent brake is a "straight air" system that allows the head-of-train locomotive to apply the brakes independently of the automatic brake, providing more nuanced train control. The two braking systems may interact differently, depending on the locomotive builder's or the railroad's preference. In some systems, the automatic and independent applications will be additive; in some systems, the greater of the two will apply to the locomotive consist. The independent system also provides a 'bail-off' mechanism that releases the brakes on the lead locomotives without affecting the brake application on the rest of the train. In the event the train needs to make an emergency stop, the engine operator can make an "emergency application," which rapidly vents all brake pipe pressure to the atmosphere, resulting in a faster application of the train's brakes. An emergency application also occurs when the brake pipe loses integrity, as all air is immediately vented to the atmosphere. An emergency brake application adds a component to each car's air brake system. The triple valve is divided into two portions: the service section, which contains the mechanism used for brake applications during service reductions, and the emergency section, which senses the faster emergency reduction in train line pressure. In addition, each car's air brake reservoir is divided into two sections—the service and emergency portions—and is known as the "dual-compartment reservoir". Normal service applications transfer air pressure from the service section to the brake cylinder. In contrast, emergency applications direct all air from both sections of the dual-compartment reservoir to the brake cylinder, resulting in a 20 to 30 percent stronger application. The higher rate of brake pipe pressure reduction activates the emergency portion of each triple valve. Due to the length of trains and the small diameter of the brake pipe, the rate of reduction is highest near the front of the train (in the case of an engine operator-initiated emergency application) or near the break in the brake pipe (in the case of loss of brake pipe integrity). The farther away from the source of the emergency application, the greater the reduction rate can be before triple valves will not detect the application as an emergency reduction. To prevent this, each triple valve's emergency portion contains an auxiliary vent port that, when activated by an emergency application, locally vents the brake pipe pressure directly to the atmosphere. This serves to vent the brake pipe more rapidly and hasten the propagation of the emergency reduction rate along the entire length of the train. Use of
distributed power (i.e., remotely controlled locomotive units mid-train and/or at the rear end) somewhat mitigates the time-lag problem with long trains, because a
telemetered radio signal from the engine operator in the front locomotive commands the distant units to initiate brake pressure reductions that propagate quickly through nearby cars.
Distributors Many modern air brake systems use distributors instead of triple valves. These serve the same function as triple valves but also offer additional functionality, such as the ability to release the brakes partially.
Working pressures The locomotive's air compressor typically charges the main reservoir with air at . The train brakes are released by admitting reduced and regulated main reservoir air pressure to the brake pipe through the engineer's automatic brake valve. In America, a fully charged brake pipe typically operates at for freight trains and for passenger trains. The brakes are applied when the engineer moves the automatic brake handle to a "service" position, which causes a reduction in brake pipe pressure. During normal service, the pressure in the brake pipe is never reduced to zero, and in fact, the smallest reduction that will cause a satisfactory brake response is used to conserve brake pipe pressure. A sudden and substantial pressure reduction caused by a loss of brake pipe integrity (e.g., a blown hose), the train breaking in two and uncoupling air hoses, or the engineer moving the automatic brake valve to the emergency position, will cause an
emergency brake application. On the other hand, a slow leak that gradually reduces brake pipe pressure to zero, something that might happen if the air compressor is inoperative and therefore not maintaining main reservoir pressure (as occurred during the
Lac-Mégantic rail disaster), will not cause an emergency brake application. == Enhancements ==