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Track brake
A magnetic track brake (Mg brake) is a brake for rail vehicles. It consists of brake magnets, pole shoes, a suspension, a power transmission and, in the case of mainline railroads, a track rod. When current flows through the magnet coil, the magnet is attracted to the rail, which presses the pole shoes against the rail, thereby decelerating the vehicle.
While brakes such as disc brakes or shoe brakes depend on the frictional connection between wheel and rail, the magnetic track brake acts directly on the rail. Therefore, its brake effect is not limited by wheel-rail contact. Thus, environmental factors such as wetness or contamination of the rail have less influence on the brake force.
Magnetic track brakes are used on rail vehicles in addition to the primary, wheel-effective brake systems. As an additional brake system, they help to ensure that the prescribed brake distances of rail vehicles can be complied with.
Since magnetic track brakes always act unregulated and at their maximum brake force, they are only used as safety and emergency brakes. They can be used at speeds of up to 280 km/h (170 mph). With the usage of special friction materials they can be used up to speeds of 350 km/h (220 mph).
Due to their track-cleaning effect, magnetic track brakes increase the coefficient of adhesion between the following wheels and the rail during the brake process. This additionally leads to an improvement of the wheel-effective brake systems.
Magnetic track brakes are distincted between rigid and articulated magnets.
On April 5, 1900, the patent (AT11554) for the first electromagnetic brake for rail vehicles was registered by the Westinghouse Air Brake Company London. Three years later, the electromagnetic track brake was introduced in Germany by the Westinghouse Company.
The Mg brake was characterized by the fact that the electromagnets were magnetized to different degrees by the exciter coils, which made the brake force dependent on the strength of the brake current. Even the winding numbers of the exciter coils were different in order to be able to regulate the brake force. Thus, the track brake was also equipped with several shoes in order to be able to adapt to possible unevenness of the rails.
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Track brake AI simulator
(@Track brake_simulator)
Track brake
A magnetic track brake (Mg brake) is a brake for rail vehicles. It consists of brake magnets, pole shoes, a suspension, a power transmission and, in the case of mainline railroads, a track rod. When current flows through the magnet coil, the magnet is attracted to the rail, which presses the pole shoes against the rail, thereby decelerating the vehicle.
While brakes such as disc brakes or shoe brakes depend on the frictional connection between wheel and rail, the magnetic track brake acts directly on the rail. Therefore, its brake effect is not limited by wheel-rail contact. Thus, environmental factors such as wetness or contamination of the rail have less influence on the brake force.
Magnetic track brakes are used on rail vehicles in addition to the primary, wheel-effective brake systems. As an additional brake system, they help to ensure that the prescribed brake distances of rail vehicles can be complied with.
Since magnetic track brakes always act unregulated and at their maximum brake force, they are only used as safety and emergency brakes. They can be used at speeds of up to 280 km/h (170 mph). With the usage of special friction materials they can be used up to speeds of 350 km/h (220 mph).
Due to their track-cleaning effect, magnetic track brakes increase the coefficient of adhesion between the following wheels and the rail during the brake process. This additionally leads to an improvement of the wheel-effective brake systems.
Magnetic track brakes are distincted between rigid and articulated magnets.
On April 5, 1900, the patent (AT11554) for the first electromagnetic brake for rail vehicles was registered by the Westinghouse Air Brake Company London. Three years later, the electromagnetic track brake was introduced in Germany by the Westinghouse Company.
The Mg brake was characterized by the fact that the electromagnets were magnetized to different degrees by the exciter coils, which made the brake force dependent on the strength of the brake current. Even the winding numbers of the exciter coils were different in order to be able to regulate the brake force. Thus, the track brake was also equipped with several shoes in order to be able to adapt to possible unevenness of the rails.