Method and system may be configured to determine a stationary time period during which a vehicle has remained stationary. The method and system may be further configured to enable a parked function of the vehicle in response to determining that the stationary time period exceeds a designated threshold. While the parked function is enabled, the vehicle applies a braking effort to the vehicle in response to detecting movement of the vehicle.

Method and system may be configured to determine a stationary time period during which a vehicle has remained stationary. The method and system may be further configured to enable a parked function of the vehicle in response to determining that the stationary time period exceeds a designated threshold. While the parked function is enabled, the vehicle applies a braking effort to the vehicle in response to detecting movement of the vehicle.

An ultra-light railway stick device and method of operation are described herein. The ultra-light railway stick weighs less than 5 pounds and is made of carbon fiber as well as ultra-high molecular weight polyethylene. The ultra-light railway stick has a head portion generally shaped like an axe as well as a body that is hexagonal and may be covered in reflective strips.

An ultra-light railway stick device and method of operation are described herein. The ultra-light railway stick weighs less than 5 pounds and is made of carbon fiber as well as ultra-high molecular weight polyethylene. The ultra-light railway stick has a head portion generally shaped like an axe as well as a body that is hexagonal and may be covered in reflective strips.

A parking brake control module using pneumatic logic to control a parking brake on a vehicle. The control module includes a brake pipe passageway, a reservoir passageway, a reservoir release valve; and an actuation cylinder vent valve. The control module applies or releases the parking brake based on pressures of the brake pipe and reservoir. A method uses pneumatic logic to control a parking brake on a vehicle. The parking brake is applied when the brake pipe pressure falls below a lower brake pipe pressure threshold and is released when the brake pipe pressure exceeds an upper brake pipe pressure threshold and the reservoir pressure exceeds a reservoir pressure threshold. A hold valve can allow an operator to manually prevent the release of the parking brake.

A parking brake control module using pneumatic logic to control a parking brake on a vehicle. The control module includes a brake pipe passageway, a reservoir passageway, a reservoir release valve; and an actuation cylinder vent valve. The control module applies or releases the parking brake based on pressures of the brake pipe and reservoir. A method uses pneumatic logic to control a parking brake on a vehicle. The parking brake is applied when the brake pipe pressure falls below a lower brake pipe pressure threshold and is released when the brake pipe pressure exceeds an upper brake pipe pressure threshold and the reservoir pressure exceeds a reservoir pressure threshold. A hold valve can allow an operator to manually prevent the release of the parking brake.

A railway slipping block brake lock has a brake linkage arm connector configured to connect a brake linkage arm to a draw rod. A draw rod is connected to the brake linkage arm connector. The draw rod has a draw rod engaged position corresponding to a railway brake engaged position, and the draw rod has a draw rod disengaged position corresponding to a railway brake disengaged position. A slipping block is mounted around the draw rod. The slipping block has a wedge shaped profile that fits to a wedge-shaped opening of a retaining frame. The retaining frame has a retaining frame wedge-shaped inside profile to receive the slipping block. The slipping block releases the draw rod and disengages from the retaining frame when the draw rod moves toward an engaged position.

A railway slipping block brake lock has a brake linkage arm connector configured to connect a brake linkage arm to a draw rod. A draw rod is connected to the brake linkage arm connector. The draw rod has a draw rod engaged position corresponding to a railway brake engaged position, and the draw rod has a draw rod disengaged position corresponding to a railway brake disengaged position. A slipping block is mounted around the draw rod. The slipping block has a wedge shaped profile that fits to a wedge-shaped opening of a retaining frame. The retaining frame has a retaining frame wedge-shaped inside profile to receive the slipping block. The slipping block releases the draw rod and disengages from the retaining frame when the draw rod moves toward an engaged position.

An unlocking system for at least one brake of a bogie includes an unlocking device configured for being attached to at least one cable connected to the at least one brake, and a support that includes a shaft forming a first axis of rotation. The unlocking device is rotatable with respect to the support about the first axis of rotation between a rest position and at least one unlocking position. The unlocking device is configured for exerting a traction on the at least one cable. The unlocking system can be produced at least partially by additive manufacturing.

An unlocking system for at least one brake of a bogie includes an unlocking device configured for being attached to at least one cable connected to the at least one brake, and a support that includes a shaft forming a first axis of rotation. The unlocking device is rotatable with respect to the support about the first axis of rotation between a rest position and at least one unlocking position. The unlocking device is configured for exerting a traction on the at least one cable. The unlocking system can be produced at least partially by additive manufacturing.