The present disclosure increases the braking force of a parking spring brake mechanism without enlarging a device and without substantial increase in cost. The subject of the present disclosure is a brake cylinder device provided with a parking spring brake mechanism wherein a first piston moves in a prescribed braking direction. The brake cylinder device is provided with a brake force transmitting section having an inclined surface 38 that is inclined so as to press a brake output section in an advancement direction by moving along with the first piston in the braking direction. The inclined surface includes a first inclined surface provided in a distal end portion, and a second inclined surface provided in a proximal end portion and inclined more than the first inclined surface with respect to the advancement direction.

A system for retarding the speed of a railcar comprises a brake; a hydraulic actuator moving the brake between a closed position in which the brake applies braking pressure on the wheel of a railcar, and an open position in which the brake does not apply braking pressure on the wheel of the railcar; a hydraulic circuit provided with a pump arrangement for supplying hydraulic fluid to the hydraulic actuator; and a control circuit coupled to the hydraulic circuit for controlling the flow of hydraulic fluid to move the brake between the closed and open positions.

A system for retarding the speed of a railcar comprises a brake; a hydraulic actuator moving the brake between a closed position in which the brake applies braking pressure on the wheel of a railcar, and an open position in which the brake does not apply braking pressure on the wheel of the railcar; a hydraulic circuit provided with a pump arrangement for supplying hydraulic fluid to the hydraulic actuator; and a control circuit coupled to the hydraulic circuit for controlling the flow of hydraulic fluid to move the brake between the closed and open positions.

Systems, assemblies, and/or the like are provided. According to various embodiments, a shuttle car has a first end; a second end; a platform disposed between the first and second ends, wherein the platform is configured to support and transport one or more objects; one or more attachment mechanisms, wherein the one or more attachment mechanisms are configured to be selectively deployed, wherein, when the one or more attachment mechanisms are selectively deployed, the one or more attachment mechanisms are configured to engage with one or more arresting cables and bring the shuttle car to a stop; and one or more locking mechanisms, wherein the one or more locking mechanisms are configured to secure the one or more attachment mechanisms to the first end or the second end of the shuttle car, and wherein the one or more locking mechanism are configured to selectively deploy the one or more attachment mechanisms.

Systems, assemblies, and/or the like are provided. According to various embodiments, a shuttle car has a first end; a second end; a platform disposed between the first and second ends, wherein the platform is configured to support and transport one or more objects; one or more attachment mechanisms, wherein the one or more attachment mechanisms are configured to be selectively deployed, wherein, when the one or more attachment mechanisms are selectively deployed, the one or more attachment mechanisms are configured to engage with one or more arresting cables and bring the shuttle car to a stop; and one or more locking mechanisms, wherein the one or more locking mechanisms are configured to secure the one or more attachment mechanisms to the first end or the second end of the shuttle car, and wherein the one or more locking mechanism are configured to selectively deploy the one or more attachment mechanisms.

A transport vehicle for traveling in a low-pressure environment structure is provided. The transport vehicle may include a deployable decelerator configured to deploy from the transport vehicle to decrease a distance between the transport vehicle and the low-pressure environment structure and a communication network that monitors and collects a plurality of operation parameters from the transport vehicle and the low-pressure environment structure to control deployment of the deployable decelerator based on a plurality of predetermined triggering events.

A transport vehicle for traveling in a low-pressure environment structure is provided. The transport vehicle may include a deployable decelerator configured to deploy from the transport vehicle to decrease a distance between the transport vehicle and the low-pressure environment structure and a communication network that monitors and collects a plurality of operation parameters from the transport vehicle and the low-pressure environment structure to control deployment of the deployable decelerator based on a plurality of predetermined triggering events.

A locomotive air brake control system that responds to penalty braking requests from external systems by applying a varying amount of train brake level based on monitored and calculated parameters in order to enforce a defined train condition. The system may include a minimum acceptable train braking, a condition to be achieved to prevent further application of train brakes, and a maximum train brake level to be applied in response to the request. Alternatively, the system may apply braking in stepped levels according defined thresholds for a train behavior variable of interest such as speed or deceleration. The system may be configured to incrementally apply and release train brakes during the adaptive penalty, and may also adjust the level of braking according to calculated braking capacity of the train.

A locomotive air brake control system that responds to penalty braking requests from external systems by applying a varying amount of train brake level based on monitored and calculated parameters in order to enforce a defined train condition. The system may include a minimum acceptable train braking, a condition to be achieved to prevent further application of train brakes, and a maximum train brake level to be applied in response to the request. Alternatively, the system may apply braking in stepped levels according defined thresholds for a train behavior variable of interest such as speed or deceleration. The system may be configured to incrementally apply and release train brakes during the adaptive penalty, and may also adjust the level of braking according to calculated braking capacity of the train.

A parking brake reset system for a railway vehicle, such as a transit vehicle, includes a brake operating unit fluidly connected to a main air reservoir and controlling air flow to a brake cylinder of the railway vehicle, a brake pipe, a parking brake, and a control valve in line between the brake pipe and the parking brake to establish fluid communication between the brake pipe and the parking brake. The control valve is in line between the brake operating unit and the parking brake, whereby the control valve controls air flow to the parking brake from the main air reservoir and the brake pipe. The control valve may be a double check valve or a 3-way cutout valve, as examples.