A fluid control device includes a first conduit having a first end and a second end, and a first fluid that moves within the first conduit between the first end and the second end. The first conduit includes an interior surface defining a cavity of the first conduit. The fluid control device includes a second conduit having a third end and a fourth end, and a second fluid that moves within the second conduit between the third and fourth ends. At least a portion of the second conduit extends within the cavity of the first conduit. The first fluid is separate from the second fluid as the first fluid moves within the first conduit and the second fluid moves within the second conduit.

A fluid control device includes a first conduit having a first end and a second end, and a first fluid that moves within the first conduit between the first end and the second end. The first conduit includes an interior surface defining a cavity of the first conduit. The fluid control device includes a second conduit having a third end and a fourth end, and a second fluid that moves within the second conduit between the third and fourth ends. At least a portion of the second conduit extends within the cavity of the first conduit. The first fluid is separate from the second fluid as the first fluid moves within the first conduit and the second fluid moves within the second conduit.

A method includes applying a brake system of a multi-vehicle system using an onboard controller device and receiving grade input at the onboard controller device from a remote controller device. The grade input indicates a grade of a surface on which the multi-vehicle system is disposed. The method further includes starting movement responsive to receiving a speed command signal at the onboard controller device from the remote controller device. The movement started by initiating release of the brake system and/or generating tractive effort from a propulsion system of the multi-vehicle system stretches the multi-vehicle system. The method further includes, responsive to the movement reaching a designated speed, switching to a closed loop control process of controlling the movement based on one or more of the speed command signal or a brake command signal received at the onboard controller device from the remote controller device.

A method includes applying a brake system of a multi-vehicle system using an onboard controller device and receiving grade input at the onboard controller device from a remote controller device. The grade input indicates a grade of a surface on which the multi-vehicle system is disposed. The method further includes starting movement responsive to receiving a speed command signal at the onboard controller device from the remote controller device. The movement started by initiating release of the brake system and/or generating tractive effort from a propulsion system of the multi-vehicle system stretches the multi-vehicle system. The method further includes, responsive to the movement reaching a designated speed, switching to a closed loop control process of controlling the movement based on one or more of the speed command signal or a brake command signal received at the onboard controller device from the remote controller device.

A vehicle control system an onboard controller device to interface with a propulsion system and a brake system. A remote controller device wirelessly communicates with the onboard controller device and receives input from an operator, generates control signals based on the input, wirelessly communicates the control signals to the onboard controller device while the vehicle system moves along one or more main line routes. A method includes receiving input from an operator at a remote controller device, generating control signals at the remote controller device based on the input from the operator, wirelessly communicating the control signals to an onboard controller device, controlling one or more of a propulsion system or a brake system of the vehicle system to change movement of the vehicle system while the vehicle system moves along one or more main line routes.

A vehicle control system an onboard controller device to interface with a propulsion system and a brake system. A remote controller device wirelessly communicates with the onboard controller device and receives input from an operator, generates control signals based on the input, wirelessly communicates the control signals to the onboard controller device while the vehicle system moves along one or more main line routes. A method includes receiving input from an operator at a remote controller device, generating control signals at the remote controller device based on the input from the operator, wirelessly communicating the control signals to an onboard controller device, controlling one or more of a propulsion system or a brake system of the vehicle system to change movement of the vehicle system while the vehicle system moves along one or more main line routes.

A dual start control circuit for auxiliary inverters of a railway vehicle is provided. An external dual circuit is designed for controlling a start and stop of the auxiliary inverters; and an APS START signal is added to start conditions of the auxiliary inverters. When a start-stop switch is turned to an “on” position, an APS start train line is electrified, APS start relays in cabs at both ends are electrified and corresponding normally-open contacts of the APS start relays are closed, a self-locking circuit is kept electrified, the APS start train line is kept electrified, and a start signal is transmitted to the auxiliary inverters through a hard wire; and when the start-stop switch is turned to an “off” position, an APS stop train line is electrified, APS stop relays in the cabs at both ends are electrified and corresponding normally-closed contacts of the APS stop relays are disconnected.

A dual start control circuit for auxiliary inverters of a railway vehicle is provided. An external dual circuit is designed for controlling a start and stop of the auxiliary inverters; and an APS START signal is added to start conditions of the auxiliary inverters. When a start-stop switch is turned to an “on” position, an APS start train line is electrified, APS start relays in cabs at both ends are electrified and corresponding normally-open contacts of the APS start relays are closed, a self-locking circuit is kept electrified, the APS start train line is kept electrified, and a start signal is transmitted to the auxiliary inverters through a hard wire; and when the start-stop switch is turned to an “off” position, an APS stop train line is electrified, APS stop relays in the cabs at both ends are electrified and corresponding normally-closed contacts of the APS stop relays are disconnected.

The present disclosure generally relates to systems and methods of increasing functional safety of locomotives. In exemplary embodiments, a locomotive functional safety system is configured to: receive one or more manual control commands from a locomotive control stand and/or a user interface onboard a locomotive; determine whether the one or more manual control commands pass or satisfy one or more predetermined criteria; if the one or more manual control commands pass or satisfy the one or more predetermined criteria, approve the one or more manual control commands and allow the one or more manual control commands to be relayed onward and/or acted upon; and if the one or more manual control commands do not pass or satisfy the one or more predetermined criteria, disapprove the one or more manual control commands and disallow the one or more manual control commands to be relayed onward and/or acted upon.

This disclosure discloses a braking-recovery system and method for a train, and a train. The system includes: a traction network, a train, and an energy storage power station. The energy storage power station is connected to the traction network, the energy storage power station includes a second controller, and the second controller controls the energy storage power station according to the voltage of the traction network to perform charging or discharging. The train includes: an electric brake; a battery; a distributor, connected to the electric brake, where there is a node between the distributor and the electric brake; a bidirectional DC/DC converter, where one end of the bidirectional DC/DC converter is connected to the battery, and another end of the bidirectional DC/DC converter is connected to the node; and a first controller, used to control, when the train is braked, the distributor and the bidirectional DC/DC converter to feed back braking electric energy of the train to the traction network, and control the bidirectional DC/DC converter according to a voltage of the traction network to absorb the braking electric energy of the train by using the battery.