A railcar anti-scissoring system includes a base controller positioned within a train locomotive that sends a launch initiation command to railcar-stabilizing units when detecting rapid deceleration indicative of a collision or derailment. The stabilizing units include a receiver secured to the rear end of each rail car and a coupling unit attached to the front end of each rail car. The coupling unit houses a deployable locking rod that is thrust into a mating cavity in the receiver upon receipt of the launch command. The deployed locking rod maintains the host railcar and the preceding railcar in a linear orientation during a rapid deceleration to prevent jackknifing.

A railcar anti-scissoring system includes a base controller positioned within a train locomotive that sends a launch initiation command to railcar-stabilizing units when detecting rapid deceleration indicative of a collision or derailment. The stabilizing units include a receiver secured to the rear end of each rail car and a coupling unit attached to the front end of each rail car. The coupling unit houses a deployable locking rod that is thrust into a mating cavity in the receiver upon receipt of the launch command. The deployed locking rod maintains the host railcar and the preceding railcar in a linear orientation during a rapid deceleration to prevent jackknifing.

A coupler uncoupling control mechanism is provided in the present application, comprising an uncoupling cylinder, a propelling cylinder and a control assembly, wherein the propelling cylinder is connected to a first valve body, and the first valve body comprises a first air inlet connected to the main reservoir pipe of the train, a first air outlet communicated with the first air inlet, a second air inlet and a second air outlet communicated with the second air inlet; the first air outlet is communicated with the air inlet chamber of the propelling cylinder, and the second air inlet is communicated with the air outlet chamber of the propelling cylinder. The control assembly comprises a second valve body and the second valve body is a pneumatic control valve; the second valve body comprises a third air inlet communicated with the uncoupling pipe of the train, a third air outlet communicated with the third air inlet, and a first control port capable of controlling airflow communication between the third air inlet and the third air outlet after being triggered; and, the third air inlet is communicated with the air inlet of the uncoupling cylinder, and the first control port is connected to the first air outlet of the first valve body. The present application can ensure that electrical couplers are uncoupled successfully.

A coupler uncoupling control mechanism is provided in the present application, comprising an uncoupling cylinder, a propelling cylinder and a control assembly, wherein the propelling cylinder is connected to a first valve body, and the first valve body comprises a first air inlet connected to the main reservoir pipe of the train, a first air outlet communicated with the first air inlet, a second air inlet and a second air outlet communicated with the second air inlet; the first air outlet is communicated with the air inlet chamber of the propelling cylinder, and the second air inlet is communicated with the air outlet chamber of the propelling cylinder. The control assembly comprises a second valve body and the second valve body is a pneumatic control valve; the second valve body comprises a third air inlet communicated with the uncoupling pipe of the train, a third air outlet communicated with the third air inlet, and a first control port capable of controlling airflow communication between the third air inlet and the third air outlet after being triggered; and, the third air inlet is communicated with the air inlet of the uncoupling cylinder, and the first control port is connected to the first air outlet of the first valve body. The present application can ensure that electrical couplers are uncoupled successfully.

A coupler uncoupling control mechanism is provided in the present application, comprising an uncoupling cylinder, a propelling cylinder and a control assembly, wherein the propelling cylinder is connected to a first valve body, and the first valve body comprises a first air inlet connected to the main reservoir pipe of the train, a first air outlet communicated with the first air inlet, a second air inlet and a second air outlet communicated with the second air inlet; the first air outlet is communicated with the air inlet chamber of the propelling cylinder, and the second air inlet is communicated with the air outlet chamber of the propelling cylinder. The control assembly comprises a second valve body and the second valve body is a pneumatic control valve; the second valve body comprises a third air inlet communicated with the uncoupling pipe of the train, a third air outlet communicated with the third air inlet, and a first control port capable of controlling airflow communication between the third air inlet and the third air outlet after being triggered; and, the third air inlet is communicated with the air inlet of the uncoupling cylinder, and the first control port is connected to the first air outlet of the first valve body. The present application can ensure that electrical couplers are uncoupled successfully.

A system for coupling a first train coach to a second coach includes a first automatic coupler mountable at an end of the first coach, providing for a mechanical coupling to a second automatic coupler mountable at the second coach. The first coupler has a first coupling actuator that drives a first locking mechanism between locked and unlocked states. A first bellows has a first mounting frame, first coupling frame, and first latching mechanism at the first coupling frame. The first coupling frame is coupled by the first latching mechanism to a second coupling frame of the second bellows. A controller receives an uncoupling instruction, generates an uncoupling signal and sends it to the first coupling actuator, receives a coupling instruction, and generates a coupling signal and sends it to the first coupling actuator.

A system for coupling a first train coach to a second coach includes a first automatic coupler mountable at an end of the first coach, providing for a mechanical coupling to a second automatic coupler mountable at the second coach. The first coupler has a first coupling actuator that drives a first locking mechanism between locked and unlocked states. A first bellows has a first mounting frame, first coupling frame, and first latching mechanism at the first coupling frame. The first coupling frame is coupled by the first latching mechanism to a second coupling frame of the second bellows. A controller receives an uncoupling instruction, generates an uncoupling signal and sends it to the first coupling actuator, receives a coupling instruction, and generates a coupling signal and sends it to the first coupling actuator.