A non-stop train system including a plurality of train cars in communication with one another and in communication with an electronic control module. The train system includes a track or any number of parallel tracks having a plurality of drop off and pick up locations. A prepositioned train car is stopped at one of the drop off and pick up locations. A non-stop express train approaches and passes by the drop off and pick up location on the track initiating the prepositioned train car to begin departure. The electronic control module is used to adjust the speed of the non-stop express train and the prepositioned train car based on a detected distance such that a rear coupler of the non-stop express train couples to the front coupler of the prepositioned train car while moving along the track.

A non-stop train system including a plurality of train cars in communication with one another and in communication with an electronic control module. The train system includes a track or any number of parallel tracks having a plurality of drop off and pick up locations. A prepositioned train car is stopped at one of the drop off and pick up locations. A non-stop express train approaches and passes by the drop off and pick up location on the track initiating the prepositioned train car to begin departure. The electronic control module is used to adjust the speed of the non-stop express train and the prepositioned train car based on a detected distance such that a rear coupler of the non-stop express train couples to the front coupler of the prepositioned train car while moving along the track.

A train coupler includes a mechanical coupler configured to couple with another train coupler, a primary pneumatic circuit, which includes a main air distribution line adapted to be connected with and supply air into a pneumatic circuit of the other train coupler, via a first inlet/outlet, an electrical head connected to a first actuator configured to be pneumatically actuated and drive the electrical head to move between a retracted position and an extended position where it is electrically coupled with an electrical head of the another train coupler, and a secondary pneumatic circuit pneumatically connected to the primary pneumatic circuit and arranged to convey flows of air derived from the main air distribution line towards the first actuator and a second inlet/outlet.

A train coupler includes a mechanical coupler configured to couple with another train coupler, a primary pneumatic circuit, which includes a main air distribution line adapted to be connected with and supply air into a pneumatic circuit of the other train coupler, via a first inlet/outlet, an electrical head connected to a first actuator configured to be pneumatically actuated and drive the electrical head to move between a retracted position and an extended position where it is electrically coupled with an electrical head of the another train coupler, and a secondary pneumatic circuit pneumatically connected to the primary pneumatic circuit and arranged to convey flows of air derived from the main air distribution line towards the first actuator and a second inlet/outlet.

An automatic train coupling includes: a coupling head including a coupling head housing and a coupling fastener, the coupling fastener being a rotary fastener including a coupling eyelet and a core, the core being rotatable between coupled and decoupled positions, the coupling eyelet by way of its first end being connected to the core such that the coupling eyelet is rotatable, the core including a throat; and a decoupling installation which is configured for being electrically, hydraulically, or pneumatically activated and which includes a motor that, by way of a drive connection of the automatic train coupling, is at least indirectly connected to the core so as to rotate the core from the coupled position to the decoupled position, the decoupling installation being disposed either completely within the coupling head housing or completely within the coupling head housing and a coupling bar adjoining the coupling head housing.

An automatic train coupling includes: a coupling head including a coupling head housing and a coupling fastener, the coupling fastener being a rotary fastener including a coupling eyelet and a core, the core being rotatable between coupled and decoupled positions, the coupling eyelet by way of its first end being connected to the core such that the coupling eyelet is rotatable, the core including a throat; and a decoupling installation which is configured for being electrically, hydraulically, or pneumatically activated and which includes a motor that, by way of a drive connection of the automatic train coupling, is at least indirectly connected to the core so as to rotate the core from the coupled position to the decoupled position, the decoupling installation being disposed either completely within the coupling head housing or completely within the coupling head housing and a coupling bar adjoining the coupling head housing.

An automatic uncoupling mechanism for couplers comprises a coupler knuckle spindle and a driving unit comprising a cylinder body hinged to a coupler body and a telescopic member; and further comprises a first rotating member, a boss and a boss stopper, wherein the first rotating member comprises a crank hinged to the telescopic member and a rotating part being sheathed on the coupler knuckle spindle. The driving unit unidirectionally drives the telescopic member so that the rotating part drives the coupler knuckle spindle to unidirectionally rotate by the contact of the boss with the boss stopper, realizing coupler uncoupling; and, after the driving unit drives the telescopic member to return to its position, the rotation of the coupler knuckle spindle for achieving coupler coupling is not limited by the rotating part. The present application may reduce the lateral force of the coupler knuckle to the driving unit during the uncoupling process of the coupler, and may cause the spring to drive the coupler knuckle to rotate rapidly and lock the coupler during the coupler coupling process.

An automatic uncoupling mechanism for couplers comprises a coupler knuckle spindle and a driving unit comprising a cylinder body hinged to a coupler body and a telescopic member; and further comprises a first rotating member, a boss and a boss stopper, wherein the first rotating member comprises a crank hinged to the telescopic member and a rotating part being sheathed on the coupler knuckle spindle. The driving unit unidirectionally drives the telescopic member so that the rotating part drives the coupler knuckle spindle to unidirectionally rotate by the contact of the boss with the boss stopper, realizing coupler uncoupling; and, after the driving unit drives the telescopic member to return to its position, the rotation of the coupler knuckle spindle for achieving coupler coupling is not limited by the rotating part. The present application may reduce the lateral force of the coupler knuckle to the driving unit during the uncoupling process of the coupler, and may cause the spring to drive the coupler knuckle to rotate rapidly and lock the coupler during the coupler coupling process.

A non-stop train system including a plurality of train cars in communication with one another and in communication with an electronic control module. The train system includes a track or any number of parallel tracks having a plurality of drop off and pick up locations. A prepositioned train car is stopped at one of the drop off and pick up locations. A non-stop express train approaches and passes by the drop off and pick up location on the track initiating the prepositioned train car to begin departure. The electronic control module is used to adjust the speed of the non-stop express train and the prepositioned train car based on a detected distance such that a rear coupler of the non-stop express train couples to the front coupler of the prepositioned train car while moving along the track.

A non-stop train system including a plurality of train cars in communication with one another and in communication with an electronic control module. The train system includes a track or any number of parallel tracks having a plurality of drop off and pick up locations. A prepositioned train car is stopped at one of the drop off and pick up locations. A non-stop express train approaches and passes by the drop off and pick up location on the track initiating the prepositioned train car to begin departure. The electronic control module is used to adjust the speed of the non-stop express train and the prepositioned train car based on a detected distance such that a rear coupler of the non-stop express train couples to the front coupler of the prepositioned train car while moving along the track.