A vehicle includes a body and a door that is movably mounted to the body. The door has a powered latch and an electrically-powered actuator that extends and retracts a plunger from an inner side of the door. A controller unlatches the powered latch and actuates the electrically-powered actuator such that the plunger contacts the body and pushes the door open. The controller then controls the electrically-powered actuator to retract the plunger while the door is open.

A railcar system that includes a railcar with a discharge opening and a longitudinal gate positioned adjacent to the discharge opening. The system Further includes a driving system connected to the longitudinal gate that is configured to move the longitudinal gate between a closed position and an open position. The system further includes a controller connected to the driving system that causes the driving system to position the longitudinal gate in the closed position, position the longitudinal gate in the open position, and position the longitudinal gate to remain an at least partially open position. The longitudinal gate is less than fully open when the longitudinal gate is in the at least partially open position.

A railcar system that includes a railcar with a discharge opening and a longitudinal gate positioned adjacent to the discharge opening. The system further includes a driving system connected to the longitudinal gate that is configured to move the longitudinal gate between a closed position and an open position. The system further includes a controller connected to the driving system that causes the driving system to position the longitudinal gate in the closed position, position the longitudinal gate in the open position, and position the longitudinal gate to remain an at least partially open position. The longitudinal gate is less than fully open when the longitudinal gate is in the at least partially open position.

A retention mechanism for a pair of bi-parting doors of a transit vehicle includes a first track connected to a first door of the pair; a second track connected to a second door of the pair; a first retention assembly connected to the transit vehicle and configured to retain the first track in the closed position; a second retention assembly connected to the transit vehicle and configured to retain the second track in the closed position; a first engagement member connected to the second track, the first engagement member being configured to engage the first retention assembly to cause the first retention assembly to move to retain the first track in the closed position when the second track is in the closed position; and a second engagement member connected to the first track, the second engagement member being configured to engage the second retention assembly to cause the second retention assembly to move to retain the second track in the closed position when the first track is in the closed position.

A powered hinge assembly includes a first gate hinge feature, a drive unit connected to the first gate hinge feature and a controller configured to displace the first gate hinge feature to an installation position upon connection to a power source. A powered tailgate assembly, incorporating the powered hinge assembly, and a method of installing a tailgate are also disclosed.

In one aspect, a lift station configured for use with a covering for an architectural structure includes a housing and one or more lift spools disposed within a spool cavity defined by the housing. Additionally, the lift station also includes first and second outriggers extending outwardly from opposed sides of the housing of the lift station. The first outrigger is configured to define a first cord guide surface for guiding a front lift cord between a front side of the covering and the spool cavity of the housing. Similarly, the second outrigger is configured to define a second cord guide surface for guiding a rear lift cord between a rear side of the covering and the spool cavity of the housing.

A vehicle includes a body and a door that is movably mounted to the body. The door has a powered latch and an electrically-powered actuator that extends and retracts a plunger from an inner side of the door. A controller unlatches the powered latch and actuates the electrically-powered actuator such that the plunger contacts the body and pushes the door open. The controller then controls the electrically-powered actuator to retract the plunger while the door is open.

A damper element for damping a translational movement of a component and for causing the component to stop at a stop position includes a housing, a carrier displaceably supported in the housing for movement in a translational direction, and a damper part for damping the translational movement. The damper part has a first end connected to the housing and a second end pivotably connected to the carrier, the carrier is pivotable about a pivot axis perpendicular to the translation direction between a first position and a second position, and the damper element further includes at least one spring biasing the carrier toward the first position.

A vehicle includes a body and a door that is movably mounted to the body. The door has a powered latch and an electrically-powered actuator that extends and retracts a plunger from an inner side of the door. A controller unlatches the powered latch and actuates the electrically-powered actuator such that the plunger contacts the body and pushes the door open. The controller then controls the electrically-powered actuator to retract the plunger while the door is open.

A powered hinge assembly includes a first gate hinge feature, a drive unit connected to the first gate hinge feature and a controller configured to displace the first gate hinge feature to an installation position upon connection to a power source. A powered tailgate assembly, incorporating the powered hinge assembly, and a method of installing a tailgate are also disclosed.