One example embodiment is an armored vehicle door quick-release mechanism includes a handle, a slide lock latch, and an actuator mechanism. The handle is coupled to the slide lock latch. The movement of the handle in a first direction causes the slide lock latch to move in a first direction to a first position so that the slide lock latch is adapted to attach the vehicle door to the actuator mechanism adapted to open and close the vehicle door. A movement of the handle in a second direction causes that slide lock latch to move in a second direction to a second position to detach the vehicle door from the actuator mechanism.

One example embodiment is an armored vehicle door quick-release mechanism includes a handle, a slide lock latch, and an actuator mechanism. The handle is coupled to the slide lock latch. The movement of the handle in a first direction causes the slide lock latch to move in a first direction to a first position so that the slide lock latch is adapted to attach the vehicle door to the actuator mechanism adapted to open and close the vehicle door. A movement of the handle in a second direction causes that slide lock latch to move in a second direction to a second position to detach the vehicle door from the actuator mechanism.

Systems and methods for a fluidic elastomer actuator-based handle is provided. A processor determines when a person is approaching a vehicle door and, in response to determining a person is approaching the vehicle door, the processor determines if the door handle is necessary based on a determined intent of the person. If the intent is determined to open the door, the processor manipulates a soft robotics material enclosing the door handle into an in-use state to present the handle to the person through the application of one or more stimuli. When not in a rest state, the soft robotics material provides a smooth surface aligned with a surface of the door panel.

A fluid-driven hatch for a bulk material container includes a cover is opened by a fluid-driven cover actuator and secured by a fluid-driven lock actuator. A fluid conduit connects both the fluid-driven cover actuator and the fluid-driven lock actuator to a pressurized fluid source. Pressurized fluid is selectively supplied to the fluid conduit such that the fluid-driven lock actuator is actuated at a first pressure to unlock the cover, and the fluid-driven cover actuator is actuated moments later at a second, higher pressure to open the cover.

A fluid-driven hatch for a bulk material container includes a cover is opened by a fluid-driven cover actuator and secured by a fluid-driven lock actuator. A fluid conduit connects both the fluid-driven cover actuator and the fluid-driven lock actuator to a pressurized fluid source. Pressurized fluid is selectively supplied to the fluid conduit such that the fluid-driven lock actuator is actuated at a first pressure to unlock the cover, and the fluid-driven cover actuator is actuated moments later at a second, higher pressure to open the cover.

A recreational or utility vehicle system comprising a motorized member that allows for opening of a cargo door utilizing motorized movement to release the cargo door as well as a manual activation device that allows for opening of the cargo door in a manual and mechanical manner. In one arrangement, the recreational or utility vehicle system provides the convenience of opening the cargo door by a simple press of a button which activates the motorized movement. This arrangement also provides for opening of the cargo door when the motorized member fails or when power is unavailable.

A recreational or utility vehicle system comprising a motorized member that allows for opening of a cargo door utilizing motorized movement to release the cargo door as well as a manual activation device that allows for opening of the cargo door in a manual and mechanical manner. In one arrangement, the recreational or utility vehicle system provides the convenience of opening the cargo door by a simple press of a button which activates the motorized movement. This arrangement also provides for opening of the cargo door when the motorized member fails or when power is unavailable.

An exemplary locking assembly includes, among other things, a lock that transitions between a first state that prevents disengaging electric vehicle supply equipment from a charge port and a second state that permits the disengaging. A control module is configured to command the lock to transition from the first to the second state in response to a user interaction with a selector device and an authentication of the user interaction. An exemplary securing method includes, among other things, receiving a request to disengage electric vehicle supply equipment (EVSE) from a charge port of a vehicle, permitting a disengaging if the request can be authenticated, and preventing the disengaging if the request cannot be authenticated.

A door lock arrangement of a vehicle door of a vehicle includes a first closing element arranged in a lock mouth of the vehicle door and a second closing element arranged on a body of the vehicle. The first and second closing elements can be brought into positive-locking engagement with each other to hold the door on the body. A damping device absorbs kinetic energy of the door during a closing movement of the door within a predetermined limit opening angle of the vehicle door relative to the body and slows down the closing movement of the door. The damping device has an impact element arranged on the door in a displaceable manner relative to the door or on the body in a displaceable manner relative to the body. The impact element is connected to an actuator, which applies a pre-tensioning force of the door directed in an opening direction of the door while the first and second closing elements are engaged with each other.

A latch mechanism is used with agricultural equipment, such as a mower, for securing the header of the mower to the tongue during transport. A pivoting catch is mounted on the trail frame on which the header is mounted. A receiver for the catch is mounted on the tongue. During mower transport the catch is biased into engagement with the receiver by a first spring and secures the header to the tongue in a parallel orientation. When the mower configuration is changed to operational mode the catch is disengaged from the receiver using a second spring attached to the catch. A cable attaches the second spring to a wheel arm of a field wheel. Deployment of the field wheel into the operation mode draws the cable and second spring into tension, overcoming the biasing force of the first spring and pivoting the catch out of engagement with the receiver.