The present invention relates to a locking mechanism for a magnetic lock and including a locking body assembly. The locking mechanism includes a lock latch and a slide bar switch that move between an active and non-active positions. The lock latch cannot move freely in the active position, but can in the non-active position. The lock latch receives a magnet, and can move freely through magnetic force action. The locking body assembly includes a locking body and a locking plate. The locking body has a housings that form a cavity. When the locking mechanism and lock latch are fixed in the cavity, a hook portion of the lock latch can extend out of or retract into the cavity as the lock latch pivots, thereby engaging or disengaging with the locking plate, and either locking or unlocking the latch. The magnetic lock includes a key and the locking body assembly.

A latch is provided including a claw configured to rotate between an open position and a closed position. A pawl is rotatable in and out of engagement with the claw. The latch includes a first release mechanism, a second release mechanism, and a third release mechanism. The first release mechanism applies a rotational force to a first portion of the pawl to rotate the pawl out of engagement with the claw. The second release mechanism applies a rotational force to a second portion of the pawl to rotate the pawl out of engagement with the claw. The third release mechanism applies a rotational force to a first portion of the pawl to rotate the pawl out of engagement with the claw.

A latch device for a vehicle which locks or unlocks by engaging with or disengaging from a rod-shaped portion includes a housing and a latch 30 rotatably supported by the housing, the latch including a hook-shaped portion 33 engageable with the rod-shaped portion to form a locked state. The hook-shaped portion 33 includes a first support surface 38A opposed to the rod-shaped portion in the locked state, a protruding portion 37 located in a position closer to a distal end of the hook-shaped portion than the first support surface 38A and configured to protrude relative to the first support surface 38A, and a second support surface 38B provided on the protruding portion 37 and configured to be opposed to the rod-shaped portion. The first support surface 38A and the second support surface 38B are configured to face in different directions, and to thereby be concurrently contactable with the rod-shaped portion.

Latch housing assemblies, latch hook assemblies, and latch assemblies are disclosed. Various disclosed latch housing assemblies include a latch pin coupled to an inner housing, and an outer housing having an inner surface coupled to an outer surface of the inner housing via at least one of a fuse pin and a spring. Various disclosed latch hook assemblies include a latch hook coupled to a latch housing, a weak point in the latch housing disposed between an inboard mount and an outboard mount, and a catch member mounted to the inboard mount and the outboard mount. Various disclosed latch assemblies include a latch housing, a bolt, and a deformable bushing at least partially surrounding the bolt, the deformable bushing configured to deform about a radius in response to a compressive load of about 1,000 lb.sub.f to about 3,000 lb.sub.f.

An actuating system for an actuatable door and to an actuatable door having such an actuating system are provided. The actuating system comprises first and second rotatable latching shafts, a coupling link, first and second pivotable mechanical transmission elements that are mounted onto first and second rotatable latching shafts, respectively, and first and second latching members. First and second latching members are non-rotatably mounted to the second rotatable latching shaft and adapted for latching the actuatable door in a closed position. A first rotation of the first rotatable latching shaft results in pivoting of the first and second mechanical transmission elements and a second rotation of the second rotatable latching shaft, which causes a third rotation of first and second latching members.

Latch housing assemblies, latch hook assemblies, and latch assemblies are disclosed. Various disclosed latch housing assemblies include a latch pin coupled to an inner housing, and an outer housing having an inner surface coupled to an outer surface of the inner housing via at least one of a fuse pin and a spring. Various disclosed latch hook assemblies include a latch hook coupled to a latch housing, a weak point in the latch housing disposed between an inboard mount and an outboard mount, and a catch member mounted to the inboard mount and the outboard mount. Various disclosed latch assemblies include a latch housing, a bolt, and a deformable bushing at least partially surrounding the bolt, the deformable bushing configured to deform about a radius in response to a compressive load of about 1,000 lb.sub.f to about 3,000 lb.sub.f.

A lever-lock release system is configured to releasably couple two objects together, for example a parachute and a payload. The lever-lock release system may comprise a first lever and a second lever, each rotatably coupled to a rigid base. When activated, the levers cascadingly rotate to release a first object and a second object. With these systems and related methods, various failure modes may be eliminated, such as undesired premature deployment of recovery parachutes during aerial delivery.

A delayed return mechanism, such as for a door latch, including a housing having a hole with an axis, a cavity in the housing at least partially filled with a fluid media, a hub disposed in the cavity including a spindle hole coaxial with the hole in the housing including teeth within the spindle hole to engage a spindle, the hub being rotatable about the axis and having a fin extending radially outward in the cavity, and a channel through which the fluid media passes during rotation of the hub to control flow of the fluid media about the cavity.

A vehicle door includes a powered latch configured to selectively retain the door in a closed position when the powered latch is latched, and permits the door to be opened when the powered latch is unlatched. The vehicle door further includes an exterior door handle having an outer side that faces away from the door structure, and an inner side that is spaced apart from an outer surface of the door to define a gap. A force sensor on the exterior door handle detects impact forces on the handle. The door also includes an unlatch switch that can be actuated by a user to request unlatching of the powered latch. A controller is configured to deny an unlatch request generated by actuation of the unlatch switch if the force sensor detects an impact on the exterior handle.

A push-push latch includes a slider slidably disposed on a frame. A resilient element is to urge the slider toward an extended state. The slider or the frame defines a cam-track. A pin member is connected to the frame or the slider. The pin member selectably engages a closed course in the cam-track to cause the slider to alternate between a retracted state and the extended state in response to alternating application and removal of an actuating force on the slider. An interference member is on the frame to selectively prevent the pin member from engaging the closed course thereby locking the slider in the retracted state. A pivotable catch is rotatably on the slider to open in the extended state and to close in the retracted state. A shape memory alloy actuator selectively causes the interference member to selectively prevent the pin member from engaging the closed course.