A fenestration hardware assembly includes a blade socket including a blade recess and an operator interface feature rotatably coupled with an operator housing. A latch blade is movably coupled with the operator housing. The latch blade is movable between deployed and withdrawn positions. In the deployed position at least a portion of the latch blade is received in the blade recess of the blade socket. In the withdrawn position the portion of the latch blade is recessed from the blade recess. The operator interface feature is rotatable between at least locked and unlocked configurations. In the locked configuration the latch blade is in the deployed position and received in the blade recess. In the unlocked configuration the latch blade is translated from the deployed position to the withdrawn position and withdrawn from the blade recess according to rotation of the operator interface feature.

A safety device for a motor vehicle, which has a striker, a pawl, an ejection spring ejecting the striker, and a rotary latch, wherein the rotary latch has an opening direction of rotation, a closing direction of rotation an open position, and a main locking position, wherein the ejection spring has a leg and the leg lies directly against the striker in the main locking position of the rotary latch and the leg lies directly against the rotary latch in at least one intermediate position of the rotary latch, in which the rotary latch is between the main locking position and the open position.

The present invention, in a non-limiting example embodiment provides a locking apparatus and method for securing locking hardware without the use of a key. In an example embodiment, the apparatus comprises at least a keyless insertion rotatable disk-style, barrel locking apparatus that, in a locked state can be inserted into a securing device without first unlocking, and then, thereafter, locking after insertion. In a nonlimiting example embodiment, unlocking and re-locking requires a key. The present invention, in an example embodiment, also provides features that allow the locking apparatus to enter and exit multiple apertures without requiring a key.

The present invention, in a non-limiting example embodiment provides a locking apparatus and method for securing locking hardware without the use of a key. In an example embodiment, the apparatus comprises at least a keyless insertion rotatable disk-style, barrel locking apparatus that, in a locked state can be inserted into a securing device without first unlocking, and then, thereafter, locking after insertion. In a nonlimiting example embodiment, unlocking and re-locking requires a key. The present invention, in an example embodiment, also provides features that allow the locking apparatus to enter and exit multiple apertures without requiring a key.

The invention relates to a fitting (1) for actuating a mechanism in a door or window, which has a handle (10) that is rotatably supported in or on a stop element (20) about an axis of rotation (D), wherein the stop element (20) can be fastened to the door or window, a drive pin (40) for actuating the mechanism in the door or window, a coupling element (50) for coupling the handle (10) to the drive pin (40), and a blocking device (70), which blocks the actuation of the drive pin (40) about the axis of rotation (D) when in the blocking position (A), wherein the blocking device (70) can be moved to a releasing position (B) through an axial actuation of the handle from a first position to a second position along the axis of rotation (D). In order to ensure increased security against unauthorized actuation of the fitting or the mechanism connected to the fitting in the window or door, and to obtain a fitting that is easy to manipulate and inexpensive to produce, the handle (10) is decoupled from the drive pin (40) in the first position (I), wherein the blocking device (70) is then in the blocking position (A), and the coupling element (50) couples the handle (10) and the drive pin (40) in the second position, and keeps the blocking device (70) in the releasing position (B). When the second position is reached, the handle is coupled to the drive pin, and unlocks it for the actuation of the mechanism.

A handleset includes a housing, a spindle sleeve, a handle, a coupler, and a spindle. The spindle sleeve includes an aperture, and is rotatably mounted to the housing. The handle is mounted to the spindle sleeve and includes a recess aligned with the aperture. The coupler is movably mounted in the aperture for movement between a decoupling position and a coupling position. The coupler in the coupling position is disengaged from the recess and does not prevent removal of the handle from the spindle sleeve. The coupler in the coupling position extends into the recess and prevents removal of the handle from the spindle sleeve. The spindle is movably received in the spindle sleeve and selectively retains the coupler in the coupling position.

A lock comprising a housing assembly, an actuatable lock assembly and a locking shell assembly. The housing assembly has a cavity and a bore. The actuatable lock assembly is rotatable between a closed orientation and an open orientation, and includes an outer body and an inner body. The inner body has a knob and an elongated shaft with an axial pin that interfaces with a slot in the outer body. The locking shell assembly has a shell housing bore extending therethrough. A rear portion of the shell housing has a slot with a longitudinal first portion and a transverse second portion. The axial pin is slidably movable along the longitudinal first portion and slidably movable along the transverse second portion upon rotation of the inner body relative to the shell housing.

A handleset includes a housing, a spindle sleeve, a handle, a coupler, and a spindle. The spindle sleeve includes an aperture, and is rotatably mounted to the housing. The handle is mounted to the spindle sleeve and includes a recess aligned with the aperture. The coupler is movably mounted in the aperture for movement between a decoupling position and a coupling position. The coupler in the coupling position is disengaged from the recess and does not prevent removal of the handle from the spindle sleeve. The coupler in the coupling position extends into the recess and prevents removal of the handle from the spindle sleeve. The spindle is movably received in the spindle sleeve and selectively retains the coupler in the coupling position.

A toggle latch device translates a first push and release of a button to a locking pin translation from retracted to extended from within a housing. A second push and release of the button reverses the locking pin translation from extended to retracted back within the housing. The latch button remains desirably flush with the housing after each push and release. The translation of the latch button and that of the locking pin is angularly displaced by 90 degrees allowing the toggle latch device to employ a unique lever system which includes a buckling spring combined with a reversing hat which forces the locking pin in each of extension and retraction.

A latch for coupling of a first component to a second component, the latch having a base body which includes a first bearing, a second bearing and a third bearing, the latch having a lever which is mounted pivotably on the first bearing about a first pivot axis between a locking position and an unlocking position, the latch having a locking which is mounted pivotably on the second bearing and which includes a spring-loaded locking part, which locking part rests on the lever in order to transmit a predetermined braking force to the lever in the locking position of the lever, the latch further including a release lever which is mounted movably on the third bearing between a blocking position for blocking the locking in the locking position and a release position for releasing the locking from the locking position.