Electromechanical lock. Actuator (103) comprises drive head (109) rotatable by electric power (160). Access control mechanism (104) comprises driven gear (101) with cogs, and grip mechanism (111). Drive head (109) comprises two pins (210, 212) configured and positioned so that one of pins (210, 212) is in notch between two cogs (220, 222, 224, 226, 228) of driven gear (101). For opening, drive head (109) rotates driven gear (101) to open position (400), by two pins (210, 212) driving cogs (220, 222, 224, 226, 228) and overcoming grip mechanism (111), and thereby setting access control mechanism (104) to be rotatable (152) by user. If external mechanical break-in force (172) is applied, drive head (109) remains stationary by at least one of pins (210, 212) contacting at least one of cogs (220, 222, 224), and by grip mechanism (111) holding driven gear (101) stationary in locked position (200).

A paddle lock has a body, a lever, a latch, a locking bolt, a bolt driving device, and a lock device. The lever is pivotally mounted on the body and has a pushing arm. The latch has a pushed protrusion selectively abutting against and pushed by the pushing arm of the lever. The locking bolt is mounted slidably in the body and has an abutting arm. The abutting arm extends toward the pushing arm to selectively abut the pushing arm. The bolt driving device is mounted in the body and is connected with the locking bolt to push the locking bolt to extend out of the body or to retract the locking bolt into the body. The lock device is mounted on the body and is connected with the bolt driving device.

A lock includes a housing assembly, an actuatable lock assembly and a latching assembly. The actuatable lock assembly is positionable in at least a closed orientation and an open orientation. The latching assembly further includes a latch, a cam and a motor. The latch, having a cam profile, is movable between a locked position and an unlocked position. In the locked position, the actuatable lock assembly is maintained in the closed orientation. In the unlocked position, the actuatable lock assembly is positionable into an open orientation. The cam is rotatably mounted and has a first follower configured to intermittently coact with the cam profile of the latch, to, in turn, move the latch between the locked position and the unlocked position. The motor is coupled to the cam. Actuation of the motor causes rotation of the cam, resulting in movement of the latch between the locked and unlocked positions.

An exemplary credential input device includes a mounting plate, a pivot pad, a sensor, an input device, and a controller. The pivot pad is pivotably mounted to the mounting plate, is biased to a home position, and is operable to pivot to each of a plurality of pivoted positions. The sensor is mounted to the pivot pad such that the sensor moves with the pivot pad, and is configured to generate information relating to an orientation of the sensor. The input device operable to move the pivot pad from the home position to each of the plurality of pivoted positions, thereby altering the orientation of the sensor. The controller is in communication with the sensor, and is configured to determine an inputted code based upon information received from the sensor, to compare the inputted code to an authorized code, and to issue a command in response to the comparing.

A spring cartridge for a mortise lock includes a housing adapted to be secured within the mortise lock housing, and first and second members slideable with respect to the spring cartridge housing, the first and second members each having a first end adapted to contact an outer surface of first and second spindle hubs and being independently actuable along a longitudinal axis of the spring cartridge housing in response to rotation of the first or second spindle hub. A spring retained by the spring cartridge housing contacts a second end of the first and second members to bias each of the members against the outer surface of the first and second spindle hubs, respectively. Upon rotation of one of the hubs, the member contacting the hub permits the hub to rotate, while the member contacting the other hub prevents the other hub from rotating.

A swivel lock assembly with electronic and manual actuating means to unlock a handle thereby permitting access to the interior of the cabinet wherein the manual actuator can override the electronic actuator and vice versa. When in a locked position, the handle rests within lock housing such that the handle engages a blocker mounted within the housing. To unlock the handle, the blocker is manipulated by electronic or manual actuation such that the handle is no longer constrained and can be swung away from the housing about a handle pivot.

An operating arrangement for at least one motor vehicle latch, in particular a flap operating arrangement for two motor vehicle flap latches placed at a distance from one another and provided with a drive train. Furthermore, a lever arrangement interacting with the drive train is provided. Moreover, there is provided at least one transmission attached to the lever arrangement to act upon the at least one motor vehicle latch. The lever arrangement has an operating lever to act upon the transmission and a locking lever that blocks the operating lever at least when in a locked position, wherein the drive train works upon the locking lever.

A lock assembly that has a first lock state and a second lock state. The lock assembly includes a latch assembly that has a latch movable between an extended position and a retracted position, and a handle operatively coupled to the latch to move the latch between the extended position and the retracted position. The lock assembly also includes a hub that is coupled to the handle for movement therewith, a member that is operatively coupled to the handle to permit or prevent movement of the latch, and a lock element. The member is engaged with the hub to permit or prevent movement of the hub. The lock element is engaged with the member in the second lock state such that the member prevents movement of the handle, and the lock element is disengaged from the member in the first lock state such that the member permits movement of the handle.

A locking mechanism for a bored lock has a lock chassis, a locking element, a motor housing, a reversible electric motor, an auger, and a spiral lock spring disposed between the locking element and the motor. The motor may drive the auger in a first or second rotational direction to move the spring towards/away from the motor to reduce/increase spring force on the locking element, thereby moving the locking element to an unlocked/locked position. One of the locking element and motor housing has a projection while the other has a guideway for slideably receiving the projection. The guideway prevents rotation of the locking element with respect to the motor as it moves between locked and unlocked positions. The projection and guideway are interlocked to prevent disassembly of the locking element and motor housing.

An over-travel mechanism configured to couple an input shaft and an output shaft in an exit device assembly. The input shaft is connected to an actuator that linearly displaces the input shaft, and the output shaft is connected to a locking member of the exit device. The over-travel mechanism includes a link coupled to the output shaft, and a preloaded elastic member transmits force between the input shaft and the link. Movement of the input shaft from a first input shaft position to a second input shaft position causes the elastic member to urge the link from a first link position toward a second link position. Movement of the input shaft from the second input shaft position to a third input shaft position causes the elastic member to elastically deform without moving the link from the second link position.