An exit device according to one embodiment includes a plurality of sensors and an electronic dogging mechanism. The exit device is configured to locally analyze sensor data to determine the security state of the exit device, report data to a management system via a wireless communication channel established between the exit device and the management system, and receive and process instructions to perform an electronic dogging operation.

An electronic lock includes a latch assembly that has a latch housing and a bolt. The bolt is movable between an extended position and a retracted position. The electronic lock includes a controller connected to a circuit board. The controller is configured to electronically control movement of the bolt between the extended position and the retracted position. The electronic lock includes an exposed conductive touch member. The conductive touch member is in electrical communication with the controller. The electronic lock includes an insulating arrangement positioned between the conductive touch member and the circuit board. The electronic lock includes a housing at least partially surrounding the conductive touch member. The housing is electrically isolated from the conductive touch member by at least a portion of the insulating arrangement.

An electronic deadbolt includes a face plate and a housing having a first end and an opposite second end. The first end is releasably coupled to the face plate, and the housing further includes a bolt compartment defining a bolt axis and a battery compartment defining a battery axis. The bolt axis is substantially parallel to and offset from the battery axis, and the bolt compartment is separated from the battery compartment proximate the second end of the housing. The electronic deadbolt further includes a bolt module disposed within the bolt compartment. The bolt module includes a motor and a deadbolt, and the deadbolt is configured to be selectively linearly extended from the face plate along the bolt axis.

A motor-driven door latch for a vehicle includes a catch part which is caught on a striker mounted on the vehicle. A door locking and releasing part includes a main motor and applies torque to the catch part through the main motor to allow the catch part to be locked to or released from the striker. A motor-driven emergency door releasing part is provided with an auxiliary motor and is contacted with the door locking and releasing part. An inside emergency operating lever is connected with an inside handle installed at the door for the vehicle. An outside emergency operating lever is connected with an outside handle installed at the door for the vehicle. A manual emergency door release part is connected with the inside emergency operating lever.

A latch (10) includes a rotatable jaw (18) that engages and holds a striker (32) in a latched position. A rotatable pawl (28) in an engaged position is operative to hold the jaw in the latched position. Movement of the pawl to a disengaged position enables the jaw to move to an unlatched position and to disengage the striker. The pawl is movable from the engaged position to the disengaged position through operation of either an electrical actuator (84) or through movement of an actuating end (26) of the pawl by a cable (36).

In some embodiments, a method of determining whether a door is ajar may include determining an orientation of a door lock of the door, and, based on the orientation of the door lock, analyzing at least one signal from at least one of two or more proximity sensors of the door lock. The method may further include determining whether the door is ajar based at least in part on a result of the analyzing of the at least one signal. In some embodiments, a method of determining a status of a door may include receiving a first signal from a first magnetometer disposed within a door lock of the door, receiving a second signal from a second magnetometer disposed within the door lock of the door, and detecting, based on a result of an evaluation of both the first signal and the second signal, a possible attack on the door.

A lock actuator assembly includes an escutcheon defining a longitudinal axis. A rotatable drive disk is rotatably coupled to the escutcheon about a rotational axis. A slide arm is slidingly coupled to the escutcheon and operably coupled to the drive disk such that movement of the slide arm along the longitudinal axis rotates the drive disk about the rotational axis. Additionally, an electronic actuator is coupled to the escutcheon. The electronic actuator is configured to drive the slide arm along the longitudinal axis, and the drive disk is adapted to couple to a lock mechanism so as to shift the lock mechanism between a locked position and an unlocked position when the drive disk rotates about the rotational axis.

A connection lock is provided, including: a driving member, movable between first and second positions; a locking device by which the driving member is restrictable in the second position; a first housing; an actuating assembly, movably mounted to the first housing and assembled with the driving member; a blocking assembly, mounted to the first housing and movable between release and blocking positions; an electronic transmission unit, connected to the first housing; when the driving member is in the first position, the actuating assembly is driven by the driving member to drive the blocking assembly to the release position, the blocking assembly is detachable from an anti-theft hole; when the driving member is in the second position, the driving member drives the actuating assembly and the actuating assembly restricts the blocking assembly in the blocking position so that the blocking assembly is undetachable from the anti-theft hole.

An exit device according to one embodiment includes a plurality of sensors and an electronic dogging mechanism. The exit device is configured to locally analyze sensor data to determine the security state of the exit device, report data to a management system via a wireless communication channel established between the exit device and the management system, and receive and process instructions to perform an electronic dogging operation.

A cable lock with a bare wire cable, the cable lock including a lock unit for securely grasping the free end of the cable. The cable lock also includes a cable testing mechanism comprising a first cable contact that engages the cable, and a second cable contact that engages the cable. The cable lock also includes an electrical current generating and measuring mechanism powered by a battery, the mechanism being in electric communication with one of the cable contacts for putting current into the cable, and in electric communication with the other of the cable contacts for reading current passing through the cable.