A lock assembly comprises a driving member, a drive assembly, and an engaging member. The drive assembly comprises a drive connector operatively connected to the driving member, a lead screw operatively connected to the drive connector, a carriage configured and arranged to move along the lead screw, and an elongate member operatively connected to the carriage. The driving member is configured and arranged to rotate the drive connector, and the drive connector is configured and arranged to rotate the lead screw. Rotation of the lead screw moves the carriage along the lead screw and the elongate member moves with the carriage between locked and unlocked positions. The engaging member is configured and arranged to selectively engage the elongate member in the locked position.

A control structure of a door lock contains: a body, a slidable partition, a motor, a slide cylinder, a deadbolt, a latch, a first resilient element, and a second resilient element. The body includes a first cap, a second cap, an open segment, a close segment, a drive space, a holder, a groove, and an abutting post. The slidable partition is accommodated in the body and includes a slot, two spaced first driving extensions, a second driving extension, a through hole, two symmetrical hooks, and a seat. The motor is accommodated in the holder. The slide cylinder is received in the drive space. The deadbolt is movably received in the opening. The latch is accommodated in the notch. The first resilient element is positioned on the second positioning segment and the first positioning segment. The second resilient element is positioned on the first locating protrusion.

An access control device generally includes an electromechanical actuator operable to transition the access control device between a locked state and an unlocked state, an energy storage device operable to store electrical power from a power supply, and control circuitry. The control circuitry is configured to direct a first electrical power from the energy storage device to the electromechanical actuator in response to one or more first criteria. In a fail secure mode, the first electrical power is configured to cause the electromechanical actuator to transition the access control device to the locked state. In a fail safe mode, the first electrical power is configured to cause the electromechanical actuator to transition the access control device to the unlocked state. Certain embodiments further include a user-adjustable switch operable to transition the control circuitry between the fail secure mode and the fail safe mode.

A control structure of a door lock contains: a body, a slidable partition, a motor, a slide cylinder, a deadbolt, a latch, a first resilient element, and a second resilient element. The body includes a first cap, a second cap, an open segment, a close segment, a drive space, a holder, a groove, and an abutting post. The slidable partition is accommodated in the body and includes a slot, two spaced first driving extensions, a second driving extension, a through hole, two symmetrical hooks, and a seat. The motor is accommodated in the holder. The slide cylinder is received in the drive space. The deadbolt is movably received in the opening. The latch is accommodated in the notch. The first resilient element is positioned on the second positioning segment and the first positioning segment. The second resilient element is positioned on the first locating protrusion.

An electric control device for a latch includes a mounting seat having including a first compartment and a second compartment. An electric locking device includes a bracket securely mounted in the second compartment and a driving member securely mounted to the bracket. The driving member for actuating the locking member is coupled with a locking member. The locking member includes a stop portion having a protrusive end abutting a first face of the bracket without interfering with movement of the locking member. A locking cap device is pivotably connected to the mounting seat and is received in the first compartment. The locking cap device includes an inner side having a first protrusion corresponding to the stop portion. When the stop portion is located on a rotational path of the first protrusion, the locking cap device is not pivotable from a closure position to a non-closure position.

An anti-theft device for securing an article of merchandise against unauthorized removal from a display counter. The anti-theft device includes a plurality of arms configured to immobilize the article of merchandise relative to a tray. At least one arm is operated by an electromechanical release mechanism between closed and opened positions. When the electromechanically actuated arm is in the closed position, the article of merchandise is immobilized relative to the tray. When the electromechanically actuated arm is transitioned into the open position, the article of merchandise can be removed from the tray. The anti-theft device may include a locking mechanism configured to transition between a locked configuration, in which the arms are immobilized relative to the tray, and an unlocked configuration, in which the arms can be extended or retracted relative to the tray.

An interchangeable electronic lock mechanism provides selective access to a motor controlled latching system including a motorized pin to lock and unlock a knob assembly. The lock mechanism may be used to replace key operated locking cores, on the exterior of a storage unit, with a plug and optional adapter inserted into a remaining shell housing, and a driver to control access to a storage unit. Manual rotation of the knob activates the drive assembly to control access to the storage unit. An optional break away security feature in the knob inhibits unauthorized unlatching of the lock. When the lock is unlatched, the knob rotates the drive assembly including the plug and adapter within the shell housing, and in turn, activates the driver to operate the lock assembly in the storage unit. An optional modular chassis assembly includes a removable array of components for testing, maintenance and repair.

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.

An access control device generally includes an electromechanical actuator operable to transition the access control device between a locked state and an unlocked state, an energy storage device operable to store electrical power from a power supply, and control circuitry. The control circuitry is configured to direct a first electrical power from the energy storage device to the electromechanical actuator in response to one or more first criteria. In a fail secure mode, the first electrical power is configured to cause the electromechanical actuator to transition the access control device to the locked state. In a fail safe mode, the first electrical power is configured to cause the electromechanical actuator to transition the access control device to the unlocked state. Certain embodiments further include a user-adjustable switch operable to transition the control circuitry between the fail secure mode and the fail safe mode.

An anti-theft device for securing an article of merchandise against unauthorized removal from a display counter. The anti-theft device includes a plurality of arms configured to immobilize the article of merchandise relative to a tray. At least one arm is operated by an electromechanical release mechanism between closed and opened positions. When the electromechanically actuated arm is in the closed position, the article of merchandise is immobilized relative to the tray. When the electromechanically actuated arm is transitioned into the open position, the article of merchandise can be removed from the tray. The anti-theft device may include a locking mechanism configured to transition between a locked configuration, in which the arms are immobilized relative to the tray, and an unlocked configuration, in which the arms can be extended or retracted relative to the tray.