A deadbolt control and security system for preventing rotation of a deadbolt manual egress handle of a deadbolt lock is described herein. The system preferably includes a deadbolt interface unit and at least one actuator unit. The deadbolt interface unit has a manual mode (the deadbolt interface unit manual egress handle controlling locking and unlocking the deadbolt lock) and a remote mode (the at least one actuator unit controlling locking and unlocking the deadbolt lock). The deadbolt interface unit includes: a deadbolt interface unit manual egress handle; a gear train having a shaft coordinated with the deadbolt interface unit manual egress handle; a unit-handle coupler that interfaces between the deadbolt manual egress handle and the deadbolt interface unit manual egress handle via the shaft; and a clutch. Preferred systems prevent the deadbolt lock from being unlocked using keys and/or other bypass tools.

An electronically-controlled manually-actuated deadbolt lock is provided. The electronically-controlled manually-actuated deadbolt lock includes an internal spring-actuated coupling mechanism that, when a user is authenticated, the coupling mechanism is placed in an engaged position that allows a deadbolt latch to be moved into a locked or unlocked position responsive to a manual rotation of a turn piece. Because the deadbolt latch is manually driven, a warped door condition can be overcome. Additionally, because the deadbolt latch is manually actuated, operation of the electronic motor may be decreased, which may increase battery life.

An actuating apparatus for opening and closing a cover in or on a vehicle has a blocking device for blocking the cover in a locked position. The blocking device has a transmission mechanism with a rotation part (64.1; 50) mounted rotatably and driveable by an actuator (34), and a blocking bar (62) which is operatively connected to the rotation part. The transmission mechanism converts a rotation movement of the rotation part into an axial movement of the blocking bar. The blocking bar is transferable with the aid of the rotation part from a release position into a blocking position. The transmission mechanism is self-locking so that, at least whenever the blocking bar is in the blocking position, the rotation part is not driveable via an axial movement of the blocking bar, and the rotation part prevents an axial movement of the blocking bar out of the blocking position.

An electronic lockbox includes a latching apparatus that uses a rotary actuator with multiple positions to achieve multiple locking states. Multiple positions of the actuator are detected, using optical sensors. The locking mechanism includes an outer sleeve and an inner cylindrical barrel that are coupled with torsion springs. The lockbox has a shackle and a key bin that include latch pins which are retained by the inner barrel when in the locked state, and the barrel can be rotated to either release the shackle or to release the key bin that typically holds a building's key. During insertion of a latch pin into the rotatable barrel, the maximum torque imparted on a first spur gear by the torsion spring, at a maximum rotation angle of the rotatable barrel, is sufficient to rotate the barrel back to its neutral position after the latch pin has been fully inserted into the barrel, and is less than or equal to a back drive torque limit of a prime mover of the rotary actuator.

The present disclosure is directed to an electronic deadbolt control system including a deadbolt configured to extend or retract between a locked position and an unlocked position, respectively. An output shaft connected between a final gear and the deadbolt is configured to transmit an actuation force to the deadbolt from an electric motor. A first magnet and a second magnet are associated with the final gear to define a home position for either a left hand deadbolt or a right hand deadbolt. A cam is positioned on the output shaft to engage with a switch such that, in combination with a threshold current motor output, the control system determines whether the deadbolt is in an extended position or a retracted position. A thumb-turn shaft is disengaged from the final gear in the home position to permit manual actuation of a thumb-turn.

A door latch for an electrical appliance includes a rotary gripper movably disposed between a gripping position and a release position with rotational displaceability and having a gripping mouth delimited between a pair of jaws. The rotary gripper is adapted to hold captive a striker in the gripping mouth for holding closed a door of the electrical appliance in the gripping position and to permit release of the striker for opening the door in the release position. The gripping position and the release position correspond to different rotational positions of the rotary gripper. A spring arrangement in the gripping position of the rotary gripper exerts on the rotary gripper a bias which counteracts a movement of the rotary gripper towards the release position. An opener mechanism for opening the closed door includes a movably arranged opening element separate from the striker and a drive unit for driving the opening element.

A lock and lid lock for an appliance are provided. The lock has a base supporting a driving mechanism, a sliding mechanism, a connecting mechanism and a locking mechanism. The driving mechanism includes a driving unit that drives rotation of a screw rod. A sliding block is connected to a gear that is engaged with the screw rod and drives the sliding block to move linearly back and forth with the rotation of the screw rod. One end of the connecting mechanism is connected to the sliding block and the other end is connected to the locking mechanism. This allows linear movement of the sliding block to be converted into rotational movement of the locking mechanism. The locking mechanism is rotatably connected to the base and may include a locking portion which is configured to unfold or retract relative to the base along with the rotation of the locking mechanism.

An electronic drive for a lock assembly includes a housing, a motor disposed within the housing, and at least one link bar coupled to the motor. The at least one link bar at least partially extends out of the housing. The electronic drive also includes a driven disk coupled to a first end of the at least one link bar and rotatable about a rotational axis. The driven disk is adapted to couple to the lock assembly, and upon rotation, extend and retract at least one locking element. In operation, the motor selectively drives substantially linear movement of the at least one link bar to rotate the driven disk about the rotational axis.

The present disclosure generally relates to providing electronic locking systems. Using novel designs and network technology, the present systems, methods, and apparatuses can provide a secure alternative to a cam lock or a lock box for storing items that may be left unattended, without the use of a physical key. For example, in certain embodiments, the present systems, methods, and apparatuses can facilitate the locking and unlocking of a cam lock or a lock box by using a digital construct, an encryption system, and various native and/or third-party software components.

An exemplary apparatus includes a housing, a lock mechanism mounted to the housing, an electromechanical driver, a first override mechanism, and a second override mechanism. The electromechanical driver is mounted to the housing and is operable to unlock the lock mechanism. The first override mechanism is movably mounted to the housing and is operable to unlock the lock mechanism. The second override mechanism is movably mounted to the housing and is operable to unlock the lock mechanism. The apparatus has a first configuration in which a lock cylinder is engaged with the first override mechanism such that actuation of the lock cylinder unlocks the lock mechanism. The apparatus has a second configuration in which the lock cylinder is engaged with the second override mechanism such that actuation of the lock cylinder unlocks the lock mechanism.