An electronic storage cabinet lock includes a lock housing, a lock core, a circuit board, a motor assembly, a clutch mechanism and a battery assembly that are installed in an outer shell. A button assembly and a handle are mounted on the outer side of the outer shell. A cam is mounted on the motor assembly. One end of the lock core is secured in a shaft hole of the handle. When a password is correctly inputted, the button assembly transmits information to the circuit board to control the motor assembly to operate. The cam is driven to rotate to control the open state or closed state of the clutch mechanism. The handle can rotate to drive the lock core to rotate, thereby rotating a lock tongue to open the lock.

A method for detecting a change of a state of a lock by means of a device connected to a key for that lock. The method includes measuring a change of a position of the key about three axes; and indicating that the state of the lock has changed if the measured change of position of the key indicates that the key has rotated about a first axis by an angle greater than or equal to a primary threshold value and about the other two axes by an angle smaller than a secondary threshold value.

A safety switch (2) with a latching unit (12), by means of which an associated actuator (3) is held in a latched position. The latching unit (12) has an arrangement of latching jaws (14). Each latching jaw (14) is spring-mounted by means of a spring unit (15). The latching jaws (14) are concentrically arranged and each face one another with a first free end and delimit an insertion opening (A). The latching jaws (14) are held in latched position by the spring forces generated by the spring units (15). The latching jaws (14) can be displaced against the spring forces of the spring unit (15), which serves to enlarge the insertion opening (A).

A key holder designed for use with manual key switches affixes a key onto a control box. The key holder includes a rotor housing, a key rotor, and a threaded opening. The key is mounted into the key rotor before being inserted into the control box. Further, the key rotor is rotatably mounted into the rotor housing via the threaded opening. The key rotor includes an interior face, an exterior face, a threaded body, and a key slot. The interior face and exterior face are positioned opposite each other about the threaded body. The key slot traverses through the threaded body. To connect the key rotor to the rotor housing, the threaded body is screwed into the threaded opening. This transforms the rotational motion into the linear motion of the key rotor, which along with the locking feature of the manual key switch, prevents the key from rotating.

A motor vehicle door lock apparatus includes a meshing mechanism configured to mesh with a striker, an outside operation switch, an inside handle, a locking and unlocking mechanism configured to be selectively switched to an unlocking state and a locking state that cannot be released based on a door opening operation of the inside handle, a control unit configured to authenticate a transmitter signal and, when the transmitter is situated outside a vehicle, to enable operation of the outside operation switch when authenticated and to disable operation of the outside operation switch when not authenticated and an electric releasing mechanism to release a meshing of the meshing mechanism by the control unit driving a releasing motor to activate operation of the outside operation switch when the control unit authenticates the transmitter outside the vehicle, regardless of the locking and unlocking mechanism staying in the unlocking or the locking state.

An electronic storage cabinet lock includes a lock housing, a lock core, a circuit board, a motor assembly, a clutch mechanism and a battery assembly that are installed in an outer shell. A button assembly and a handle are mounted on the outer side of the outer shell. A cam is mounted on the motor assembly. One end of the lock core is secured in a shaft hole of the handle. When a password is correctly inputted, the button assembly transmits information to the circuit board to control the motor assembly to operate. The cam is driven to rotate to control the open state or closed state of the clutch mechanism. The handle can rotate to drive the lock core to rotate, thereby rotating a lock tongue to open the lock.

An electronic gaming machine includes a cabinet, an access door, an electromechanical latch mechanically coupled to the cabinet and configured to mechanically engage and disengage the access door, and a switch assembly operable to control the electromechanical latch. The switch assembly includes a lock mechanically coupled to the cabinet and extending into the cabinet, a cam mechanically coupled to a rotatable portion of the lock within the cabinet, and a switching element mounted within the cabinet proximate the cam and configured to be mechanically engaged and actuated by the cam when the cam rotates into contact with the switching element, wherein the switching element is electrically connected to the electromechanical latch and is further configured to control the electromechanical latch in response to actuation by the cam.

A portable electronic lock for luggage, comprising: a housing and a securement member in cooperation with the housing to secure an item to the lock; a locking mechanism in the housing in communication with the securement member to releasably secure the securement member to the housing; a communications module in the housing for operating the locking mechanism to release and secure the securement member in response to a wireless signal; and a secondary release system for releasing the locking mechanism, wherein the secondary release system is selectively operable by a user.

A method for detecting a change of a state of a lock by means of a device connected to a key for that lock. The method includes measuring a change of a position of the key about three axes; and indicating that the state of the lock has changed if the measured change of position of the key indicates that the key has rotated about a first axis by an angle greater than or equal to a primary threshold value and about the other two axes by an angle smaller than a secondary threshold value.

The lock with key having expanding arm elements is an electromechanical lock mechanism. The lock with key having expanding arm elements comprises a key structure, a lock structure, and a lock control circuit. The lock structure is a fastening device. The lock structure secures the position of a first object relative to a second object. The lock structure is a releasable structure such that the position of the first object relative to the second object can be adjusted after the lock structure is released. The lock control circuit is an electric circuit. The lock control circuit forms an electronic locking mechanism that fastens and releases the locking structure. The key structure is a multi-blade structure that controls the operation of the lock control circuit.