An exemplary system includes a mechanical key and an access control device. The access control device includes a housing defining a keyway that has a fixed position within the housing. The access control device further includes a root depth sensor assembly, an insertion depth sensor assembly, a control assembly in communication with the sensor assemblies, and an electronic lock device. The control assembly is configured to determine the bitting code of the mechanical key based upon information received from the sensor assemblies, to compare the bitting code of the mechanical key to a lock/unlock bitting code; and to transmit a lock/unlock command in response to the bitting code matching the lock/unlock bitting code. The electronic lock device is configured to transition between a locked state and an unlocked state in response to receiving the lock/unlock command and without requiring rotation of the mechanical key.

An interlock system comprising: a first lock including a first lock memory configured to store one or more virtual keys; and a first key including a first key memory configured to store one or more virtual keys, wherein the first lock is configured to be actuated between a first condition and a second condition, when a first virtual key stored in the first key memory is transferred to the first lock memory, by engagement of the first key and first lock, and movement of the first key with respect to the first lock.

A smart door lock may include latch mechanism for locking and unlocking doors; authorization module for authorizing or de-authorizing authority of mechanical key for opening latch mechanism; the mechanical key for inserting into the latch mechanism for unlocking after authorized by the authorization module. Thanks to the structure of smart door lock, there is no need to carry the mechanical key all the time.

A mechanical key includes a key pattern recessed in the mechanical key in a thickness direction and key segments separable in the thickness direction. At least one of the key segments includes a key pattern slit. The key pattern slit extends through the at least one of the key segments in the thickness direction and is shaped in conformance with the key pattern.

A locking module includes: a storage unit in which a password is saved; an input unit which receives a number as an input; a locking unit which restrains a zipper and thereby restricts the sliding of the zipper in a state in which two housings are coupled through the zipper; and a control unit which, when the saved password matches the input number, transmits a lock release signal to the locking unit and controls to release the zipper restrained by the locking unit.

The invention relates to a closing system having a key (1.1) coded in a quantum-physical manner, which withstands very high mechanical forces, wear, or temperatures. The key consists, for example, of a solid stainless-steel bar having, for example, a diameter of 8 mm and, for example, a length of 120 mm. The coding of the key (1.1) is based on a quantum-physical solid body cryptography. The matter of the solid main body is partially changed in such a way that this change can be read out by means of read-out methods suitable therefor. The coding occurs into the depth of the main body such that external influences such as damage to the surface do not impair the function of the key. The quantum key processed in such a way has no visible or perceptible features of the coding. More than 500 billion different codings are accommodated on a length of approximately 50 mm. The locking system comprises a decoding unit on the lock for decoding the codings, which have been introduced into the solid metal of the key in a quantum-physical manner. The arrangement according to the invention offers a locking system that is extremely resistant to forgery and manipulation, on the basis of quantum-physical solid body cryptography.

An electrical mechanical locking device. A lock has an outer shell with an indentation. An inner body is rotatably housed within the outer shell. A contact pin is connected to the inner body. A printed circuit board frame is rigidly connected to the inner body. A printed circuit board is attached to the printed circuit board frame. A driver arm support bracket is rigidly connected to the printed circuit board frame. A lock microprocessor is connected to the printed circuit board and electrically connected to the contact pin. The lock microprocessor is connected to a key identification code verification database. An electrical actuator is electrically connected to the lock microprocessor. A driver arm is pivotally connected to the driver arm support bracket. The electrical actuator is connected to the driver arm. A jam plate is connected to the driver arm. A jam plate return spring is connected to the jam plate and the printed circuit board frame. A locking pin is covered by the jam plate and inserted into the outer shell indentation when the electrical mechanical device is locked. When the electrical mechanical device is unlocked the locking pin is not covered by the jam plate and rises clear of the indentation. A powered key includes a key microprocessor. A battery power source is electrically connected to the key microprocessor. The key microprocessor has access to key database that includes a programmable key identification code for identifying the key. The key also includes a contact tip for insertion into the lock and for making electrical contact with the lock contact pin. In a preferred embodiment the electrical actuator is a nitinol wire.

A locking device that can be mounted into a rotating or swinging door is disclosed. The locking device can have a deadbolt. The locking device can detect the position of the deadbolt and/or whether the door is closed. The locking device can have a camera, microphone and speaker. The locking device can send images detected by the camera and audio detected by the microphones to a remote computer.

An exemplary system includes a mechanical key and an access control device. The access control device includes a housing defining a keyway that has a fixed position within the housing. The access control device further includes a root depth sensor assembly, an insertion depth sensor assembly, a control assembly in communication with the sensor assemblies, and an electronic lock device. The control assembly is configured to determine the bitting code of the mechanical key based upon information received from the sensor assemblies, to compare the bitting code of the mechanical key to a lock/unlock bitting code; and to transmit a lock/unlock command in response to the bitting code matching the lock/unlock bitting code. The electronic lock device is configured to transition between a locked state and an unlocked state in response to receiving the lock/unlock command and without requiring rotation of the mechanical key.

Provided are an electronic key management system and a server. The electronic key management system includes: an electronic key configured to lock and unlock an electronic locking device; an electronic key storage device configured to include a plurality of key holes and a key holder fastened with an electronic key carried into the key hole, and control the key holder according to a preset electronic key access right; a management server configured to set an access right to the electronic locking device of the electronic key, transmit a one-time authentication ID to the electronic key that is put into the electronic locking device and electrically connected to the electronic locking device, and receive log information of the electronic key on the electronic locking device in real time; and a user terminal configured to transmit and receive the log information and the one-time authentication ID between the electronic key and the management server, and display real-time log information.