A key-shape data management system includes a storage server, an acceptance server, and a transmission server. The storage server stores vehicle identification information capable of identifying a vehicle, mechanical lock identification information capable of identifying a mechanical lock mounted on the vehicle, key-shape data of a mechanical key used in combination with the mechanical lock, and information on multiple manufacturing bases capable of manufacturing the mechanical key. The acceptance server accepts a request for acquiring the mechanical key together with determining information and delivery location information indicating a delivery location of the mechanical key. The transmission server determines the vehicle identification information based on the determining information, determines the key-shape data based on the vehicle identification information, determines one of the manufacturing bases corresponding to the delivery location, and transmits the delivery location information and the key-shape data to the determined manufacturing base.

An access apparatus (ZV) for a vehicle (FZ) has a vehicle-side position-determining device (PBE) for determining the position (POS1, POS2, POS3) of a mobile identification signal generator (IDG) with respect to the vehicle. In addition, said access apparatus (ZV) has a vehicle-side control device (STE) for emitting location-determining signals (LS1) to the mobile identification signal generator (IDG) for determining the position thereof. In this context, the vehicle-side control device (STE) is configured to control the frequency of the emission of the location-determining signals as a function of the position of the mobile identification signal generator with respect to the vehicle. In this way, the power consumption both in the vehicle and in the identification signal generator can be reduced on the basis of the location-dependent adaptation of the emission of the interrogation signals, without adversely affecting reliable operation of the access apparatus.

An electromechanical locking system includes one or more moveable locking elements and one or more actuators configured to move each of the one or more moveable locking elements between positions. The system includes a receptacle configured to receive a key, a sensor, a processor; and a computer-readable storage medium. The processor causes the sensor to scan the key and detect one or more features of the key, identify a first code that corresponds to the detected features of the key, and apply one or more functions to the first code to yield a second code. The second code includes one or more characters that each character corresponds to one of the plurality of positions. The processor causes the one or more actuators to move the one or more movable locking elements to the positions that correspond to the one or more characters of the second code.

There is provided a lock control device attachable to a locking mechanism, the lock control device including circuitry configured to receive key information and a process request from a first communication device, the key information including authorization information of the first communication device related to a plurality of types of functions of the lock control device, and determine whether the process request is permitted based on the key information, wherein the key information further includes identification information of the first communication device.

A lock device including a keyway sized and configured to receive a key, a sensor assembly including an optical source and a key height sensor, and a controller in communication with the sensor assembly. The optical source is configured to generate an optical signal, and the key height sensor is configured to generate a key height signal in response to receiving the optical signal. The key is configured to interact with the optical signal such that the key height signal varies based upon the height of the key. The controller is configured to generate a key profile based at least in part upon the key height signal, to compare the key profile to authorization data, to select an action based upon the comparing, and to perform the action.

A key, comprising: a key head; and a key shank (10), characterized in that the key shank (10) includes a torsion section (20) that is formed, in particular cold formed, along a longitudinal axis (L) at least in sections, wherein the key shank (10) includes a base cross-section (26) in a transition portion to the torsion section (20), wherein a cross-section (30) of the key shank (10) protrudes at least in sections beyond the base cross-section (26) in the torsion section (20) in a direction towards the key tip (70).

An electromechanical locking system includes one or more moveable locking elements and one or more actuators configured to move each of the one or more moveable locking elements between positions. The system includes a receptacle configured to receive a key, a sensor, a processor; and a computer-readable storage medium. The processor causes the sensor to scan the key and detect one or more features of the key, identify a first code that corresponds to the detected features of the key, and apply one or more functions to the first code to yield a second code. The second code includes one or more characters that each character corresponds to one of the plurality of positions. The processor causes the one or more actuators to move the one or more movable locking elements to the positions that correspond to the one or more characters of the second code.

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.

A system may include a lock assembly having a shell and a plug rotatable with respect to the shell and a lock operating object for operating the lock assembly including a key. The system may further include an audit enhancement assembly configured to facilitate creation of an audit trail of operation of the lock assembly by the lock operating object, and may include a motion sensor configured to sense rotational motion of the lock operating object and/or the plug of the lock assembly. The audit enhancement assembly may include processing circuitry in communication with the motion sensor, and memory circuitry in communication with the processing circuitry to receive and record a value derived from a motion signal from the motion sensor and a temporal value associated with a motion signal event.

The present invention generally relates to the field of replicating or copying keys. More specifically, the present invention relates to creating a copy of a master key based on a captured image of the master key by using a laser scanning of the master key and decoding the master key based on the captured image. The present invention identifies a set of target key information based on the image of the master key to provide for the cutting of a duplicate key blade copy using a key scanning and cutting system located at a retail or end location. Additional key information may also be captured along with the image of the master key.