A smart deadlock system according to an embodiment of the present invention includes a thumb-turn, a key cylinder, a connecting shaft connecting the thumb-turn and the key cylinder, and a sensor module. The sensor module may include a sensing unit to sense a rotation state of a rotation sensing element inserted onto the connecting shaft, and generate sensing information associated with the rotation state of the rotation sensing element, and a rotation information generation unit to receive the sensing information from the sensing unit, and generate rotation information associated with an extent of rotation of the rotation sensing element based on the sensing information. According to the smart deadlock system, it is possible to check the operation of the deadlock more accurately by sensing the rotation state of the rotation sensing element using the sensor.

To suppress costs when an electronic lock is used, when key information held by an electronic lock and a server is “K//n” (“n” is an integer), key information “K//n” and new key information “K//n+1” are supplied from a server to a portable terminal of a user who wants to unlock the electronic lock. The key information and new key information are transferred from the portable terminal to the electronic lock, and when the key information transferred from the portable terminal to the electronic lock matches the key information recorded in the electronic lock, the electronic lock is unlocked. When the key information expires, the key information recorded in both the electronic lock and the server are overwritten with “K//n+1.”

An electronic lock cylinder that may be a direct replacement for a European-style standard cylinder is disclosed. The lock cylinder may include a core, a first shaft rotatably mounted in the core, and a second shaft rotatably mounted in the core and coaxial with the first shaft. A first cam and a second cam may be each rotatably mounted in the core and coaxial with the first shaft. The first cam may include a first lug and the second cam may include a second lug, where the first lug and the second lug may each be coupled to a deadbolt. A clutch may be disposed on the first shaft and shiftable from a first position to a second position, and a motor may be disposed in the core and operatively coupled to the clutch and configured to shift the clutch from the first position to the second position. When the clutch is in the first position, the first shaft is operatively coupled to the first cam, and the second shaft is decoupled from both the first cam and the second cam, when the clutch is in the second position, both the first shaft and the second shaft are operatively coupled to the second cam. The lock includes a first shaft rotatably mounted in the core and a second shaft rotatably mounted in the core and coaxial with the first shaft. A clutch is disposed on the first shaft and rotationally fixed to the first shaft but axially shiftable. The lock also includes a slider with a finger, where the finger is engaged with the clutch, and a motor is configured to shift the slider axially between a first position and a second position. In the first position, the clutch is disengaged from the second shaft, and in the second position, the clutch is engaged with the second shaft, such that rotation of the first shaft causes rotation of the second shaft.

A lock can include a motor assembly, a gear assembly, and an unlocking assembly. The motor assembly can include a motor and a drive shaft. The gear assembly can include a cam, a pinion gear, and a pinion. The pinion gear can include a plurality of teeth disposed along only a portion of a perimeter of the pinion gear. The pinion gear can be configured to engage the pinion. The pinion can be configured to translate laterally to release a biasing member to unlock a door of a container.

Electronic locks, electronic lock systems, and electronic lock networks are provided, and can include a latch, an interior unit including an interior handle operable to place the latch in the unlatched position, an interior user-interface, and an interior controller coupled to the interior user-interface; an exterior unit including an exterior handle having an active mode and a non-active mode, the exterior handle operable to place the latch in the unlatched position when in the active mode, an exterior user-interface, a fingerprint sensor configured to sense fingerprint data, and an exterior controller configure to receive the sensed fingerprint data, output the sensed fingerprint data, and place the exterior handle in the active mode upon receiving an active signal; and a main controller coupled to the interior controller and the exterior controller, the main controller configured to receive the sensed fingerprint data from the exterior controller, compare the sensed fingerprint data to a known fingerprint data, and output the active signal to the exterior controller based on the comparison.

A tool box or tool cabinet (hereafter: “tool box”) is provided with a locking mechanism having a locked condition in which it prevents access to tools within the tool box, and an unlocked condition in which it allows access to tools within the tool box. An electric motor has a rotor, and is provided with a microprocessor and control circuit, coupled to the motor for controlling it. The microprocessor is adapted to receive Bluetooth signals when paired to a user's portable Bluetooth-enabled mobile device, The microprocessor and control circuit are effective, when the user's portable Bluetooth-enabled mobile device is sufficiently close to the control circuit to be detected, to energise the motor to rotate the rotor in a first sense, effective to disable the locking mechanism to allow access to the tools.

A keyless gate lock apparatus and system. The keyless gate lock apparatus and system of the present disclosure may comprise a lock assembly comprising a housing configured to be coupled to a first surface of a gate or a fence, a lock plate configured to be coupled to a second surface of the gate or the fence, and a lock bar comprising an elongated body extending from a first end to a second end. The lock assembly may comprise an electronic lock assembly configured to establish a wireless data transfer interface with a mobile electronic device and selectively actuate at least one locking mechanism to unlock the lock bar from the lock assembly in response to authorizing an access request from the mobile electronic device.

An electronic lock assembly includes an exterior assembly, an interior assembly, and a latch having a deadbolt movable between an extended position and a retracted position, the latch being movable in response to rotation of a torque blade. The electronic lock includes a motor within the interior assembly and operable to rotate the torque blade, and a control circuit operatively connected to the motor and configured to selectively actuate the motor. A mortise insert includes a battery subassembly electrically connectable to the control circuit.

Systems and methods for providing a wireless lock system include a locking device wherein the locking device comprises a retractable bolt and a wireless communication transceiver. The systems and methods can also include a bolt catch that is configured to couple with the retractable bolt, wherein, when coupled, the bolt and locking device are locked into a static position relative to the bolt catch. A keypad programmable with a plurality of combination buttons and a wireless communication transceiver can be configured to communicate with the bridge wirelessly. The bolt then protrudes from the locking device to couple with the bolt catch and decouples from the bolt catch and recedes into the locking device in response to one or more wireless signals received from a wireless device. A wireless communication bridge device may also be utilized to provide additional wireless communication links to further devices to expand user reach and interoperability.

An electronic device according to various embodiments of the present invention may comprise: a wireless communication interface; a display; a magnetic stripe transmission (MST) module comprising a coil for inducing generation of a magnetic field; a processor electrically connected to the wireless communication interface, the display, and the MST module; and a memory electrically connected to the processor, wherein the memory stores instructions for controlling the processor, the instructions, when executed, causing the processor to: receive digital card key information for unlocking a door lock apparatus from an external device through the wireless communication interface; convert the digital card information into an MST signal containing the same; activate the MST module in response to an MST module activation request input thereto; and unlock the door lock apparatus by transmitting the converted MST signal through magnetic induction and waking up the door lock apparatus through the transmitted MST signal. Other embodiments are also possible.