The present invention relates generally to mechatronic locks and more specifically, and preferably, wireless mechatronic smart lock systems for locking doors which can be operated by a mechanical tool after positive authentication of the user. In a first aspect, there is provided a mechatronic lock system arranged for actuating a door lock operating member for locking and unlocking a door upon activation of said system comprising: an outside lock interface, comprising means for receiving a mechanical tool, arranged for operating said door lock operating member by a user of said lock system upon receiving said mechanical tool; an inner assembly, comprising: a wireless communication unit, arranged for wireless communication with a wireless communication device for authorizing said user; a control unit, in communicative connection with said wireless communication unit and arranged to activate said system for unlocking said door by activating a mechatronic clutch arranged for coupling said outside lock interface to said door lock operating member; wherein said mechatronic clutch is activated upon positive authorization of said user for opening said door by operating said outside lock interface.

Apparatus for unlocking and locking a lock (1′) enabling access to protected areas. The apparatus comprises a housing (5) with a housing interior (64). A rotational shaft (30) is in operative connection with the housing. A motor (10) extends in the housing interior (64), is in operative rotational connection with shaft (30) and is operative to rotate the shaft (30). A battery cell (9) extends in the housing interior (64) and is in partially surrounding relation of the motor (10). The battery cell is in operative electrical connection with the motor (10). In cross section, the battery cell (9) includes at least two points (34) and (36) such that a line segment (32) joining these two points passes through the motor (10).

Certain aspects of the technology disclosed herein include an apparatus and method for storing energy in a electromechanical lock. The electromechanical lock can include a main housing and a deadbolt. The main housing can be configured to extend a deadbolt along a path to lock and/or unlock a door. The deadbolt can have a hollow inner region configured to receive an energy storage device. The energy storage device within the deadbolt can be electrically connected to the main housing. The energy storage device can be used to power an actuator and/or accelerometer in the main housing.

Systems and methods for controlling access to a secured space are disclosed. The system includes a locking device having a body having a rotatable locking cam having a locked paddle and an unlocked paddle. The cam is rotatable between a first position and a second position. The body also has a locking pin and a power supply for supplying electrical power to circuit components of the locking device. The locking device also includes a shackle having two arms. One of the two arms has a groove in a bottom portion thereof configured to engage with the locking pin when the shackle is in a closed position. In the first position, the locked paddle of the rotatable locking cam engages the locking pin in the groove. In the second position, the locked paddle of the rotatable locking cam is disengaged from the locking pin.

A motor vehicle door lock, such as a motor vehicle bonnet lock includes a locking mechanism which substantially consists of a rotary latch and a pawl. The locking mechanism interacts with a striker element on a bonnet. The lock further has an unlocking/opening mechanism for the bonnet, which mechanism is equipped with a release element provided in the interior of a motor vehicle body. The release element is operated twice to open the bonnet. The locking mechanism is transferred to a pre-latched position after the release element has been operated at least once, with the striker element still being trapped. The bonnet is opened from the pre-latched position by lifting the pawl off the rotary latch with the aid of a power mechanism, said lifting being activated separately.

A wirelessly-controlled jamb-mounted access control system can include an in-jamb housing, a lock body at least partially inside the housing and rotatable about a first axis between locked and unlocked positions. The first axis can extend parallel to the jamb, and the lock body can include inner and outer sidewalls that define a latch cavity configured to receive a latch tongue of a door. The wirelessly-controlled j amb-mounted access control system can further include an actuator configured to control release of the lock body from the locked position in response to a control signal.

A jobsite box includes a body, the body having an interior, an exterior, and a lid, a key pad positioned on the exterior of the body, the key pad being in communication with a controller positioned on the body, a locking mechanism connected to the body, the locking mechanism being configured to lock and unlock the jobsite box, a battery positioned in the interior of the body, the battery configured to power the locking mechanism. The controller is configured to lock or unlock the locking mechanism when a predetermined code is entered into the key pad.

A merchandise security system for protecting an item of merchandise from theft. The merchandise security system comprises a smart device and an electronic key coupled to the smart device. The electronic key is configured to communicate with a merchandise security device for operating a merchandise security device.

A method for operating a combination lock including a body and a shackle. A keybox is located in the body and includes a cover. The body includes a first control panel, a second control panel and a switch button. The method includes a step of setting a first combination to the first control panel, a second combination to the second control panel. A step of switching the switch button to the first position so that the shackle is operated and the cover is opened relative to the keybox by inputting the first combination or the second combination from the first control panel. When the switch button is switched to the second position, the shackle is operated and the cover is opened relative to the keybox by inputting the first combination or the second combination from the second control panel.

An electronic lock includes an interior subassembly including a manual turnpiece, a control circuit, and a motor actuatable by the control circuit, and an exterior subassembly including a facial authentication circuit operatively connected to the control circuit. The electronic lock includes a latch operatively connected to the interior subassembly, the latch being engageable by the manual turnpiece or the motor to move the electronic lock between a locked state and an unlocked state. The facial authentication circuit includes at least one camera and is configured to generate an authentication signal to the control circuit, and wherein, at least in part in response to the authentication signal, the control circuit is configured to actuate the motor to move the electronic lock between the locked state and the unlocked state.