A locking mechanism for a bored lock has a lock chassis, a locking element, a motor housing, a reversible electric motor, an auger, and a spiral lock spring disposed between the locking element and the motor. The motor may drive the auger in a first or second rotational direction to move the spring towards/away from the motor to reduce/increase spring force on the locking element, thereby moving the locking element to an unlocked/locked position. One of the locking element and motor housing has a projection while the other has a guideway for slideably receiving the projection. The guideway prevents rotation of the locking element with respect to the motor as it moves between locked and unlocked positions. The projection and guideway are interlocked to prevent disassembly of the locking element and motor housing.

A portable safe that includes a lower shell defining an internal cavity and having a cable aperture and a cable end aperture defined on the body of the safe. The lower shell is lockably and translatably coupled to the cover and the safe includes a cable-reel assembly with a retractably extendable cable having a free end. The cable is operably configured to extend a cable length sufficient for the free end to at least partially surround the safe body and be received within the cable end aperture. The safe includes a cable locking position along a cover translation path with the cover and lower shell encapsulating the second cavity and with the free end of the cable longitudinally retained by the cover and/or the lower shell. The safe also includes an article loading position to expose the second cavity.

A portable safe that includes a lower shell defining an internal cavity and having a cable aperture and a cable end aperture defined on the body of the safe. The lower shell is lockably and translatably coupled to the cover and the safe includes a cable-reel assembly with a retractably extendable cable having a free end. The cable is operably configured to extend a cable length sufficient for the free end to at least partially surround the safe body and be received within the cable end aperture. The safe includes a cable locking position along a cover translation path with the cover and lower shell encapsulating the second cavity and with the free end of the cable longitudinally retained by the cover and/or the lower shell. The safe also includes an article loading position to expose the second cavity.

A motor-driven door latch for a vehicle includes a catch part which is caught on a striker mounted on the vehicle. A door locking and releasing part includes a main motor and applies torque to the catch part through the main motor to allow the catch part to be locked to or released from the striker. A motor-driven emergency door releasing part is provided with an auxiliary motor and is contacted with the door locking and releasing part. An inside emergency operating lever is connected with an inside handle installed at the door for the vehicle. An outside emergency operating lever is connected with an outside handle installed at the door for the vehicle. A manual emergency door release part is connected with the inside emergency operating lever.

A hinged object, such as a door, window, gate, lid, etc., comprises a first hinge, a second hinge, and an electromechanical locking device mounted on or in the hinged object. A first electrical wire is embedded in the hinged object that couples the electromechanical locking device to the first hinge, the first hinge to couple to a low-voltage power source to supply low-voltage electrical current to the electromechanical locking device via the first electrical wire. A second wire is embedded in the hinged object that couples the electromechanical locking device to the second hinge, the second hinge to couple to the low-voltage power supply to return low-voltage electrical current from the electromechanical locking device to the low-voltage power supply via the second electrical wire.

An actuator (24, 528, 606, 646, 670, 700, 702) is configured to cause a latch assembly (22, 322, 422, 522, 526, 604, 644, 668, 694) to be changed from a closed condition in which an item is latched, to an open condition in which the item is unlatched. A catch jaw (30, 530, 690) is operative in a first position to engage a member (106) connected to the item when the latch assembly is in the closed condition. The catch jaw in a second position enables the member to disengage from the catch jaw when the latch assembly is in the open condition. The actuator assembly includes a drive (152, 526, 608, 706) and a gear system (157, 563, 610, 712). The gear system is operative to move a release member (174, 538, 612, 722, 764). The release member is configured to be in operative connection with the catch jaw such that the movement of the release member causes the catch jaw to be enabled to move to the second position.

A locking mechanism for a bored lock has a lock chassis, a locking element, a motor housing, a reversible electric motor, an auger, and a spiral lock spring disposed between the locking element and the motor. The motor may drive the auger in a first or second rotational direction to move the spring towards/away from the motor to reduce/increase spring force on the locking element, thereby moving the locking element to an unlocked/locked position. One of the locking element and motor housing has a projection while the other has a guideway for slideably receiving the projection. The guideway prevents rotation of the locking element with respect to the motor as it moves between locked and unlocked positions. The projection and guideway are interlocked to prevent disassembly of the locking element and motor housing.

An exit device according to one embodiment includes a plurality of sensors and an electronic dogging mechanism. The exit device is configured to locally analyze sensor data to determine the security state of the exit device, report data to a management system via a wireless communication channel established between the exit device and the management system, and receive and process instructions to perform an electronic dogging operation.

A movably mounted actuation element and an actuator apparatus for producing a feedback movement of the actuation element depending on an excitation signal are included in an operating apparatus for a motor vehicle. The actuation element has a defined rest position in the housing. The actuation element is arranged in such a rest position in the non-actuated state in which at least one centering element blocks the feedback movement. The actuation element carries out an evasive movement in a direction aligned obliquely or perpendicular to the direction of the feedback movement in the case of an application of an operating force on part of the user, the actuation element switching from the rest position into a released position, in which it is released for the feedback movement by the at least one centering element, as a result of the evasive movement.

A locking mechanism for a bored lock has a lock chassis, a locking element, a motor housing, a reversible electric motor, an auger, and a spiral lock spring disposed between the locking element and the motor. The motor may drive the auger in a first or second rotational direction to move the spring towards/away from the motor to reduce/increase spring force on the locking element, thereby moving the locking element to an unlocked/locked position. One of the locking element and motor housing has a projection while the other has a guideway for slideably receiving the projection. The guideway prevents rotation of the locking element with respect to the motor as it moves between locked and unlocked positions. The projection and guideway are interlocked to prevent disassembly of the locking element and motor housing.