The present disclosure relates to a bi-directional overrunning clutch, electronic door locks having bi-directional overrunning clutches, and methods of using the same. In certain embodiments, the electronic door lock includes a first locking mechanism for driving an inner wheel through a first torque to rotate a rotatable shaft to operate a locking device on a door by a user from outside, a second locking mechanism for driving inner wheel through the first torque to operate the locking device from an inside, a third locking mechanism for driving an outer wheel rotatable coaxially around the rotatable shaft through a second torque to operate the locking device electronically, and the bi-directional overrunning clutch. When outer wheel rotates at second torque, inner wheel and rotatable shaft rotate along with outer wheel, and when inner wheel rotates at first torque, outer wheel does not rotate along with inner wheel and rotatable shaft.

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.

A system of isolation management comprises a computer for generating an isolation plan; a lockbox configured to receive the isolation plan from the computer; a mobile device associated with an individual, and one or more locks for isolation locking of an asset by each individual according to the isolation plan. The mobile device is allocated to the lockbox according to the isolation plan. The lockbox is configured to recognise the mobile device when proximal to the lockbox. The one or more isolation locks are removably housed in the lockbox. The one or more isolation locks are each able to be recognised by the mobile device and the mobile device is configured to record an association of one or more of the isolation locks to the mobile device according to the isolation plan. There is also an isolation point for isolating the asset with the one or more isolation locks according to the isolation plan. The isolation point is able to be recognised by the mobile device.

A lockset that includes a latch assembly, an interior assembly and an exterior assembly. The latch assembly includes a bolt movable between an extended position and a retracted position. The interior assembly is configured to electronically control movement of the bolt between the extended position and the retracted position. The exterior assembly includes a locking assembly configured to be mechanically coupled with the latch assembly. The interior assembly includes an interior wireless communication unit and the exterior assembly includes an exterior wireless communication unit that is configured to wirelessly communicate therebetween. In some embodiments, an exterior assembly includes a photovoltaic cell and the interior assembly includes a light source. The light source and the solar cell are configured for wirelessly communicating and for power transmission between the exterior and interior assemblies through a bore hole in the door.

Disclosed herein is a shipping container that includes numerous multi-factor authentication (MFA) tie ins to provide added security to the container. In some embodiments, the shipping container is associated with a mobile user profiles within a mobile application. A retailer makes a sale, then, using a mobile application, associates the container with the destination address and the MFA details associated with the buyer's mobile application account. Once the container is loaded up, the container will not open again except for the buyer using the buyer's MFA authentication credentials.

The invention provides a digital lock (100, 1001, 1002) including at least two magnets. One magnet is a semi hard magnet (310) and the other magnet is a hard magnet (320). The hard magnet (320) is configured to open or close the digital lock (100, 1001, 1002). The semi hard magnet (310) and the hard magnet (320) are placed adjacent to each other. A change in magnetisation polarisation of the semi hard magnet (310) is configured to push or pull the hard magnet (320) to open or close the digital lock (100, 1001, 1002).

The present disclosure relates to a bi-directional overrunning clutch, electronic door locks having bi-directional overrunning clutches, and methods of using the same. In certain embodiments, the electronic door lock includes a first locking mechanism for driving an inner wheel through a first torque to rotate a rotatable shaft to operate a locking device on a door by a user from outside, a second locking mechanism for driving inner wheel through the first torque to operate the locking device from an inside, a third locking mechanism for driving an outer wheel rotatable coaxially around the rotatable shaft through a second torque to operate the locking device electronically, and the bi-directional overrunning clutch. When outer wheel rotates at second torque, inner wheel and rotatable shaft rotate along with outer wheel, and when inner wheel rotates at first torque, outer wheel does not rotate along with inner wheel and rotatable shaft.

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 method of operating a door system includes receiving a signal from a pressure sensor disposed in a sill or a frame of the door system, authenticating the user after receiving the signal, shifting the lock from a locked configured to an unlocked configuration in response to receiving the signal after authenticating the user, and moving the door panel from a closed position to an ajar position in response to receiving the signal.

A magnetic lock assembly for a door includes a metal housing containing therein a magnet and a coil selectively energized to lock or unlock the door against an external armature plate. The magnetic lock further includes an audible alarm, a printed circuit board secured to an exterior surface of the metal housing and a cover made from a material that permits electromagnetic radiation to pass therethrough and positioned around the printed circuit board. The printed circuit board includes an electronic controller and a wireless communications interface configured to communicate wirelessly to a remote external system a signal indicating any one or more door conditions. These include propped door, delayed egress, forced door, insufficient bond, and door status indicating an open or closed status of the door.