The invention relates to a door assembly (1) comprising a door frame (4), a door leaf (6), and a locking system (21) having a door lock (22) and having a drive assembly (25) with an electrically driven drive unit (26) and with an electrical energy source (27). The door lock (22) has a lock case (23) and a locking and/or blocking mechanism (24). The electrically driven drive unit (26), as viewed in the direction of the door leaf thickness (16), is arranged laterally next to and either directly adjacent to the lock case (23) or in the region of a door leaf surface (14, 15) on the door leaf (6), and has a mechanical drive connection with the locking and/or blocking mechanism (24) of the door lock (22).

A wireless deadbolt door lock is an electric dock lock that can be powered and controlled through wireless means. This is accomplished using an electric deadbolt door lock body containing a Dual Position Latching Solenoid (DPLS) to move a deadbolt plunger in a reciprocating linear motion, between a withdrawn deadbolt position and a locking deadbolt position, protruding out from the electric deadbolt door lock body. The DPLS is controlled by an energy efficient bi-stable permanent magnet activation system (BSPMAS), which can be wirelessly controlled. A wireless charging station between the door frame and the door can be used to charge batteries or capacitors to power the BSPMAS. A mechanical release/locking device and electrical mechanical switches are also provided for unlocking or locking the deadbolt door lock when a wireless device is unavailable.

A non-contact transmission device for an electronic lock includes a housing. The housing has an accommodation trough to accommodate a retainer in a slidable manner. The retainer is provided with an RFID coil. An inner side of the housing is formed with a positioning trough. When the retainer is slid in the accommodation trough, the RFID coil is positioned in the positioning trough, such that the RFID coil is closer to the outer edge of the housing without lowering the strength of the housing. When two non-contact transmission devices are mounted to a door frame and a door panel respectively, the distance between the RFID coils of the two non-contact transmission devices can be shortened to improve the transmission efficiency between the RFID coils.

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.

A handle for a car door includes a near field communication unit having a microchip and an antenna. The antenna includes a coil and an elongated connection part configured to cooperate with the microchip, a body, an overmolded portion formed on the body and defining an encapsulating zone including an entirety of the coil and part of the elongated connection part. The elongated connection part includes a terminal portion including a cooperation extremity configured to cooperate with the microchip. The terminal portion is outside the encapsulated zone.

A system and method for a door system is disclosed. The system produces an inductive power transfer signal and modulates the inductive power transfer signal. The system also encodes data within the modulated inductive power transfer signal and transmits the signal at a door frame of a door. At the door, the system receives the modulated inductive power transfer signal and extracts data from the received signal, and transduces the received signal into a door power signal. The system also supports secure data transfer by encrypting the encoded data at the door frame and decrypting the extracted data at the door. As a result, the modulated inductive power transfer signal between the door frame and the door provides a secure wireless data transfer channel for configuring components at the door and/or displaying data at the door, while also providing power to components at the door.

A system and method for a door is disclosed. The system includes a frame magnetic lock assembly mounted to a door frame, and a door magnetic lock assembly mounted to a door for receiving inductively transferred power from the frame magnetic lock assembly. The door system also includes a door electronics subsystem mounted to the door that includes a power management system that provides power to the door from the inductively transferred power, and charges an energy storage element at the door from the inductively transferred power. The power management system provides power to the door from the energy storage element when the inductively transferred power is not available at the door, such as when the door is open, and resumes providing power to the door from the inductively transferred power once the inductively transferred power is restored. Once restored, some of the inductive power recharges the energy storage element.

Disclosed is a door lock charging apparatus for receiving power from an external power supply and generating an electromagnetic field for charging a door lock apparatus, the door lock charging apparatus including an electromagnetic field generator electrically connected to a power supply and configured to generate an electromagnetic field on the conductive surface using the power supply and a charger configured to propagate the generated electromagnetic field to a door lock apparatus attached to a second position on the conductive surface.

A lock mechanism for a door including a deadbolt configured to be positioned in an extended first position and a retracted second position. The lock mechanism further includes an actuator for moving the deadbolt between the first and second positions, and a rechargeable battery for powering the actuator. A receiving coil of the lock mechanism generates an induced current for charging the rechargeable battery. The receiving coil is configured to generate the induced current from an electromagnetic field generated by a transmitting coil facing the receiving coil and located on an interior surface of a door frame for the door.