An electronic lock with 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 move the bolt between the extended position and the retracted position. The exterior assembly includes a touch keypad subassembly configured to detect touches to at least a portion of its surface. The touch keypad subassembly defines an opening through which a wiring harness extends. The opening in the touch keypad subassembly is sealed, at least in part, by an epoxy resin and/or internal structure of the touch keypad subassembly.

A secure sterilization system comprises at least a plurality of sterilization compartments contained within a device, and a control system for granting individual users access to unique ones of the secure compartments. The plurality of sterilization compartments include circuitry and components that include UV-C LEDs and UV-C photodetectors. In some embodiments, a plurality of walls within the sterilization compartment include circuitry and components that include UV-C LEDs and UV-C photodetectors. In some embodiments, a plurality of walls within a sterilization compartment include sensor components for presence/absence detection of assets within a compartment. Administrator-controlled versions of a secure sterilization system include access drawers with multiple sterilization compartments.

A key, a lock core and a lock, relating to a key, a lock core and a lock are provided. The key includes: a column body, a first end of the column body being provided with a light emitting component; a first cathode component disposed on the column body and connected to one end of the light emitting component to be mated with a second cathode component in the lock core; a first piezoelectric electrode disposed on the column body and connected to the other end of the light emitting component to be pressed against a second piezoelectric electrode in the lock core. When the first cathode component is mated with the second cathode component in the lock core, and the first piezoelectric electrode is pressed against the second piezoelectric electrode in the lock core, a piezoelectric current is generated, to cause the light emitting component to emit light.

A portable information handling system main housing portion has a transparent cover removeably coupled at an upper surface and sealed with an inflatable seal to aid desired cooling airflow. A pump fills the inflatable seal after the transparent cover closes over the housing and deflates the inflatable seal before release of the transparent cover to an open position. In one embodiment, the transparent cover integrates a liquid crystal display that presents operating condition of processing components visible within the housing through the transparent cover.

A method of operating a door system includes sensing a user on an exterior side of a door panel in physical propinquity to the lock such that the lock transitions from a sleep state to an active state, authenticating the user when the lock is in the active state before converting the lock from a locked configuration to an unlocked configuration, and converting the lock from the locked configuration to the unlocked configuration in response to transition to the active state. Authenticating the user includes receiving an authentication signal from a remote device on the user in physical propinquity to the to the lock.

A system for sensing a position of a locking bolt of an industrial locking switch includes an inductive circuit, a converter, and a master controller. The inductive circuit includes an inductive coil and a capacitor electrically connected in parallel. The inductive coil is positioned to receive a locking bolt of an industrial locking switch when the locking bolt is transitioned to a lock position. The converter is configured to convert a frequency of a current signal on the inductive circuit to a digital frequency value. The master controller is configured to generate a bolt detection signal in response to determining that the digital frequency value changes by an amount equal to or substantially equal to a defined frequency shift corresponding to a frequency shift induced by the inductive coil in response to presence of the locking bolt within the inductive coil's magnetic field.

An adaptive electric dual-controlled intelligent lock includes a mechanical clutching structure and an intelligent electronic control structure. The mechanical clutching structure includes a lock head, a lock cylinder and a lock tongue, wherein: the lock cylinder includes movable buckles, springs and a bearing. After being inserted into the keyhole of the lock head and then into the locked groove, a key is turned, the movable buckles move in an elastic range of the springs and drive the lock tongue connected with the bearing to swing, thereby realizing a mechanical unlocking process. The intelligent electronic control structure includes a PCB (printed circuit board), a motor and a shifting lever, wherein: a wireless control module is connected with an external mobile intelligent device; after the motor is started, the shifting lever pushes the movable buckles, so that the bearing drives the lock tongue to swing, thereby achieving an intelligent unlocking process.

A method of controlling a lock mechanism of an active door includes transiting an access controller of the lock mechanism to an authorized access mode and transitioning the access controller from the authorized access mode to an entry mode. Transitioning the access controller to the authorized access mode is in response to an authorized user being sensed approaching the active door from an exterior side of the active door or in response to input on a remote device. In the authorized access mode, an exterior handle of the active door is decoupled from a main latch of the lock mechanism. Transitioning the access controller to the entry mode is in response to sensed contact with the exterior handle. In the entry mode, the exterior handle is capable of rotating to transition the access controller to an unlocked mode in which the exterior handle is operably coupled to the main latch.

A method of operating a door system includes sensing a user on an exterior side of a door panel in physical propinquity to the lock such that the lock transitions from a sleep state to an active state, authenticating the user when the lock is in the active state before converting the lock from a locked configuration to an unlocked configuration, and converting the lock from the locked configuration to the unlocked configuration in response to transition to the active state. Authenticating the user includes receiving an authentication signal from a remote device on the user in physical propinquity to the to the lock.

A system described herein may provide for the dynamic and secure assignment of lockers that may be used when delivering goods in response to a fulfillment request. In some embodiments, smart tags may be used for packages provided in response to a fulfillment request. A smart locker system of some embodiments may include a set of lockers and one or more scanners that identify goods that have been delivered into a particular locker, such as by scanning smart tags placed on or in packages. The smart locker system may further receive a request from a User Equipment (“UE”), via a contactless tap, to provide the delivered goods, authenticate the UE, locate the particular locker in which the delivered goods are located, and unlock the locker.