Electromechanical lock utilizing magnetic field forces. An actuator is moved between a locked position and an unlocked position. In the locked position, a first permanent magnet directs a first magnetic field exerting a pushing force so that rotation of the first axle is blocked, and a second permanent magnet directs a second magnetic field exerting a pulling force so that the first axle is kept uncoupled with the second axle. In the unlocked position, the first permanent magnet directs a reversed first magnetic field exerting a pulling force so that the first axle is released to rotate, and the second permanent magnet directs a reversed second magnetic field exerting a pushing force so that the first axle becomes coupled with the second axle.

An electromagnetic opening device comprises a housing, a fixed iron core, a movable iron core having a bottom end engaging with the fixed iron core, a shaft sleeve that sleeves a top end of the movable iron core and extends outside of the housing, and an electromagnetic coil, and a vibration sensing mechanism comprising a sensing block having a rotation shaft, a stopping end and a balancing end located on two sides of the movable iron core. A bottom of the stopping end is rotationally connected onto the housing through the rotation shaft. When the sensing block compresses a balance spring disposed between the balancing end and the housing through the rotation of the rotation shaft, the stopping end abuts against the shaft sleeve. The vibration sensing mechanism effectively prevents a mistaken shrinkage of the shaft sleeve of the movable iron core and abnormally opening of a safe deposit box.

A multimode electronic lock is disclosed. The lock has three mechanical flag members which move so as to break light beams and detect the position of the flag members, sending a signal to an electronic lock controller. This allows the electronic lock controller to accurately and reliably determine whether the lock is in a locked or unlocked state, regardless of whether an electronic lock/unlock command or a mechanical key and tumbler mechanism was last used to lock or unlock it. Optional features which allow the locking assembly to be secured from transient accelerations/impacts and to move in highly consistent and controllable ways are also disclosed. The electronic lock controller can accept lock/unlock commands from a smartphone or other pairable device, and can lock or unlock the lock according to preprogrammed schedules and/or proximity of the paired device.

Electromechanical lock utilizing magnetic field forces. An actuator is moved between a locked position and an unlocked position. In the locked position, a first permanent magnet directs a first magnetic field exerting a pushing force so that rotation of the first axle is blocked, and a second permanent magnet directs a second magnetic field exerting a pulling force so that the first axle is kept uncoupled with the second axle. In the unlocked position, the first permanent magnet directs a reversed first magnetic field exerting a pulling force so that the first axle is released to rotate, and the second permanent magnet directs a reversed second magnetic field exerting a pushing force so that the first axle becomes coupled with the second axle.

A security door system includes a door jamb, a door, and a deadbolt mechanism. The door jamb includes a soffit and an aperture defined in the soffit. The deadbolt mechanism is mounted to a surface of the door and out of a plane of the door such that a deadbolt of the deadbolt mechanism is operable to project into the aperture in a locked position. In various implementations, the deadbolt mechanism may be mounted to the surface of the door by attachment members such as bolts that extend through attachment member apertures in the door. Shock absorbent material may be variously positioned around the attachment members in the attachment member apertures and may absorb at least some shock from a force applied to the deadbolt mechanism.

A tamper resistant lock. A lock has a lock housing with housing indentation. A cylinder is rotatably housed within the housing. A locking pin is connected to the cylinder and is inserted into the housing indentation when the lock is in a locked position and the locking pin is clear of the housing indentation when the lock is in an unlocked position. An anti-tampering mechanism is positioned between the housing and the cylinder. The anti-tampering mechanism receives a user's key and also includes a relative motion hole. A key extension portion is rotatably inserted inside the anti-tampering mechanism body and includes a relative motion indentation. The key extension portion is keyed to the cylinder. A lock ball is inserted into the relative motion hole and the relative motion indention, thereby preventing relative motion between the anti-tampering mechanism body and the key extension portion. A flexible band is wrapped around the anti-tampering mechanism body and covers the lock ball and holds the lock ball in place in the relative motion hole and relative motion indentation. The flexibility of the flexible band is sufficient to permit the lock ball to leave the relative motion indentation while simultaneously retaining the lock ball in the relative motion hole if the anti-tampering mechanism body is rotated while the locking pin is inserted into the housing indentation, thereby permitting relative motion between the anti-tampering mechanism body and the key extension portion. In a preferred embodiment the tamper resistant lock is a padlock.

An appliance latch for latching an appliance door to an appliance cabinet that includes a housing and a lock bolt positioned to move linearly within the housing between a locked state and an unlocked state. A solenoid is positioned within the housing and includes an integrated magnetic lock, distinct from the lock bolt, to prevent undesired movement from the locked state to the unlocked state and movement from the unlocked state to the locked state.

In one embodiment, a security device includes a housing; a locking mechanism configured to alternate between a locked state and an unlocked state; a release member configured to alternate between a blocked position and a release position, wherein in the blocked position the release member blocks the locking mechanism from entering the unlocked state; and in the release position the release member allows the locking mechanism to enter the unlocked state; and an electronic article surveillance (EAS) component in a cavity of the housing.

A lock mechanism for a motor vehicle ignition switch includes a housing defining a barrel and a locking cylinder fitted for rotation in the barrel. A cap is fitted over one end of the housing capturing a frangible lock insert between the housing and cap. The frangible lock insert includes an electrically conductive pathway between radially displaced connection points on the rim of the insert. A circuit includes the electrically conductive pathway which is interrupted by disintegration of the frangible lock insert. Such disintegration occurs upon efforts to tamper with the lock mechanism or application of brute force to the sensor.

An electronic lockbox uses a rotary actuator with multiple positions to achieve multiple locking states. Multiple positions of the actuator are detected, using optical sensors. The locking mechanism includes an outer sleeve and an inner cylindrical barrel that are coupled with torsion springs. The lockbox has a shackle and a key bin that are retained by the inner barrel when in the locked state, and the barrel can be rotated to either release the shackle or to release the key bin that typically holds a building's key.