A magnetic door lock control system for use with an egress handle system and a door is provided. The magnetic door lock control system employs magnets that communicate with one another across the door jamb thereby eliminating the need for a hard wired electrical connection between the egress handle system (e.g., a mechanical switch bar) configured with a door and a door locking mechanism mounted above the door in the header of the entranceway. In this way, the need for an electrical wire loop between the egress handles and the door locking mechanism is eliminated.

One or more embodiments describe a magnetic actuator including at least two magnets. One magnet is a semi hard magnet and the other magnet is a hard magnet. The hard magnet is configured to open or close the magnetic actuator. The semi hard magnet and the hard magnet are placed adjacent to each other. A change in magnetization polarization of the semi hard magnet is configured to push or pull the hard magnet) to open or close a digital lock realised with the magnetic actuator. The magnetic actuator can also be used to realise a valve.

The disclosed computer-implemented method may include a magnetic insertable lock component with a magnet-sensing lock housing. By using a magnet within a pin and a magnetic field sensor within the lock housing, the apparatus may accurately detect the state of the lock. In some embodiments, the apparatus may determine the pin is inserted fully into the lock, the pin is inserted partially into the lock, the pin is not inserted in the lock, and/or that a foreign object that is not the pin is inserted into the lock. By using a magnet within the pin to track the state of the lock, the apparatus may improve both the user experience and the security of the lock. Various other methods, systems, and computer-readable media are also disclosed.

An improved method and system for providing a magnetic closure system for an electronic device (100) may include a first portion (130), a second portion (150), a connecting element (145) pivotally connecting the first portion to the second portion and configured to enable the electronic device to fold between a closed position and an open position, and a magnetic element (160, 165) for providing a closure force to bias the electronic device in the closed position. The magnetic element may include a first magnet pair and a second magnet pair, each of the first magnet pair and second magnet pair including a first magnet housed within the first portion and a second magnet housed within the second portion. The first magnet pair may provide an attractive magnetic force that biases the electronic device in the closed position, while the second magnet pair may provide a repelling magnetic force that partially counteracts the biasing from the attractive magnetic force as a gap between the first portion and the second portion decreases, and a pole size of the second magnet pair is smaller than a pole size of the first magnet pair.

The present invention relates to a locking garbage can device primarily comprised of a garbage can body with at least one actuator catch, a lid comprised of at least one rod with at least one actuator magnet, and a housing with at least one housing magnet. The lid is comprised of a magnetic locking mechanism that repels the actuator magnet of the rod via like-poled magnetic fields into a catch located in the garbage can body such that the lid cannot be removed from the body. By turning the housing, the housing spins such that a magnet with an opposite polarity of the actuator magnet of the rod attracts the rod toward the housing such that it disengages the catch and the lid can be lifted from the body.

A cabinet lock includes a latch configured to translate between extended and retracted positions and a lever configured to rotate between engaged and disengaged positions. The latch may be coupled to the lever with a pin in a corresponding slot. When the lever is in the disengaged position the latch may be in the extended position and when the lever is in the engaged position the latch may be in the retracted position. The lever includes a ferromagnetic portion responsive to a magnet within a threshold distance, where the presence of the magnet moves the lever to the engaged position.

A lock mechanism for interengaging two relatively movable components includes a bolt mounted within a first component and interengageable with a second component when the first and second components are in a predetermined position relative to each other and the bolt is extended. A magnetically-releasable latch mechanism is positioned to latch the bolt in a retracted position and is mounted for movement between a biased latch engaging position and a latch releasing position in a non-common direction of movement of the bolt. A first magnet is disposed within a trigger being translatable along an axis parallel to a longitudinal axis of the bolt and a second magnet is positioned to displace the latch mechanism to the latch releasing position as the trigger is caused to translate vertically when the first component is in the predetermined position relative to the second component to permit displacement of the bolt to the extended position.

A computing device is described. The computing device includes a first portion with a protrusion and a second portion separably connected to the first portion. The second portion has a receptacle. An undocking assist mechanism is configured to separate the first portion from the second portion when the protrusion is at least partially inserted into the receptacle. An actuator is configured to actuate the undocking assist mechanism. Methods of use are also described.

The present invention describes a means for unlocking and/or locking a privacy lockset via a magnet that is affected by a ferrous metal object or another magnet and, a means whereby said magnet travels in a controlled motion when affected by a ferrous metal object or said other magnet. As well as a trigger to secure or release a lock and a means whereby the motion of said magnet moves said trigger, whereby a magnet or ferrous metal object can be used to unlock or lock a privacy lockset. Rotational, lateral, and/or thrust forces are configured to move the trigger. The present invention may apply to rim locks, mortise locks, sliding door locks, cam locks, cylinder locks, and non-keyed deadbolts. Various materials or door styles may be provided.

An electronic lock device according to one embodiment includes a first magnetometer, a second magnetometer, a dynamic ferromagnetic component positioned between the first magnetometer and the second magnetometer, a processor, and a memory comprising a plurality of instructions stored thereon that, in response to execution by the processor, causes the electronic lock device to read sensor data from the first magnetometer and the second magnetometer, modify the sensor data to generate compensated sensor data that compensates for magnetic noise generated by the dynamic ferromagnetic component, and determine whether the door is in a closed state or an open state based on the compensated sensor data.