A dual hasp conventional trailer door lock has a lever arm that is secured between a fixed lower hasp and a swivel upper hasp so as to align an upper hasp hole with a lower hasp hole. The present invention has an elongate body that rests against the door to cover the two hasps. A lockable pin is manually pushed through the holes from a key end to an anchor end of the lock body. An electronic motion sensor is housed in a hollow in the body. Any tampering of the body triggers any one of an alarm sound and/or phone transmission and/or flashing strobe light.

A lockout system includes a hasp assembly and a plurality of tags. The hasp assembly has a back plate defining slots each sized and shaped to receive a tag. The back plate and tags each have openings that align when a tag is received in a slot. A first hasp portion has a first loop portion and a second hasp portion has a second loop portion. The first and second hasp portions are rotatable with respect to one another such that moving the lockout system has both an unlocked position and a locked position associated with an open position and a closed position. In the closed position, the first and second hasp portions complete and define a closed loop, where one or more tags can be installed in slots preventing further movement from the closed position.

A lockout system includes a hasp assembly and a plurality of tags. The hasp assembly has a back plate defining slots each sized and shaped to receive a tag. The back plate and tags each have openings that align when a tag is received in a slot. A first hasp portion has a first loop portion and a second hasp portion has a second loop portion. The first and second hasp portions are rotatable with respect to one another such that moving the lockout system has both an unlocked position and a locked position associated with an open position and a closed position. In the closed position, the first and second hasp portions complete and define a closed loop, where one or more tags can be installed in slots preventing further movement from the closed position.

The disclosure generally relates to a system and method for managing distributed encrypted combination over-locks from a remote location. In an exemplary embodiment, the invention is a distributed management system for that controls access to various locations, such as, for example, self-storage units, hotel rooms, apartment buildings, storage containers, short-term housing rentals, lockers, equipment rooms, vaults, hospitals, airports, government facilities, nuclear power facilities, water treatment facilities, weapon storage facilities, aircraft cockpits, and any other setting that requires restricted, selective, or monitored access that can be remotely controlled.

The disclosure generally relates to a system and method for managing distributed encrypted combination over-locks from a remote location. In an exemplary embodiment, the invention is a distributed management system for that controls access to various locations, such as, for example, self-storage units, hotel rooms, apartment buildings, storage containers, short-term housing rentals, lockers, equipment rooms, vaults, hospitals, airports, government facilities, nuclear power facilities, water treatment facilities, weapon storage facilities, aircraft cockpits, and any other setting that requires restricted, selective, or monitored access that can be remotely controlled.

A theft deterrent system for an electronics cabinet may include a first hasp, which may include a plurality of studs extending from a surface thereof. At least one stud of the plurality of studs may be dimensioned to engage with a padlock ring of the electronics cabinet. The first hasp may have a tab having a shackle hole therein. The theft deterrent system may include a second hasp, which may include a plurality of holes dimensioned to receive a respective one of the plurality of studs. The second hasp may also have a tab having a shackle hole therein. The system may further include a shield retainer dimensioned to surround at least portions of the first hasp and the second hasp. To secure the electronics cabinet, a shackle of a hidden shackle lock may be fed through the shackle holes and the hidden shackle lock may then be locked.

A theft deterrent system for an electronics cabinet may include a first hasp, which may include a plurality of studs extending from a surface thereof. At least one stud of the plurality of studs may be dimensioned to engage with a padlock ring of the electronics cabinet. The first hasp may have a tab having a shackle hole therein. The theft deterrent system may include a second hasp, which may include a plurality of holes dimensioned to receive a respective one of the plurality of studs. The second hasp may also have a tab having a shackle hole therein. The system may further include a shield retainer dimensioned to surround at least portions of the first hasp and the second hasp. To secure the electronics cabinet, a shackle of a hidden shackle lock may be fed through the shackle holes and the hidden shackle lock may then be locked.

The disclosure generally relates to a system and method for randomly generating unlock codes and identifiers for locks, and creating unlock code and identifier pairs. In an exemplary embodiment, the invention is integrated with, or part of, a distributed management system that controls access to various locations, such as, for example, self-storage units, hotel rooms, apartment buildings, storage containers, short-term housing rentals, lockers, equipment rooms, vaults, hospitals, airports, government facilities, nuclear power facilities, water treatment facilities, weapon storage facilities, aircraft cockpits, and any other setting that requires restricted, selective, or monitored access that can be remotely, controlled, whereby users can receive unlock codes electronically on their mobile device.

The disclosure generally relates to a system and method for randomly generating unlock codes and identifiers for locks, and creating unlock code and identifier pairs. In an exemplary embodiment, the invention is integrated with, or part of, a distributed management system that controls access to various locations, such as, for example, self-storage units, hotel rooms, apartment buildings, storage containers, short-term housing rentals, lockers, equipment rooms, vaults, hospitals, airports, government facilities, nuclear power facilities, water treatment facilities, weapon storage facilities, aircraft cockpits, and any other setting that requires restricted, selective, or monitored access that can be remotely, controlled, whereby users can receive unlock codes electronically on their mobile device.

A locking mechanism includes a hasp having a tongue disposed along a first side of the hasp, and a captive latch pin protruding from the hasp disposed away from the tongue. The locking mechanism includes an actuator assembly with a captive latch and an actuator configured to manipulate the captive latch. The captive latch may receive the captive latch pin of the hasp. A body locking mechanism can obstruct access to at least a portion of the hasp and the actuator assembly, wherein the hasp may slidably move when the captive latch pin is not retained by the captive latch, and wherein a retention of the captive latch pin by the captive latch arrests the slidable movement of the hasp.