A latch mechanism is provided having a housing, a cap, and at least one indicator. The housing may include a first top surface. The cap may include a second top surface and may be mounted for selective rotational movement relative to the housing between a latched position and an unlatched position. The at least one indicator may be interposed between the cap and the housing and mounted for axial movement relative to the cap. As the cap is rotated from the latched position to the unlatched position, at least a portion of the indicator is axially displaced to an extended position above at least one of the first and second top surfaces.

Technology is provided for a storage card adapter. The storage card adapter is used for housing storage cards (e.g., M.2 storage cards), and the storage card adapter can then be inserted into a drive bay. The storage card adapter includes a compression latch system that, when engaged, brings together the cover and carrier frame of the storage card adapter such that at least 100 lbs of compressive force is applied to thermal pads disposed on either side of storage cards housed within the storage card adapter. The compression latch system includes a cam into which a shaft of a compression latch is inserted. When a lever attached to one end of the shaft is pivoted about the shaft, a ramp on the opposite end of the shaft engages with an engagement ramp within the cam to thereby pull together the cover and carrier frame and provide the desired compressive force to the thermal pads. The storage card adapter also includes a spring latch that locks the lever of the compression latch into place when the compression latch is fully engaged with the cam.

A locking system includes a first wire, a first block, a locking core, and a cam. The first wire includes at least one positioning structure and the first block is attached to the first wire at a first positioning structure of the at least one positioning structure to prevent movement of the first block on the first wire. The locking core rotates between a locked position and an unlocked position, and the cam is secured to the locking core to move the first block between a first position that corresponds to the locked position and a second position that corresponds to the unlocked position.

A cam lock has a lock cylinder and a cam part connected to the lock cylinder. The cam part is turnable from a lock position to an open position when turning a key placed in the lock cylinder. The cam part comprises a spring and a flange that is arranged to receive external force towards the lock cylinder. The spring allows the movement of the cam part at the open position towards the lock cylinder as response to external force. The spring is further arranged to turn the cam part towards the lock position.

A dual-code lock core is provided, including a first unlocking component, a code wheel, and a second unlocking component. When the code wheel rotates to a first unlocking position, the first unlocking component may move to unlock the dual-code lock core; and when the code wheel rotates to a second unlocking position, the second unlocking component may move to unlock the dual-code lock core.

A latch (10) is usable to selectively hold a closure member such as a door (188) in a closed position. The latch includes a body (12) which has a manually engageable handle (18) on a front side thereof. A shank (30) is in rotationally movable connection with the handle. The shank extends through the body and into an indexing cam bore (58) on the back side of the body. The shank is both axially and rotationally movable about a cam bore axis (62). An indexing cam (88) is connected to the shank. The shank is in operative connection with a striker (102). The striker is rotationally movable responsive to rotation of the handle between a latched position and unlatched position when the shank is in a second axial position. When the shank is in a first axial position, the shank is held in a fixed rotational position by the indexing cam, and the striker is held in the latched position. A cam bolt (164) is movably engageable with the striker to hold the striker in the latched position. The cam bolt is in operative connection with a lock cylinder (142). The lock cylinder is rotatable in engagement with a correct key to selectively position the cam bolt.

A ticket dispensing module comprising an elongate ticket dispensing aperture provided within a face of the ticket dispensing module, the elongate ticket dispensing aperture being a hole elongate in a plane parallel to the face when a door of the ticket dispensing module closed; and a housing body having opposed first and second faces with complementary slideable engagement elements, the first slideable engagement element of a first housing body engageable with the second slideable engagement element of a corresponding, second housing body, by relative displacement of the housing bodies along a direction of elongation of their slideable engagement elements, wherein at least one of the slideable engagement elements is tapered along its direction of elongation, wherein the slideable engagement elements of the first and second faces of the housing bodies are configured to prevent separation of the housing bodies transverse to the direction of relative displacement when they are engaged.

A lock device comprising: a lock frame defining a cavity and having at least one frame recess; a lock body having a key-receiving face and defining a chamber and the longitudinal wall comprising at least one aperture therethrough emerging in the chamber, each one of the at least one aperture facing a respective one of the at least one frame recess, the lock body being moveable within the cavity of the lock frame; a translation pin movably inserted within the chamber; an active pin positioned within an aperture of the lock body and movable between an insertion position and a retracted position; a moveable magnetic body positioned within the chamber to sequentially prevent and allow motion of the translation pin; and an actuator body movable between a locked position and an unlocked position.

An ejector lever includes a lever body and an unlocking mechanism, where the unlocking mechanism includes an unlocking hook and a safety latch, the unlocking hook is rotatably connected to the lever body using a first rotating shaft, and the safety latch is rotatably connected to the lever body using a second rotating shaft. The unlocking hook is provided with a first end and a second end, the first end is opposite to the second end across the first rotating shaft, the first end is provided with a hook, the second end is provided with a first abutting part, the safety latch is provided with a second abutting part, and the first abutting part is in contact with the second abutting part; and the second abutting part is configured to apply first force on the first abutting part when the safety latch rotates around the second rotating shaft.

Locks for storage containers having closures such as doors, covers or lids are disclosed. The lock is mounted to the closure and is latched in such a manner as to selectively prevent opening or removal of the closure. The latch of the lock can engage a slot in the storage container, a bracket on the storage container, or a strike on the storage container. Alternatively, the latch can engage a mounting bracket on the door or other portion of the door to selectively block movement of a handle for the door. Further, the latch can have a locking device which can selectively block movement of the latch. Movement of the locking device can be selectively controlled by a magnetic key.