A lock includes an internal facing portion and an external facing portion, a lever assembly, a housing cover on the external facing portion of the lock including a lock assembly having a locked position and a unlocked position and a button cap. The button cap extends into a first groove of the housing cover and engages a silicon sleeve sealing the button cap and the housing cover. A housing includes a trigger button and an inner seal to engage a second groove sealing the housing and the housing cover, and an anchoring frame on the internal facing portion of the lock coupled to the housing. The trigger button extends through the anchoring frame, and the trigger button is accessible from the internal facing portion of the lock to releasably actuate the lock assembly.

A locking system for an enclosure, including a control bracket mounted to a door of the enclosure and configured to slide in a longitudinal direction along a guide rod running through a pin bracket of the control bracket. The control bracket further includes a latching pin to secure the door of the enclosure. A handle mechanism has a push rod that causes the control bracket to slide along the longitudinal direction, also causing the latching pin to move into a position that secures the door.

A latch is configured to fix a panel relative to a frame. The latch includes a housing having a longitudinal axis and defining an aperture along the longitudinal axis; a cap mounted within the aperture of the housing for rotation about the longitudinal axis, the cap comprising a drive surface; and a cover coupled to the housing to pivot about a lateral axis, the cover pivotable to be in a closed position in which the cover covers the cap; wherein when the cap is in an unlatched position, the drive surface of the cap is aligned with an engagement surface of the cover and positioned to block the cover from pivoting to the closed position; and wherein when the cap is in a latched position, the drive surface is unaligned with the engagement surface and positioned to permit the cover to pivot to the closed position.

An exemplary lockset includes a mortise case, a magnet assembly mounted in the mortise case, and a manual actuator operable to move the magnet assembly between a coupling position in which a first magnet of the magnet assembly is aligned with a reference point and a decoupling position in which the first magnet is misaligned with the reference point. In certain embodiments, the magnet assembly further includes a second magnet having an opposite polarity as the first magnet, and the second magnet is misaligned with the reference point when the magnet assembly is in the coupling position and is aligned with the reference point when the magnet assembly is in the decoupling position.

The invention relates to a plastic enclosure for enclosing industrial components. The enclosure comprises a case (2), a lid (9), and a latch device (13) for locking the lid to the case. The lid (9) has a grip means formed as a rigid lug (14) molded to be monolithic with the lid (9), the lug comprising a throughhole (19) to which a hook portion (17) of a rocker (15) can grip. The lug (14) is arranged, in the closed position of the lid, to extend over and at a distance from the second wall (7) to be substantially in parallel with a wall of the case to limit an intermediate space between the wall (7) and the lug (14) when the lid is in the closed position. The hook portion (17) is arranged so that, in the release position (II) of the rocker (15), it is turned inside the intermediate space away from the path of the lug (14) and, in the locking position (I) of the rocker, the hook portion is turned to protrude laterally outwards through the through-hole (19) of the lug (14) and to compress the sealing gasket (12) by pressing the sealing flange (8) against the sealing gasket (12) to create a spring force against which the hook portion holds the lug (14). The output force of the hook portion (17) exerted to the lug (14) is amplified by a mechanical advantage provided by a lever effect of the rocker (15) when being turned to the locking position by an input force exerted to the handle arm (18).

To provide improved sealing of slidable facade components, a hardware (10) for a slidable facade component is provided. The hardware comprises a guide pin arrangement (12) for the slidable facade component with at least two guide pins (18a) for a first side of the slidable facade component and at least two guide pins (18b) for a second side of the slidable facade component opposite the first side. Furthermore, an actuating rod arrangement (14) for transmitting an actuating force is provided with a first actuating rod (20a) for the first side of the slidable facade component and a second actuating rod (20b) for the second side of the slidable facade component. Further provided is an actuating device (16) coupled to the drive rod assembly for transmitting the actuating force to the first and second drive rods with an actuation. The guide pins are each designed as eccentric bearing pins (22) with an eccentrically arranged axis of rotation (24) for rotatable attachment to the slidable facade component and are provided for engagement with a guide groove arrangement (26) arranged in the frame area. The eccentric bearing pins are each coupled to one of the drive rods via a coupling element (28) and are rotatable via a longitudinal movement of the drive rods. With the eccentric bearing pins supported in the guide groove arrangement, the slidable facade component can be moved transversely to the guide direction in order to cause the slidable facade component to be pressed against a fixed frame region transversely to the guide direction.

A locking system for an enclosure, including a control bracket mounted to a door of the enclosure and configured to slide in a longitudinal direction along a guide rod running through a pin bracket of the control bracket. The control bracket further includes a latching pin to secure the door of the enclosure. A handle mechanism has a push rod that causes the control bracket to slide along the longitudinal direction, also causing the latching pin to move into a position that secures the door.

A compression latch assembly for latching a panel to a frame includes a housing assembly, a lockplug assembly, a handle actuator assembly, and a rotating pawl assembly. The housing assembly defines an exterior well and a first and second compartment. The lockplug assembly resides within the first compartment and includes a lockplug having a circumferential guide surface. The handle actuator assembly has a handle within the exterior well, a crank coupled to the handle, and a drive shaft coupled to the crank. The handle and the crank rotate about common pivot point within the second compartment. The handle is selectively captured and ejected by interaction between the circumferential guide surface and a locking pin on the handle. The rotating pawl assembly has a hook defining a slot that receives the drive shaft. Pivotal movement of the handle actuates the hook by movement of the drive shaft within the slot.

A door sealing system for a container having a container door is provided. The container can be part of a vacuum system, for example as mounted on a trailer. The sealing system is hydraulically actuated and includes a mechanical lock. A corresponding vacuum system and method of operation are also provided.

The present invention relates to a locking mechanism for arrangement on a door, the locking mechanism (1) comprising an actuator(10), arranged to be linearly movable along a first axis(Y). The locking mechanism further comprises a locking clamp (20) for engaging a locking element (50) on a door frame. The locking clamp (20) may be flexibly coupled to the actuator (10) so that, when the actuator (10) is moved along the first axis, the locking clamp (20) may move linearly along the first axis (Y) and rotate around a first rotational axis(A) to admit engagement to the locking element. The present invention further relates to a locking system (100) comprising such locking mechanism (1). Figure for publication: FIG. 5