An adjustable buckle lock has a hook unit, a fixing unit, a wrench unit, an adjustment assembly, and a buckling ring unit. The hook unit can be securely mounted on a first locked object, and the fixing unit can be securely mounted on a second locked object. A pivotal end of the wrench unit is pivotally mounted on the fixing unit. The adjustment assembly is mounted on the wrench unit, and the buckling ring unit is pivotally mounted on the adjustment assembly and selectively hooks on the hook unit. With the moving of the buckling ring unit controlled by the adjustment assembly, the distance between the buckling ring unit and the hook unit is changed, and thus the pulling force for the buckling ring unit hooking on the buckling ring unit is adjusted, which ensures the first locked object and the second locked object are sealed together by a suitable force.

A latch for releasably connecting two elements is operable between engaged and released positions. An elongate handle opens and closes a latch mechanism about a first axis of rotation at the rear end of the handle. The latch handle is held closed only when the latch mechanism is in the engaged position and is lockable in the closed position by a manually operable handle catch. The front end of a handle cover is rotatably connected to the front end of the handle. The cover has a cover catch on the rear end, which is engagable with the latch mechanism to hold the cover closed. The cover is substantially coextensive with and in abutment with the handle. When the latch is mounted overhead and is open, the handle extends downward by the force of gravity and the cover extends downward away from the handle. In this configuration, the open latch is highly visible.

A mechanism for adjusting the distance and relative horizontal level between a storage box lid and the product storage box body includes a rod, a first adjustment member, and a second adjustment member. The rod is positioned on the edge of the box and is axially movable. The first and second adjustment members on the rod can be repositioned along the length direction of the rod to increase or decrease the distance between the lid and the box body to accommodate different thicknesses of seals between the two, and for achieving integrity in a horizontal level. A product storage box is also disclosed.

The container (10) has a lid structure (18) comprising two lid panels (20f) and (20t). The first lid panel (20t) forms at least a part of the top wall (14). The second lid panel 20f forms at least part of one of the side walls (16d). When the container (10) is in the erected condition the lid structure (18) can have one of, and be moved between, a closed configuration; top load configuration; and, front load configuration. The front load configuration has two variants. In a first front load configuration the first and second lid panels (20t) and (20f) remain connected to each other and are moved so that they are in a substantial face to face relationship. In the second front load configuration the second lid panel (20f) is pivoted to lie on top of the first lid panel (20t).

The container (10) has a lid structure (18) comprising two lid panels (20f) and (20t). The first lid panel (20t) forms at least a part of the top wall (14). The second lid panel 20f forms at least part of one of the side walls (16d). When the container (10) is in the erected condition the lid structure (18) can have one of, and be moved between, a closed configuration; top load configuration; and, front load configuration. The front load configuration has two variants. In a first front load configuration the first and second lid panels (20t) and (20f) remain connected to each other and are moved so that they are in a substantial face to face relationship. In the second front load configuration the second lid panel (20f) is pivoted to lie on top of the first lid panel (20t).

The invention concerns a quick-action clamping apparatus (8, 108), in particular a one-hand quick-action clamping apparatus (8, 108), for clamping a first assembly (36, 136) of a pelletizing apparatus (2, 102) to a second assembly (38, 138) of the pelletizing apparatus (2, 102), in particular a pelletizer (4, 104) to a cutting chamber (6, 106). According to the invention there is proposed a mounting element (44, 144) which is arranged at the first assembly (36, 136) or the second assembly (38, 138), a locking element (40, 140) which is arranged at the other of the first assembly (36, 136) or the second assembly (38, 138), and a clamping means (10, 110) having a clamping element (32, 132), wherein the clamping element (32, 132) is mounted rotatably about an axis of rotation (D) to the mounting element (44, 144) and the clamping element (32, 132) is adapted to be pivoted into a clamping position (S) in which the clamping element (32, 132) is in engagement with the locking element (40, 140) and braces the first assembly (36, 136) against the second assembly (38, 138). The invention further concerns a pelletizing apparatus (8, 108) and a method of bracing a pelletizer (4, 104) to a cutting chamber (6, 106).

A container is disclosed that has a base and a lid that is rotatable about a hinge from a closed configuration to an open configuration. The lid may be secured to the base with a latch assembly. A latch assembly may have a locked position and an unlocked position, where the latch assembly includes: a latch body pivotally connected to the lid, a latch button slidably connected with the latch body, the latch button having a latch button-locking member, a latch-locking arm pivotally connected to the latch body, and a latch-locking arm biasing member that exerts a rotational force on the latch-locking arm. When the latch assembly is moved to the locked position, the latch-locking arm may engage the base and rotate against the rotational force from the latch-locking arm causing the latch button to move against the linear force until the latch button-locking member engages the arm-locking member.

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).

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).

Actuation assemblies for emergency devices (e.g., inflatable life rafts carried on-board an aircraft) are provided with enhanced (preferably multiple) levels of security to preclude inadvertent unlatching and/or deployment but also allow access to an on-board emergency device removably positioned within a device bay of the vehicle which is normally covered by an access panel. The actuation assembly may be provided with a rotatable actuation shaft, a manually operated actuation lever fixed to the actuation shaft so as to rotate the actuation shaft in response to movement of the actuation lever between stowed and deployed conditions thereof, and a safety locking system operably connected to the rotatable shaft and having a locked condition which prevents operation of the actuation lever to thereby maintain the actuation assembly in a safe mode during normal vehicle operation, and an armed mode which allows the actuation lever to be moved into the deployed condition thereof.