A modular platform system includes a plurality of tiles, legs, beams, and brackets. Peripheries of the tiles and top surfaces of the beams are configured so that the tiles can snap on to the beams, allowing for easy creation of a platform. The beams, legs, and brackets are all configured so that the beams and legs are easily connected together for platform system creation.

WELDED BOARD AND ELECTRICAL CABINET STRUCTURE presents a cabinet built with welded frames that use vertical and horizontal profiles, having an internal fastening wall with holes and cutouts to the fitting of a cage nut and an internal fastening tab, a side sealing surface, a front sealing surface and the isolation barrier, the structure being assembled with at least two welded frames, which are assembled in parallel and joined through four depth profiles, said depth profiles being joined directly to the welded frames vertices.

An apparatus and method are provided for assembling a roof or floor of a cargo body, and for securing doors and other portions of a cargo body in place. In some cases, a plurality of sidewalls are provided, each comprising a side panel and an upper rail and/or lower rail coupled to the side panel. A roof panel can be located above the plurality of sidewalls adjacent the upper rails, with a roof bow extending between the upper rails below the roof panel and fixed to a track of one of the upper rails with a fastener. A floor cross member can be located between the lower rails, and can be secured to the lower rails via a track and fastener.

The invention relates in particular to a nut 1 for a clamping mechanism 10, a clamping mechanism 10 comprising a tie bolt 11 and two nuts 1, a vulcanizing press 20 comprising clamping mechanisms 10 and a support device 23.

A connecting joint for adjustably connecting at least two components of a laboratory automation system is disclosed. The connecting joint comprises a horizontal bearing unit connectable to a first component of the at least two components of the laboratory automation system; a vertical bearing unit connectable to a second component of the at least two components of the laboratory automation system; and a slider bar connecting the horizontal bearing unit with the vertical bearing unit, wherein the slider bar is movably mounted along a vertical axis within the vertical bearing unit; and wherein the slider bar is adjustably mounted in the horizontal bearing unit, wherein the slider bar is adjustable in at least one dimension essentially perpendicular to the vertical axis by the horizontal bearing unit.

A body frame joint and a vehicle having the same are provided. The body frame joint includes: a first sub-joint; and a second sub-joint. The first sub-joint and the second sub-joint are adapted to be mounted to a body frame. A transverse beam connection groove and a longitudinal beam connection groove are defined by engaging the first sub-joint and the second sub-joint. The transverse beam connection groove is adapted to accommodate a transverse beam of the body frame, and the longitudinal beam connection groove is adapted to accommodate a longitudinal beam of the body frame.

A body frame and a vehicle having the same are provided. The body frame includes: a transverse beam, provided with a transverse sliding groove; a longitudinal beam, connected with the transverse beam and provided with a longitudinal sliding groove; and a joint, disposed at a junction of the transverse beam and the longitudinal beam and mounted to the transverse beam by a transverse rivet and to the longitudinal beam by a longitudinal rivet. The transverse rivet is slidably mated with the transverse sliding groove, and the longitudinal rivet is slidably mated with the longitudinal sliding groove.

In an electrically adjustable steering of the present embodiment, a first telescopic actuator is disposed between a top bracket or a mount bracket on a vehicle body side and a steering jacket. The steering jacket includes a plurality of jacket members that overlap each other so as to be able to expand and contract in an axial direction. A motor of the first telescopic actuator is fixed to the top bracket or the mount bracket on the vehicle body side.

A wall anchor (1), having an anchor plate (2) with a front face (3) and a rear face (4), a fixing portion (5) which protrudes from the front face (4) of the anchor plate (2), which extends along a centre axis (M) and has a threaded structure (6) for receiving an anchor bolt (7), and two hooks (8, 9) which protrude from the rear face (4) of the anchor plate (2). The hooks (8, 9) are configured such that the wall anchor (1) can be fixedly connected to a profile rail (18) by protrusions (21) of a profile rail (18), with respect to forces acting in the direction of the centre axis (M).

Assembly for Clamping and Grounding Objects In various representative aspects, an apparatus for clamping and grounding solar panel frames to a mounting rail is disclosed herein. The apparatus comprises a fastener with an enlarged end, and a shank, with the enlarged end having one or more sharp protrusions that resemble teeth, and a washer with one or more sharp protrusions, and an opening. When installed, the shank is inserted through the opening of the washer, the sharp protrusions of the enlarged end penetrate either the lower or upper surface of the mounting rail and the sharp protrusions of the washer penetrate the other surface of the solar panel frames while at the same time creating a grounding path through the apparatus.