A storage system, the system is disclosed having a base; a slot in the base; a spline that slides along the base; a plurality of latches in the spline; a plurality of shelves snapped into the plurality of latches; a cam attached to a bottom of the spline, wherein the cam is slidably inserted into the slot in the base and guides spline along a path along the base.

A storage system, the system is disclosed having a base; a slot in the base; a spline that slides along the base; a plurality of latches in the spline; a plurality of shelves snapped into the plurality of latches; a cam attached to a bottom of the spline, wherein the cam is slidably inserted into the slot in the base and guides spline along a path along the base.

Example implementations relate to a computing system having a chassis and a front panel pivotably coupled to the chassis via a pair of retention brackets. In some examples, the chassis has a pair of frames that is disposed spaced apart and in parallel to each other. Further, each retention bracket of the pair of brackets is movably coupled to a respective frame of the pair of frames. The front panel is releasably engaged to the pair of frames and pivotably coupled to the pair of retention brackets such that the front panel is movable independently relative to the chassis. During installation and maintenance of the computing system, the front panel is movable linearly along a radial direction relative to the pair of frames and rotatable independently relative to the pair of retention brackets so as to provide clearance for accessing interiors of the chassis.

Example implementations relate to a computing system having a chassis and a front panel pivotably coupled to the chassis via a pair of retention brackets. In some examples, the chassis has a pair of frames that is disposed spaced apart and in parallel to each other. Further, each retention bracket of the pair of brackets is movably coupled to a respective frame of the pair of frames. The front panel is releasably engaged to the pair of frames and pivotably coupled to the pair of retention brackets such that the front panel is movable independently relative to the chassis. During installation and maintenance of the computing system, the front panel is movable linearly along a radial direction relative to the pair of frames and rotatable independently relative to the pair of retention brackets so as to provide clearance for accessing interiors of the chassis.

The present invention relates to a linear motion guide unit manufactured at low cost by forming at least a slider from a single metal plate, and reduced in sliding resistance of rolling elements as well as a method of manufacturing the same. The linear motion guide unit includes a guide rail, and the slider formed from a single metal plate. The guide rail has a bottom part, and a pair of longitudinal side parts standing from opposite sides of the bottom part, extending longitudinally in a mutually facing manner, and having respective raceway grooves in which the rolling elements roll. The slider includes an upper part, a pair of mutually facing sleeve parts extending downward from opposite sides of the upper part and having respective raceway grooves and return passages, and end cap parts formed respectively at opposite ends of the upper part and having turnaround grooves.

A shelf assembly (1) for products comprising a shelving section (5) with at least one shelf (6), which is rotatable about an axis of rotation (13) between a display position, in which the shelf is accessible from the front (7) of the shelving section, and a refill position, in which the shelf is accessible from the rear (8) of the shelving section. The shelf assembly further comprises a support (9), which has a sledge (10) rotatably supporting the shelving section and being movable in a forward-rearward direction. When the shelving section is rotated from the display position to the refill position, the sledge is first moved forwards, and then rearwards back to its starting position. The shelving section further comprises a frame (16) having opposite first and second side posts (17, 18), wherein the shelf is mounted between the side posts at art arbitrary height. The shelf is provided with a respective clamping portion at opposite ends of the shelf, fixing the shelf at the side posts. Each clamping portion comprises a hook portion engaged with a respective side post at a first surface thereof, and a tightening portion engaged with an opposite second surface of the side post, wherein the tightening portion is untightenable for arbitrary height movement of the shelf.

A slide unit includes a fixed rail fixed to a main body, and provided with a first accommodation space, a movable rail connected to a drawer body to allow the drawer body to be pulled out from and pushed into the main body, provided with a second accommodation space, and configured to be movable with respect to the fixed rail, an inner rail configured such that a first end thereof is inserted in the first accommodation space and a second end thereof is inserted in the second accommodation space, so as to allow the movable rail to be slidable with respect to the fixed rail, and a plurality of slide balls inserted in the first accommodation space to be disposed between the fixed rail and the inner rail, and inserted in the second accommodation space to be disposed between the movable rail and the inner rail.

A slide rail mechanism includes a rail member, a supporting member, a first bracket and a fastening member. The rail member includes an upper wall, a lower wall and a longitudinal wall connected between the upper wall and the lower wall. The supporting member and the rail member are capable of moving relative to each other along a longitudinal direction. The supporting member includes an upper supporting portion, a lower supporting portion and a longitudinal portion connected between the upper supporting portion and the lower supporting portion. The first bracket and the supporting member are capable of moving relative to each other along the longitudinal direction. The fastening member is capable of in one of a first state and a second state relative to the first bracket.

A slide rail mechanism includes a rail member, a supporting member, a first bracket and a fastening member. The rail member includes an upper wall, a lower wall and a longitudinal wall connected between the upper wall and the lower wall. The supporting member and the rail member are capable of moving relative to each other along a longitudinal direction. The supporting member includes an upper supporting portion, a lower supporting portion and a longitudinal portion connected between the upper supporting portion and the lower supporting portion. The first bracket and the supporting member are capable of moving relative to each other along the longitudinal direction. The fastening member is capable of in one of a first state and a second state relative to the first bracket.

A slide rail mechanism includes a rail member, a supporting member, a first bracket and a fastening member. The rail member includes an upper wall, a lower wall and a longitudinal wall connected between the upper wall and the lower wall. The supporting member and the rail member are capable of moving relative to each other along a longitudinal direction. The supporting member includes an upper supporting portion, a lower supporting portion and a longitudinal portion connected between the upper supporting portion and the lower supporting portion. The first bracket and the supporting member are capable of moving relative to each other along the longitudinal direction. The fastening member is capable of in one of a first state and a second state relative to the first bracket.