A cabinet with a snap-in frame is described. The cabinet uses spring clips that engage the frame to an opening of the cabinet. The spring clips are fastened to outer edges around the opening of the cabinet. The frame is urged into the opening of the cabinet. The frame compresses the spring clips as the frame is pushed into the opening of the cabinet. End portions of the spring clips snap into recesses of an outer surface of the frame. The spring clips are easily aligned along the opening of the cabinet to ensure proper placement of the frame with respect to cabinet.

An aisle containment system is disclosed. The aisle containment system includes a frame defined by wall beams, header frames, and a plurality of posts secured to the wall beams and header frames. The header frames extend the width of the frame and the wall beams extend the length of the frame. A plurality of blanking panels extend from the floor to one of the wall beams. The plurality of blanking panels have a top, a bottom, a first side and a second side. Vertical stiffeners are positioned along at least one of the first side and the second side of each blanking panel. The blanking panels overlap adjacent blanking panels along the length of the frame. The blanking panels are laterally adjusted to fill openings in the aisle containment system.

An aisle containment system is disclosed. The aisle containment system includes a frame defined by wall beams, header frames, and a plurality of posts secured to the wall beams and header frames. The header frames extend the width of the frame and the wall beams extend the length of the frame. A plurality of blanking panels extend from the floor to one of the wall beams. The plurality of blanking panels have a top, a bottom, a first side and a second side. Vertical stiffeners are positioned along at least one of the first side and the second side of each blanking panel. The blanking panels overlap adjacent blanking panels along the length of the frame. The blanking panels are laterally adjusted to fill openings in the aisle containment system.

A rack assembly having two side racks, two rails, and at least one sub-rack, wherein the rails are mounted between the side racks and include a front rail and a rear rail lower than the front rail. Each rail has an opening in a side of the rail, with the opening of the front rail defined in a bottom of the front rail and the opening of the rear rail defined in the rear rail at a side facing the front rail. The at least one sub-rack has a rack frame, a connection rod, and at least one supporting member and is slidable along the rails The rack frame has at least one front rod and at least one rear rod wherein each front rod has an extension rod mounted retractably on a top of the front rod and a front wheel.

An aisle containment system is disclosed. The aisle containment system includes a frame defined by wall beams, header frames, and a plurality of posts secured to the wall beams and header frames. The header frames extend the width of the frame and the wall beams extend the length of the frame. A plurality of blanking panels extend from the floor to one of the wall beams. The plurality of blanking panels have a top, a bottom, a first side and a second side. Vertical stiffeners are positioned along at least one of the first side and the second side of each blanking panel. The blanking panels overlap adjacent blanking panels along the length of the frame. The blanking panels are laterally adjusted to fill openings in the aisle containment system.

An aisle containment system is disclosed. The aisle containment system includes a frame defined by wall beams, header frames, and a plurality of posts secured to the wall beams and header frames. The header frames extend the width of the frame and the wall beams extend the length of the frame. A plurality of blanking panels extend from the floor to one of the wall beams. The plurality of blanking panels have a top, a bottom, a first side and a second side. Vertical stiffeners are positioned along at least one of the first side and the second side of each blanking panel. The blanking panels overlap adjacent blanking panels along the length of the frame. The blanking panels are laterally adjusted to fill openings in the aisle containment system.

A vertically floating hinge includes a pin having a linear configuration, a first leaf, and a second leaf. The first leaf includes a pair of spaced apart first-leaf knuckles rotatably coupled to the pin. The second leaf includes at least one second-leaf knuckle rotatably coupled to the pin, the second-leaf knuckle situated between the pair of spaced apart first-leaf knuckles and configured to slide along the pin between the pair of first-leaf knuckles. The first-leaf knuckles are spaced apart from one another and define a first-leaf space therebetween, each first-leaf knuckle defining a first-leaf knuckle channel configured to receive the pin therethrough. The at least one second-leaf knuckle is smaller than the first-leaf space so as to selectively slide vertically along the pin between the pair of first-leaf knuckles.

A rack assembly having two side racks, two rails, and at least one sub-rack, wherein the rails are mounted between the side racks and include a front rail and a rear rail lower than the front rail. Each rail has an opening in a side of the rail, with the opening of the front rail defined in a bottom of the front rail and the opening of the rear rail defined in the rear rail at a side facing the front rail. The at least one sub-rack has a rack frame, a connection rod, and at least one supporting member and is slidable along the rails The rack frame has at least one front rod and at least one rear rod wherein each front rod has an extension rod mounted retractably on a top of the front rod and a front wheel.

A mobile storage system includes a series of storage units movable relative to each other to create an aisle or aisles between adjacent storage units. The mobile storage system includes a gesture sensor on each storage unit that is able to detect movement of a hand of a user near the gesture sensor. The gesture sensor communicates the detected movement of the user's hand to a control unit of the mobile storage system such that the control unit can coordinate the movement of the storage units. The gesture sensor includes a light emitter and a light detector that operate to detect the movement of the user's hand. Based on the direction of movement detected, the control unit can move the storage units or activate a light or other device. A method of operating the mobile storage system based on the sensed movement detected by the gesture sensor is also disclosed.

A mobile storage system includes a series of storage units movable relative to each other to create an aisle or aisles between adjacent storage units. The mobile storage system includes a gesture sensor on each storage unit that is able to detect movement of a hand of a user near the gesture sensor. The gesture sensor communicates the detected movement of the user's hand to a control unit of the mobile storage system such that the control unit can coordinate the movement of the storage units. The gesture sensor includes a light emitter and a light detector that operate to detect the movement of the user's hand. Based on the direction of movement detected, the control unit can move the storage units or activate a light or other device. A method of operating the mobile storage system based on the sensed movement detected by the gesture sensor is also disclosed.