A rotation bracket includes an L-shaped connecting rod, a rotation mechanism, and a stand base. The L-shaped connecting rod includes a vertical rod and a horizontal rod. The vertical rod is configured to connect to a communications device. The horizontal rod is fastened to the rotation mechanism, and the horizontal rod is a rotatable rod. The rotation mechanism is fastened to a top of the stand base, and the rotation mechanism is configured to drive the L-shaped connecting rod to rotate in a horizontal plane. The stand base is configured to fixedly connect to an inner surface of a wall or to a ground.

A display fixing apparatus, which enables a worker to fix a display to a wall at a position in front of the display, is provided.

A display fixing apparatus, which enables a worker to fix a display to a wall at a position in front of the display, is provided.

An adapter plate and a fastening system for fastening a manifold to a rack in a datacenter is disclosed. The adapter plate is associated with the manifold and has holes to receive buttons in configurable positions. The configurable positions enable the buttons to mate with keyholes of a bracket of the rack in order to fasten the manifold to the bracket.

An adapter plate and a fastening system for fastening a manifold to a rack in a datacenter is disclosed. The adapter plate is associated with the manifold and has holes to receive buttons in configurable positions. The configurable positions enable the buttons to mate with keyholes of a bracket of the rack in order to fasten the manifold to the bracket.

A soil compactor machine can include: a machine frame; at least one cylindrical roller drum rotatably coupled to the machine frame and rotatable about a drum axis oriented generally transverse to a direction of travel of the compactor machine; a plurality of sensors mounting locations on the machine frame for mounting one or more lidar sensors and cameras; and a plurality of brackets, wherein, one of each of the plurality of brackets is positioned at each of the sensor mounting locations for mounting the lidar sensors and the cameras, wherein the bracket at each of the sensor mounting locations has a similar design as the other of the plurality of brackets.

A soil compactor machine can include: a machine frame; at least one cylindrical roller drum rotatably coupled to the machine frame and rotatable about a drum axis oriented generally transverse to a direction of travel of the compactor machine; a plurality of sensors mounting locations on the machine frame for mounting one or more lidar sensors and cameras; and a plurality of brackets, wherein, one of each of the plurality of brackets is positioned at each of the sensor mounting locations for mounting the lidar sensors and the cameras, wherein the bracket at each of the sensor mounting locations has a similar design as the other of the plurality of brackets.

The present disclosure relates to a suspension system comprising a hang standard having slots and being configured to be vertically arranged, and a bracket configured to be attached to the hang standard in a cantilevered fashion using connectors on a proximal end of the bracket that enter slots on along the hang standard. A slider unit is adapted to be mounted on the bracket and to carry a container or other component. A rearwardly extending portion of the slider unit is arranged on the slider unit to reach into one of the slots of the hang standard occupied by a connector of the bracket to prevent the slider unit from tilting forward on the bracket.

Disclosed are mounting brackets, mounting bracket assemblies, mountable lights, and methods of installation thereof. In one embodiment, a mounting bracket assembly comprises an obround-shaped wall mount configured to be mounted to a wall and a light mount configured to be coupled to a surface of a light. The wall mount comprises a raised internal ridge extending from a wall-facing side of the wall mount and a rim segment surrounding the raised internal ridge. A clearance space can be formed in between the wall and the rim segment when the wall mount is mounted to the wall. The light mount comprises a curved ledge and an inwardly-projecting brim. At least part of the curved ledge can rest on a top of the wall mount and the inwardly-projecting brim can be positioned within part of the clearance space when the light is mounted to the wall.

Disclosed are mounting brackets, mounting bracket assemblies, mountable lights, and methods of installation thereof. In one embodiment, a mounting bracket assembly comprises an obround-shaped wall mount configured to be mounted to a wall and a light mount configured to be coupled to a surface of a light. The wall mount comprises a raised internal ridge extending from a wall-facing side of the wall mount and a rim segment surrounding the raised internal ridge. A clearance space can be formed in between the wall and the rim segment when the wall mount is mounted to the wall. The light mount comprises a curved ledge and an inwardly-projecting brim. At least part of the curved ledge can rest on a top of the wall mount and the inwardly-projecting brim can be positioned within part of the clearance space when the light is mounted to the wall.