The present disclosure describes a mount adapted to being secured to a drop ceiling T-bar. The mount includes a base having a slot, an alignment component coupled to or integral with an adjustable clamp having a clamp end, the alignment component slidably received within the slot such that the adjustable clamp is movable along an axis parallel to the base, at least one stationary clamp coupled to or integral with the base and extending outwardly therefrom, a moveable support coupled to the base via one or more spring-loaded components, and a fastening mechanism configured to secure the adjustable clamp to the base. The clamp end of the adjustable clamp, the at least one stationary clamp, and the moveable support are configured to engage and secure a T-bar therebetween. Mount assemblies and related methods are as described herein.

An orbital camera system has at least two extensions that extend from a hub to rotate a camera about a hub in a balanced and low vibration manner. In addition, the exemplary orbital camera system is versatile in configuration having extensions with hinges to allow variations in the configuration. The hub may be powered by a motor that provides smooth rotation even at low speeds. The hub is coupled to a down rod and the motor may be detachably attached to the down rod. A counterweight may be a battery or a battery station that enables detachable attachment of a battery thereto. An illumination light is coupled to the hub to provide uniform light over the imaging area. A focal element and/or a centering light emitter may be configured along the rotational axis for aid in placing an object to be imaged.

A camera mount includes a pivotable assembly of a pair of arms and a pocket into which an end of one of the arms is inserted, in one of a plurality of discrete orientations. The arms are pivotably joined to one another by a fastener and permitted to be aligned at one of a plurality of angles. The camera mount is installed in a track, a rail or another system mounted to a fixture of a materials handling facility or another environment, and a camera module is mounted to another end of one of the arms. A position of the camera module is selected by installing the camera mount into a desired location on the track, the rail or the other system. An orientation of the camera module is selected by selecting the one of the plurality of discrete orientations and aligning the arms at one of the plurality of angles.

A hanging head connecting mechanism of a ceiling fan has a connecting seat, a hanging rod, and a motor shaft. The connecting seat has a connecting plate, a first bushing, a second bushing, and multiple connecting pieces. The second bushing is located around the first bushing. The hanging rod is mounted in the connecting seat and disposed between the first bushing and the second bushing. The motor shaft is mounted in the connecting seat and disposed inside the first bushing. The connecting pieces are serially mounted through the second bushing, the hanging rod, and the motor shaft. Two of the connecting pieces are each mounted on a respective one of two opposite sides of the second bushing, and a wire-routing gap is formed between the first connecting piece and the second connecting piece.

A load balancing arm for a medical device support system includes a proximal hub, a support arm, first and second springs, and a link. The link has a proximal end pivotably mounted to a link bearing element for pivotable movement about a link pivot axis, and a distal end pivotably mounted to a distal end of the first spring and a proximal end of the second spring. The link and first and second springs are configured such that the biasing forces exerted by the first and second springs are transmitted through the link to the link bearing element thereby to generate a moment about a main pivot axis of a proximal hub that counters a moment generated by a medical device load at a distal end of the support arm.

The present disclosure provides an embedded mounting bracket and camera assembly comprising same. The embedded mounting bracket is used for mounting a camera, and the embedded mounting bracket includes a bracket body and a mounting member. The bracket body includes a bracket side wall, the bracket side wall includes a lower end surface and an upper end surface opposite to the lower end surface, and the upper end surface includes multiple step surfaces with different heights from the lower end surface. The mounting member is detachably assembled to the bracket body for bearing the camera. The mounting member is selectively assembled on the step surfaces with different heights, so as to replaceably assemble at least two cameras with different body heights to the bracket body.

A medical device suspension system includes a spindle extending along a longitudinal axis and a cable management cover surrounding the spindle. A gap is formed between the cable management cover and the spindle. A hub is rotatably mounted to the spindle and includes a housing. A top hub cover is disposed along the longitudinal axis between the hub and the cable management cover and defines an end of the gap, the top hub cover including a passage in fluid communication with an internal volume of the housing. The top hub cover is rotatable with respect to the spindle about the longitudinal axis. A cable is provided within the gap, the cable entering the gap at a fixed location about the longitudinal axis and passing into the housing through the passage. Rotation of the top hub cover about the longitudinal axis causes the passage to rotate about the longitudinal axis.

A mounting device includes a housing, a sliding structure, and a switch structure. The housing includes two tracks, an elastic element including a blocking rib, and a first clamping element. The sliding structure is movably disposed in the tracks and includes a second clamping element and a reverse rib. The switch structure is movably disposed on the sliding structure and includes a forward rib. When the sliding structure is in the installed position, a support frame is fastened between the first clamping element and the second clamping element, and the blocking rib prevents the sliding structure moving relative to the housing. When the switch structure is moved in a detaching direction, the forward rib pushes the blocking rib away from the reverse rib, to allow the sliding structure to move in the detaching direction relative to the housing.

Knuckle joint assembly for a medical device support system. The knuckle joint assembly includes a cartridge assembly that includes a cartridge housing and a rotary bearing. The cartridge housing includes a bore having a central axis and a bearing mount in the bore. The rotary bearing is press fitted in the bearing mount and configured to receive axially therethrough a spindle to rotatably support the spindle about the central axis. The knuckle joint assembly includes a retaining clip and a retaining pin. The retaining clip is selectively movable to disengage and engage a groove in a spindle to respectively support or release the spindle along a central axis. The retaining pin is movable between a first position to allow movement of the retaining clip between positions but prevent removal of the retaining clip, and a second position to block movement of the retaining clip from the engaged position.

A motorized bracket is intended to receive, in a support, a video projector and having a base, a first arm and a second arm. The first arm is connected to the base at a first motorized rotation axis. The second arm is connected to the first arm at a second motorized rotation axis and the second arm is connected to the support at a third motorized rotation axis. The motorized rotation axes each consist of a motor coupled to a geared motor assembly in direct engagement with the arm or the support that is to be controlled.