In some embodiments, a computer peripheral mounting device for connecting a peripheral device to a support, wherein the support defines a thickness, comprises a fixed tubing extending in a longitudinal direction; a clamp coupled to a first end of the fixed tubing; an adjustment mechanism positioned at a second end of the fixed tubing, opposite the first end, and a shaft positioned within the fixed tubing and coupled between the adjustment mechanism and the clamp, wherein the adjustment mechanism is configured to rotate around the longitudinal direction relative to the fixed tubing in order to rotate the shaft within the fixed tubing and without the adjustment mechanism nor the shaft translating along the longitudinal direction relative to the fixed tubing, and wherein rotation of the shaft is configured to cause the distance between the first surface and the second surface to change.

A display apparatus includes an at least partially deformable display, an at least partially deformable apron, the apron is coupled to the display and moves in a vertical direction to change an externally exposed area thereof, a housing for accommodating at least a portion of each of the display and the apron, a base coupled to the housing, a guide having a first end mounted on the apron and a second end mounted on the base, the guide moves the display and the apron in the vertical direction to change an externally exposed area of each of the display and the apron, and a moving supporter having a first end mounted on the apron to move in the vertical direction and a second end mounted on the base to move in a lateral direction with respect to the base.

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 system can include a stand that includes a base and an upright; at least one arm mountable to the upright; and serial transmission port circuitry operatively coupled to a plurality of serial transmission ports disposed along the upright.

Examples relate to a surgical microscope system and a corresponding apparatus, method and computer program. The surgical microscope system comprises one or more sensors for providing sensor information about a balance of the surgical microscope system. The surgical microscope system comprises one or more brakes for holding at least one component of the surgical microscope system in place. The surgical microscope system comprises a surgical microscope. The surgical microscope system comprises a processing module, configured to process the sensor information. The processing module is configured to determine an information about the balance of the surgical microscope system. In some embodiments, the processing module is configured to provide a warning to a user of the surgical microscope system based on the information about the balance of the surgical microscope system. The warning indicates danger of imbalance in the surgical microscope system. Alternatively or additionally, the processing module may be configured to control a release of the one or more brakes based on the information about the balance of the surgical microscope system.

Disclosed is an articulated support arm for an elongated flexible medical instrument, including: a segment rotating about an axis of rotation, a radial brake for preventing rotation of the segment about the axis of rotation, including: a supply of hydraulic fluid, a piston whose stroke along the direction of the axis of rotation, due to the pressure of the hydraulic fluid, prevents rotation of the segment about the axis of rotation, the piston being an annular piston having a hollow center about the axis of rotation, the supply of hydraulic fluid passing through the hollow center.

Implementations relate to a configurable counterbalance mechanism. In some implementations, a counterbalance apparatus includes a spring, a tension element coupled between the spring and a mechanical ground, a base element coupled to a load, and a configurable arm rotatably coupled to the base element. A first pulley and a second pulley are rotatably coupled to the configurable arm, the second pulley orbitable about the first axis, and the tension element is at least partially wrapped around the first pulley and the second pulley. The configurable arm is rotatably configurable at either a first orientation or a second orientation, where the first orientation is associated with a center of gravity of the load located on a first side of the counterbalance apparatus and the second orientation is associated with the center of gravity of the load located on a second side of the counterbalance apparatus opposite to the first side.

A projector mount assembly for a sports enclosure includes a frame structure mountable to rear and front cross beams of a sports enclosure, at least one extension bracket secured to the frame structure and mountable to the front cross beam, and a projector mounting arm mounted to the at least one extension bracket and extending forwardly therefrom. The projector mounting arm is adapted to support, and facilitate front-to-back adjustment of, a projector. The projector mounting arm is pivotable relative to the at least one extension bracket to facilitate adjustment of an elevation of the projector.

A floating mechanism (300) and an ultrasonic diagnostic apparatus. The floating mechanism (300) and the ultrasonic diagnostic apparatus can implement the direct superposition of lifting movements and rotational movements, so that the floating mechanism (300) can move in more directions. In addition, a lifting structure and a rotation structure in the floating mechanism (300) are integrally linked in design, accordingly, the link performance is good, the response is fast, the occupied space is small, and the operation range is great.

Examples are disclosed that relate to display assemblies and counterbalance mechanisms for rotatable displays. In one example, a counterbalance mechanism for a rotatable display comprises at least one crank arm rotatably connected to a ground. The counterbalance mechanism also comprises at least one spring comprising a first end connected to a spring end of the at least one crank arm, and a second end connected to the ground. At least one connecting link has a first portion connected to the at least one crank arm and a second portion connected to the rotatable display.