Provided is a stand for a device that is capable of storing, in a stable state, a plurality of arms that are rotatably coupled. The stand for a device includes a supporter including a first fulcrum, a first arm that is coupled to the supporter so as to be rotatable around the first fulcrum and that includes a second fulcrum on one end, and a second arm that includes a first end and a device-side second end, the first end being coupled to the first arm so as to be rotatable around the second fulcrum. In a case where the first arm and the second arm are positioned at stored positions, the second fulcrum is positioned below the first fulcrum and, also, the second arm is tilted with respect to the vertical direction toward the first arm side.

Systems and methods for assembling structural components are disclosed wherein a selectively configurable fixture is placed on an assembly surface of an assembly table. An assembly table interface couples about a pin of a pin slot of the assembly table and, by means of linkage assembly, translates movement of the pin to a positioning member. The positioning member, by the translated movement of the pin, abuts an element of structural component and supports the element while a fastener is applied to join multiple elements of the structural component. A selectively configurable fixture may be used in isolation, or in combination with other fixtures.

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 motor including a rotor, a first arm, a mount, a stator, a first bearing, and a second bearing. The motor is configured to rotate the rotor. The mount connected to the first arm. The stator coupled to the mount. The first bearing located between and connecting the rotor to the stator. The second bearing located between and connecting the rotor to the mount. The first arm prevents movement of the stator and the mount.

The disclosure relates to an accessory support device, comprising a support structure that defines a flat base plane. And comprising an inclined portion that is supported on the support structure that extends in an inclined plane upward relative to the base plane from a front of the accessory support device to a rear of the accessory support device. The accessory support device further comprises an upright portion that is supported on the support structure or on the inclined portion that extends in a mainly upright plane relative to the base plane from the rear of the accessory support device, so as to form a privacy panel that shields the user from being seen from the rear of the accessory support device. The upright portion and the inclined portion are angularly adjustably connected via an angle compensation device to compensate the upright portion for angular adjustment of the inclined portion.

A telescoping extension device for camera phones utilizes an extendable, telescoping pole, a control handle located at the first end of the pole, and a camera phone holder designed to support a camera phone attached at the upper or second end of the pole. A propeller blade assembly, consisting of propeller blades and an electric motor, is attached to the second end of the pole. A propeller blade control switch located on the control handle provides a remote signal to the motor to control the off and on rotation and speed of the blades. By actuating the motor and rotating the blades, a “helicopter” effect is created, resulting in the second end of the pole to be lifted, thereby increasing the photographic field of vision of the camera phone.

A carrier arm joint device for a carrier arm of a stand device for arranging in the operating room and for displacing a medical device held on the carrier arm is configured for setting a payload corresponding to a weight of the medical device to be taken up by the carrier arm. The device includes at least one pivot axis for mounting at least one strut of the carrier arm, respectively; and a support axis for supporting a lever configured to transmit forces holding the carrier arm between the strut and the carrier arm joint device A distance between the axes is adjustable within an adjustment range in order to set the payload; the size and/or the extent of the adjustment range is independent of the position of the pivot axis. It is possible to maximize the adjustment range and therefore the payload spectrum in a comparatively compact and structurally rigid joint. A carrier system and a stand device can include at least one such carrier arm joint device.

A display device which can elevate and rotate to a position includes a base, a controlling member mounted to the base, and a supporting frame. A display is mounted on the supporting frame, and a first magnetic piece is positioned on the controlling member. A second magnetic piece is positioned on the supporting frame. The first and second magnetic pieces are configured to attract each other. The controlling member includes a first elastic piece between the base and the supporting frame. The first elastic piece retracts to enable the supporting frame to rotate. The controlling member can slide to detach the second magnetic piece from the first magnetic piece, and the first elastic piece retracts to allow an upward rotation of the supporting frame thereby changing height of the display.

Aspects of the present invention provide a display support arm assembly that includes a proximal housing supporting at least one proximal shaft, a distal housing spaced from the proximal housing and supporting at least one distal shaft, and at least one link extending from the at least one proximal shaft to the at least one distal shaft. The at least one link is coupled for pivotal movement about an axis of the at least one proximal shaft. The display support assembly also includes a gas strut extending between the proximal housing and the distal housing. The gas strut provides substantially constant force throughout a range of the vertical adjustment of the display support arm. The display support assembly further includes at least one torque element associated with either or both of the at least one proximal shaft and the at least one distal shaft.

The description relates to cooperatively controlling devices based upon their location and pose. One example can receive first sensor data associated with a first device and second sensor data associated with a second device. This example can analyze the first sensor data and the second sensor data to determine relative locations and poses of the first device relative to the second device and can supply the locations and poses to enable content to be collectively presented across the devices based upon the relative locations and poses.