A monitor arm with decorative lighting (or luminous display arm) includes a light-emitting element and a wire that is connected to the light-emitting element. The light-emitting element and the wire are routed through an inside cavity of the arm. A conductive slip ring is disposed inside a connecting joint of the arm to facilitate electrical connection of the wire. The monitor arm with decorative lighting includes wiring arranged inside a cavity of the arm so as to not be visible from the exterior providing additional safety and organization for wires and a clean outward appearance.

A support system for a display device includes a first arm configured to extend from a support surface. A second arm is rotatably connected to the first arm. The second arm has a range of movement relative to the first arm. A ring housing is rotatably connected to the second arm. A tilt ring is moveably connected to the ring housing and configured to connect to a display. An adjustment mechanism is configured to move the tilt ring relative to the ring housing to modify the frictional engagement of the tilt ring and the ring housing.

Structures and systems are disclosed for supporting tablets or displays. A core arm that is configured to have a range of rotation based on angle length of a track or tunnel, an angle length of a joint rotation stop structure, and an angle length of a floating stop key. The core extends from a rear end to a front end of the structure. The core arm can also include a floating stop key that is movable with the track or tunnel of the core arm structure. The structures and systems can thus be readily configured for light or heavy configurations, with or without the use of an extension arm, and can conceal cable routing, which is accessible, via snap fit covers, for easy installation and maintenance.

A gimbal includes a handle (300), a first arm (100), a second arm (200) and a clamping member (400) sequentially connected, the second arm (200) including a second connecting portion (210) and a second rod portion (211); and further includes: a first driving member (11) connected to the handle (300) and the first arm (100) to drive the first arm (100) to rotate with respect to the handle (300); a second driving member (12) connected to the second connecting portion (210) and the second rod portion (211) in the second arm (200) to drive the second rod portion (211) to rotate with respect to the second connecting portion (210); and a third driving member (13) connected to the second rod portion (211) and the clamping member (400) to drive the clamping member (400) to rotate with respect to the second rod portion (211).

A multifunctional holder is provided for supporting a first object and a second object. The multifunctional holder includes a backboard assembly, an adapter, at least one movable arm and a positioning member. The backboard assembly is disposed on a back side of the first object. The adapter is connected to the backboard assembly. The at least one movable arm is connected to the adapter, wherein a first degree of rotational freedom is provided between the backboard assembly and the adapter, and a second degree of rotational freedom is provided between the adapter and the at least one movable arm. The positioning member is disposed on the backboard assembly or the adapter for fixing the second object.

A rotational mechanism includes a frame, a plurality of rotational units, an inner ring rotatably supported on the frame via the plurality of rotational units, and a rotation driving unit configured to generate power for rotating the inner ring. The inner ring is provided with a protrusion portion on an outer periphery. Each of the plurality of rotational units includes two bearings and a first pressing unit. The first pressing unit is configured to apply pressing forces to the two bearings in opposite directions in a rotational axis direction of the inner race. The protrusion portion is held between the two bearings due to the pressing forces.

Provided is a surveying stand capable of precisely adjusting the angle of a staff. The surveying stand comprises an annular first pedestal (1) and support legs (2) connected to the first pedestal (1). A staff fixture (3) is disposed in the first pedestal (1). A staff alignment device is connected to the first pedestal (1). The staff fixture (3) can rotate horizontally relative to the first pedestal (1). A rotation adjustment device capable of adjusting the rotation angle of the staff fixture (3) is arranged between the first pedestal (1) and the staff fixture (3). The surveying stand is easy to operate and is capable of precisely adjusting the angle of the staff.

This application is directed to a passively-cooled electronic device including a housing, a plurality of electronic assemblies and a plurality of thermally conductive parts. The electronic assemblies are enclosed in the housing and include a first electronic assembly and a second electronic assembly. The first and second electronic assemblies are disposed proximately to each other within the housing, and the second electronic assembly is substantially sensitive to heat, including heat generated by operation of the first electronic assembly. The thermally conductive parts are coupled between the first electronic assembly and the housing, and configured to create a first plurality of heat conduction paths to conduct the heat generated by the first electronic assembly away from the second electronic assembly without using a fan. At least a subset of the thermally conductive parts mechanically supports one or both of the first and second electronic assemblies.

The present invention relates to the field of folding frames, and in particular, to a rivet riveting folding frame. While the rivet riveting folding frame realizes the bending for adjustment of angle, the movable connections are all realized by riveting of rivets, and all the riveting positions of rivets have arc transitions, so that the phenomenon that scratching by screws and nuts is prone to occur in the prior art is avoided, and young users can use them at ease. In addition, the rivet riveting adopted in the present invention can greatly reduce the processing difficulty and improve the assembly efficiency.

A system includes a robotic camera and a robotic display. The robotic camera has a robotic camera mount that moves an image capture device such as a camera and the robotic display has a robotic display mount that moves an image display device, such as a video display. The robotic mounts are used to synchronously move the camera and display so that they are in positions where captured images are displayed in the same orientation, e.g. images captured in a portrait orientation are displayed by the display in the same orientation and images captured in a landscape orientation are displayed by the display in the same orientation.