A piece of computer furniture for adjustably positioning at least one computer peripheral device, with a base (1) arranged below a legroom (2) and adapted to support the piece of computer furniture on the floor, a shelf (3) for placing or holding the piece of computer peripheral device, a main stand (4) extending from the base (1) on one side and laterally adjacent the legroom (2) to the shelf (3). The main stand (4) is connected or coupled to the base (1) via a first joint (5) so as to be inclinable and fixable in a selectable inclination position. The shelf (3) is connected or coupled to the main stand (4) via a second joint (6) so as to be inclinable and fixable in a selectable inclination position. A swivel joint (7) is provided for horizontally pivoting the shelf (3).

The present invention provides a plastic motor for a handheld stabilizer, comprising an upper bearing, a lower bearing, motor iron cores, an iron core carrier, a hollow metal motor shaft, a locking structure, a motor shell and a motor end cover, wherein at least one of the iron core carrier, the motor shell and the motor end cover is made of plastic material, the hollow metal motor shaft passes through the center of the upper bearing, the iron core carrier and the lower bearing in sequence, and a locking structure is provided at the other end of the hollow metal motor shaft. By the plastic motor for a handheld stabilizer disclosed in the present invention, problems in the prior art such as high cost of motors for handheld stabilizers, low production efficiency, difficulty in threading, tending to deform after loading and short service life are solved.

A hollow hinge includes a first hollow component, a second hollow component and a plurality of support assemblies. The first hollow component has a first surface and a second surface opposite to the first surface, and a plurality of concave portions are disposed on the second surface. The second hollow component is disposed on the second surface of the first hollow component and a plurality of receiving portions corresponding to the concave portions are disposed on the second hollow component. The support assemblies are respectively contained in the receiving portions and continuously butt against the first hollow component through a force. The hollow hinge avoids friction between components and strengthens support, thereby prolonging durability and improving assembly and production yield rate.

A hollow hinge includes a first hollow component, a second hollow component and a plurality of support assemblies. The first hollow component has a first surface and a second surface opposite to the first surface, and a plurality of concave portions are disposed on the second surface. The second hollow component is disposed on the second surface of the first hollow component and a plurality of receiving portions corresponding to the concave portions are disposed on the second hollow component. The support assemblies are respectively contained in the receiving portions and continuously butt against the first hollow component through a force. The hollow hinge avoids friction between components and strengthens support, thereby prolonging durability and improving assembly and production yield rate.

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.

Methods, apparatus, systems and articles of manufacture are disclosed to mount a camera to a mounting plate, the apparatus comprising: a camera socket connector to connect to a socket of the camera; and a mounting plate connector to connect to the mounting plate, wherein the camera socket connector able to be removably coupled to the mounting plate connector.

A device for supporting solar modules is provided, the device having a base rail) and an upper support arranged on the base rail for holding an upper end of a solar module. The upper support has a first support element and a second support element which are movably connected to one another in such a way that the first support element is movable relative to the second support element between a first position and a second position. The upper support extends up to a first height above the base rail when the first support element is arranged in the first position. The upper support extends up to a second height above the base rail, which is different from the first height, when the first support element is arranged in the second position. A kit, a method for manufacturing a device, and a solar module arrangement are also provided.

A hollow hinge includes a first hollow component, a second hollow component and a plurality of support assemblies. The first hollow component has a first surface and a second surface opposite to the first surface, and a plurality of concave portions are disposed on the second surface. The second hollow component is disposed on the second surface of the first hollow component and a plurality of receiving portions corresponding to the concave portions are disposed on the second hollow component. The support assemblies are respectively contained in the receiving portions and continuously butt against the first hollow component through a force. The hollow hinge avoids friction between components and strengthens support, thereby prolonging durability and improving assembly and production yield rate.

A stand assembly for an electronic device includes a neck portion with a first end that holds and extends from the electronic device, a spine portion that is coupled via a joint structure to a second end of the neck portion, the joint structure being configured to provide a first rotational degree of freedom of the neck portion with respect to the spine portion, and one or more interconnect wires. The one or more interconnect wires include a first wire portion, a second wire portion and a third wire portion, the first wire portion being routed through an interior of the neck portion, the second wire portion being routed along a surface of the spine portion, and the third wire portion being routed though the joint structure from the surface of the spine portion to the interior of the neck portion.

A assembled support mechanism for an LED display screen, comprises: a bottom support, being in an assembled frame structure, provided with devices configured for longitudinal and transverse splicing at a periphery thereof, and the devices configured for longitudinal and transverse splicing comprising a longitudinal engagement device and a transverse engagement device; and middle portions of a front side and a rear side of the bottom support being respectively provided with screen connecting portions configured for connecting to an LED display screen in a vertical direction. A plurality of rotational stands, in detachable connection with the bottom support, and a respective rotational stand after being spliced and assembled being rotatable around the bottom support with a rotational angle range of 0° to 180°.