This application discloses a stand assembly that includes an upper portion for holding electronic components and a lower portion for supporting the upper portion. The lower portion including a base, a joint, and a second fastener structure configured to mate with a first fastener structure of the upper portion. The first fastener structure and the joint are configured to respectively provide a first degree of freedom of motion and a second degree of freedom of motion of the upper portion with respect to the lower portion. Movement of the upper portion at the first degree of freedom has substantially consistent resistance through first part of a first full range of motion associated with the first degree of freedom of motion. Movement of the upper portion at the second degree of freedom has substantially consistent resistance through a second full range of motion associated with the second degree of freedom.

Disclosed is a display device. The display device of the present disclosure may include: a base; a head spaced apart from the base and including a display panel; a pole extending from the base in a direction in which the head is spaced apart from the base; an articulated connector coupled to the head; an elevating module movably coupled to the pole in a length direction of the pole; and an arm extending in a direction intersecting the head and the pole, the arm having one side connected to the articulated connector and the other side connected to the elevating module.

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 method of stabilizing a payload fitted in a carrier includes providing a first carrier component of the carrier, supporting a second carrier component of the carrier using the first carrier component, and supporting a third carrier component of the carrier using the second carrier component. The first carrier component is configured to permit rotation of the payload about a pitch axis. The second carrier component is configured to permit rotation of the payload about a yaw axis. The third carrier component is configured to permit rotation of the payload about a roll axis and connects to the payload.

A stand (100) is disclosed. The stand (100) may include a first connecting component and a second connecting component. The first connecting component may include at least one fixing element and a chamber. The chamber may have an opening. The second connecting component may include an insertion portion including at least one fixing element and a chamber. The chamber may have an opening. When the insertion portion of the second connecting component is inserted, along an axis in an insertion direction, into the chamber through the opening, the fixing element in the first connecting component may work in pairs with the insertion portion to cause the first connecting component to be connected with the second connecting component.

“A multifunctional apparatus to lift and support a computing device includes a base assembly, an oblique arm assembly, a power arm assembly, a head assembly, and a board assembly. The base assembly is adaptable to secure with a platform. The oblique arm assembly is pivotally connected with the base assembly. The power arm assembly is pivotally connected with the oblique arm assembly. The head assembly having a proximal end, and a distal end, wherein the proximal end is pivotally connected with the power arm assembly. The board assembly is rotatably connected with the distal end of the head assembly. The board assembly is adaptable to securely support the computing device.”

A display stand holder with slide rail structure includes a stand body, a pivot member, a display assembly module, and one or more constant-force springs. The stand body has a top end. The pivot member has a first end and a second end. The first end is provided with a pivot portion. The pivot portion is pivotally connected to the top end of the stand body, and the second end is away from the top end with respect to the first end. The display assembly module is disposed at the second end of the pivot member. The display module includes a slide rail assembly. The slide rail assembly includes a guide member and a slide member, and the slide member is slidably assembled on the guide member. The constant-force spring is connected between the guide member and the slide member.

Improved support structures and systems are disclosed for installing tablet devices, display screens, flat screen monitors, or medical devices within a wide variety of environments. A core arm extends from a rear end, toward a front end, in which the rear end is configured to be pivotably mounted either directly to a mount structure, or to an extension arm that in turn is mounted to a mount structure. The front end is configured to be pivotably mounted to a front-end panel mount structure. The structures and systems can be configured for light or heavy configurations, with or without the use of an extension arm, and can provide fully concealed cable routing, in which one or more cables are readily accessible, via snap fit covers, for easy installation and maintenance, which can provide a clean structure that can readily be serviced and cleaned as desired.

A screen support frame includes a base and a supporting member that includes a supporting member mounting portion, which has one end mounted to the base and an opposite end formed with a protrusion, and a supporting member rotating portion including a receiving hole in which the protrusion of the supporting member mounting portion is received. The supporting member rotating portion includes rails, between which a longitudinally movable member is arranged. A frontward projection arm extends from one side of the longitudinally movable member. A screen fixing portion is mounted to the frontward projection arm of the longitudinally movable member of the supporting member rotating portion and includes symmetrically arranged elastic members and symmetrically arranged friction members. The screen fixing portion further includes a rotating disc. The present invention provides effects of adjusting of angle of rotation, vertical position, elevational angle, and sideway rotating angle.

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.