An electronic device includes a fan assembly that draws air (including heated air) away from components and forces the air out of the electronic device. The fan assembly includes a guide vane located in the fan housing. Subsequent to air entering the fan assembly via the fan inlets, the guide vane is designed to direct the air to a fan outlet. Further, the guide vane is designed and positioned in the fan assembly to limit or prevent flow separation that may cause the heated air to recirculate and may also cause increased turbulence leading to elevated acoustic noise. Furthermore, the guide vane may include a tapered region to allow the heated air to readily flow over the guide vane to limit or prevent a vortex from occurring within the fan assembly. Using the guide vane, the fan assembly drives more air at the same fan speed and lowers noise generation.

Provided is a curvature variable display device including a panel assembly including a display panel, a back plate disposed on a rear surface of the panel assembly, a first side bracket and a second side bracket respectively coupled to two sides of a rear surface of the back plate, a bending plate having one end rotatably coupled to the first side bracket and another end rotatably coupled to the second side bracket and having a convex curvature toward a rear of the back plate, a stand post having an upper end coupled to a center area of the bending plate and a lower end coupled to a stand base, and a dial assembly provided on the stand base to wind or unwind a wire coupled to the rear surface of the back plate and change curvatures of the panel assembly and the back plate.

Various implementations for a display positioning system include stand with a front a back surface being connected to form a curved bend such that the bottom edges of the front and back surface are spread out to support the stand, the front surface is further connected to a stand lip forming a stand channel between the front surface and an extended portion of the stand lip, an insert configured to rest within the stand channel of the stand and including a front plate and a back plate that extend beyond a top portion of the insert and form an insert channel, the insert channel being configured to receive a first edge of a computing device and support the computing device in an elevated position, and an adapter with an optical element that is configured to rest within a first slot in the stand when not in use.

Various embodiments provide a display screen system that includes a display screen, a first stand element, and a second stand element. The display screen can include a front display surface, a back surface, and a bottom surface. The first and second stand elements can each include a connection element disposed between a first end and a second end. The display screen stand system can be configured to be assembled in a table top configuration or a wall mount configuration. In the table top configuration, the first stand element and the second stand element are attached to the bottom of the display screen. In the wall mount configuration, the first stand element and the second stand element are configured to be coupled to the back of the display screen.

The display apparatus includes a display assembly. The display apparatus further includes a mounting device on which the display assembly is mounted and a rotating shaft forming the center of rotation of the display assembly. The rotating shaft is at a fixed location for the mounting device and the display assembly, respectively. The display assembly is switched between a first mode and a second mode rotated from the first mode about a rotating shaft and is changed in the height of the center of the display assembly.

A floating rubber foot structure is provided herein. The floating rubber foot structure includes a floating rubber foot extending through an opening in a device case. The floating rubber foot is mounted to an inner surface of the device case at a mounting point proximate to the opening, and the floating rubber foot is disposed with a gap between the floating rubber foot and a wall of the opening in the device case.

An electronic device may have a glass housing structures. The glass housing structures may be used to cover a display and other internal electronic device components. The glass housing structure may have multiple glass pieces that are joined using a glass fusing process. A peripheral glass member may be fused along the edge of a planar glass member to enhance the thickness of the edge. A rounded edge feature may be formed by machining the thickened edge. Raised fused glass features may surround openings in the planar glass member. Multiple planar glass members may be fused together to form a five-sided box in which electronic components may be mounted. Raised support structure ribs may be formed by fusing glass structures to a planar glass member. Opaque masking material and colored glass may be used to create portions of the glass housing structures that hide internal device components from view.

A base may be configured to be attached to a pedestal. The pedestal may include a top plate, a bottom plate, and a mounting tab. The bottom plate may be configured to rest on a horizontal surface. The mounting tab may extend from the top plate (e.g., a platform on the top plate). The mounting tab may be configured to extend into an opening defined by the base. The mounting tab may be configured to prevent rotation of the base of the remote control device when the base is attached to the pedestal. The bottom plate may include a concave bottom surface. The concave bottom surface may include a recessed portion and a flat portion. The flat portion may be along an outer perimeter of the bottom plate. The flat portion may be configured to rest on the horizontal surface.

A mobile device accessory comprising a base that affixes to a mobile device, and a rotating element, such as a rotary ball-bearing disc, coupled to said base allowing for the device to spin along the axis of the rotating element. The accessory may further comprise hinged or extendable arms. The accessory may further comprise a power source or motor for rotating the accessory. The accessory may further comprise a control circuit coupled to a software application capable of controlling the rotation of the spinning element.

A display including a supporting stand and a display panel is provided. The supporting stand has a rotating assembly, a drive motor, and a microcontroller. The display panel has a computing device. The drive motor is connected to the rotating assembly for driving the rotating assembly to rotate. The microcontroller is coupled to the drive motor for controlling the drive motor. The display panel is disposed on the rotating assembly. The computing device is coupled to the microcontroller. The computing device is configured to read an image. The computing device transmits a signal to the microcontroller based on an orientation of the image being portrait or landscape so that the microcontroller switches on the drive motor and the rotating assembly drives the display panel to rotate relative to the supporting stand for switching a rotating position of the display panel to a portrait mode or a landscape mode.