A portable electronic device including a first body, a second body, and a hinge mechanism is provided. The second body is connected to the first body through the hinge mechanism, and the hinge mechanism has a basis axis located at the first body and a rotation axis located at a lower end of the second body. When the second body rotates with respect to the first body, the rotation axis slides along an arc shaped path with respect to the basis axis to increase or decrease a distance between the rotation axis and the basis axis and increase or decrease a distance between the lower end of the second body and a back end of the first body.

A portable electronic device including a first body, a second body, and a hinge mechanism is provided. The second body is connected to the first body through the hinge mechanism, and the hinge mechanism has a basis axis located at the first body and a rotation axis located at a lower end of the second body. When the second body rotates with respect to the first body, the rotation axis slides along an arc shaped path with respect to the basis axis to increase or decrease a distance between the rotation axis and the basis axis and increase or decrease a distance between the lower end of the second body and a back end of the first body.

An artificial joint is provided. The artificial joint may comprise: a first joint member including a first bone replacement part, and a (1-1).sup.st branch and a (1-2).sup.st branch branched from opposite sides of the first bone replacement part; a second joint member including a second bone replacement part, and a (2-1).sup.nd branch and a (2-2).sup.nd branch branched from opposite sides of the second bone replacement part; a first main string connecting one side of the (1-1).sup.st branch and one side of the (2-1).sup.nd branch; a second main string connecting the one side of the (1-1).sup.st branch and one side of the (2-2).sup.nd branch; a third main string connecting one side of the (1-2).sup.st branch and the one side of the (2-1).sup.nd branch; and a fourth main string connecting the one side of the (1-2).sup.st branch and the one side of the (2-2).sup.nd branch.

A hinge structure includes a main support including a sliding groove disposed therein; a limit support rotationally connected to the main support via a straight shaft disposed in the sliding groove, and a limit groove is disposed at one side of the limit support; a sub support connected to the limit support via a crank shaft, wherein the sub support is sleeved on the crank shaft, a crank sliding block is disposed at one end of the crank shaft and in the limit groove; and a shaft sleeve; wherein when the main support rotates relative to the sub support, the straight shaft slides in the sliding groove and the crank sliding block slides in the limit groove. A folding mechanism and a mobile terminal are also provided.

A hinge structure includes a main support including a sliding groove disposed therein; a limit support rotationally connected to the main support via a straight shaft disposed in the sliding groove, and a limit groove is disposed at one side of the limit support; a sub support connected to the limit support via a crank shaft, wherein the sub support is sleeved on the crank shaft, a crank sliding block is disposed at one end of the crank shaft and in the limit groove; and a shaft sleeve; wherein when the main support rotates relative to the sub support, the straight shaft slides in the sliding groove and the crank sliding block slides in the limit groove. A folding mechanism and a mobile terminal are also provided.

A self-aligning support incorporates a support attachment fitting and a rotatable pin assembly having a primary load pin coupling the support attachment fitting to an attachment support, and inboard and outboard attachment claws engaged to end portions of the primary load pin. The rotatable pin assembly is configured to rotate relative to the support attachment fitting. At least one fuse pin extends through the primary load pin to limit translation of the primary load pin relative to the inboard and outboard claws.

A hinge includes: a base seat that includes a rack extending in a front-back direction; a moving platform that is movable on the base seat along the front-back direction; and a shaft unit that includes a rotating shaft rotatably extending through the moving platform in a left-right direction, a main gear member rotatably extending through the moving platform, co-movable with the moving platform, and meshed with the rack to constitute a rack and pinion system, and a first bevel gear piece fixedly sleeved on the rotating shaft, and meshed with the main gear member such that rotation of the rotating shaft results in collective linear front-back motion of the shaft unit and the moving platform relative to the base seat.

A hinge includes: a base seat that includes a rack extending in a front-back direction; a moving platform that is movable on the base seat along the front-back direction; and a shaft unit that includes a rotating shaft rotatably extending through the moving platform in a left-right direction, a main gear member rotatably extending through the moving platform, co-movable with the moving platform, and meshed with the rack to constitute a rack and pinion system, and a first bevel gear piece fixedly sleeved on the rotating shaft, and meshed with the main gear member such that rotation of the rotating shaft results in collective linear front-back motion of the shaft unit and the moving platform relative to the base seat.

A bearing including a sidewall including a substrate and a low friction material extending along at least one of a radially inner surface or a radially outer surface of the sidewall, the sidewall further including: a body defining a bore about a central axis; and a flange contiguous with and extending from an axial end of the body, where the flange includes a folded over outermost peripheral edge, where the substrate has a reduced thickness at the outermost peripheral edge, the flange being configured such that the substrate is not exposed along the outermost peripheral edge.

A foldable terminal is disclosed, which may include a first storage rotation shaft, a second storage rotation and a flexible screen. One end of the flexible screen is connected and fixed to the first storage rotation shaft, and the other end of the flexible screen is connected and fixed to the second storage rotation shaft. And a portion of the flexible screen is wound around at least one of the first storage rotation shaft and the second storage rotation shaft. In response to the flexible screen being folded, the first storage rotation shaft is rotatable to release the flexible screen, and in response to the flexible screen being unfolded, the second storage rotation shaft is rotatable to roll up the flexible screen.