A vehicle interior component comprising a cover rotatably coupled to a base at a pivot joint is disclosed. The component may comprise a mechanism comprising a projection engaging a first surface when the cover is closed and engaging a ramp as the cover is rotated between closed and open positions. The pivot joint may comprise an axle to provide an axis of rotation. The pivot joint may comprise the projection on the axle. One of the projection and the ramp may slide along the other as the cover opens and/or closes. The mechanism may comprise a cam surface and a follower. The base and/or cover may flex at the pivot joint. The cover may comprise a door, bin or sunglass bin. The component may comprise a console, center stack/console, floor console, overhead console, instrument panel, door panel, etc.

The description relates to hinged devices, such as hinged computing devices. One example can include first and second portions that rotate around a hinge shaft that is fixedly secured to the first portion and rotationally secured to the second portion. The second portion defining a first contact surface spaced apart from a second contact surface. Multiple friction clips friction fit around the hinge shaft and rotating with the hinge shaft between the first contact surface and the second contact surface.

A hinge structure may comprise a first assembly including a central post with an outer surface and a first connector element on the central post for mounting on a first structure, a second assembly pivotally coupled to the first assembly and including a ring extending about the central post, a ring connector connected to the ring, and a second connector element on the ring for mounting on a second structure. A braking element may apply a selectable amount of resistance to pivot movement of the second connector element with respect to the first connector element and including a friction pad extending about a portion of the central post, a pressure band for pressing the friction pad against the central post, and a connecting structure connecting the ends of the band and being adjustable to move the ends closer toward each other and to relax the ends away from each other.

Conventional laptop computers may utilize a door-hinge style or in a bezel-behind-base style hinge to connect a display with a keyboard of the laptop computer. Typically, these hinges present an undesirable discontinuous visual impression to the user. In the disclosed technology, a leading edge of a display abuts a leading edge a keyboard. The disclosed sliding double-pivot hinge places a pivot axis parallel and coincident with the abutting interface, the leading edges of the display and the keyboard remain abutting throughout a rotational range of motion of the display with reference to the keyboard. The resulting visual impression to the user is that the display is contiguous with the keyboard regardless of the display angle. Further, the disclosed sliding double-pivot hinge may be used in a kickstand to permit the kickstand to rotate up to 180 degrees to fold back on itself and lay flat against an associated computing device.

A hinge assembly for a door, the hinge assembly including a hinge pin arranged to be fixed to the door at one end and having a pin connector part at an opposite second end. A rotation damper connected to a damper connector part arranged to cooperate with the pin connector part for transferring torque around an axis of rotation between the damper connector part and the pin connector part throughout an opening angle of the door, such that a rotational movement of the damper connector part about the axis of rotation in at least a first rotational direction is dampened by the rotation damper. The pin connector part and the damper connection part allow an initial closing angle of rotation of the door before the damper acts on the rotation of the hinge pin, the initial closing angle being at least 2°.

Proposed is a door hinge for an oven. More particularly, proposed is a door hinge for an oven, which when a door is opened, can prevent the door from being excessively opened and can prevent the door from being further opened at the maximum opening angle.

Proposed is a hinge device having tension maintaining function, the hinge device including: a winding member affixed to a main body of a mounted structure having an inner space formed therein; a hinge member affixed to a door that opens or closes the inner space and mounted on the winding member so as to enable the door to be pivotable; and a tension member having one end affixed to the winding member and the other end affixed to the hinge member, such that the tension member transmits a tension to the door when opening and closing the door.

Conventional laptop computers may utilize a door-hinge style or bezel-behind-base style hinge to connect a display with a keyboard of the laptop computer. Typically, these hinges present an undesirable discontinuous visual impression to the user. In the disclosed technology, a leading edge of a display abuts a leading edge of a keyboard. The disclosed sliding double-pivot hinge places a pivot axis parallel and coincident with the abutting interface, the leading edges of the display and the keyboard remain abutting throughout a rotational range of motion of the display with reference to the keyboard. The resulting visual impression to the user is that the display is contiguous with the keyboard regardless of the display angle. Further, the disclosed sliding double-pivot hinge may be used in a kickstand to permit the kickstand to rotate up to 180 degrees to fold back on itself and lay flat against an associated computing device.

Technologies are described for a hinge mechanism coupled to at least a dual-display device wherein the displays can rotate with respect to each other through 360 degrees. The hinge mechanism has at least one flexible connection member that follows a generally S-shaped path when the displays are in a tablet position. In some embodiments, a second flexible connection member can be added that follows a mirrored S-shaped path. The S-shaped path of the first flexible connection member and the mirrored S-shape path of the second flexible connection member together create a cross-configuration. In other embodiments, interconnected friction hinges can allow for a free-stop function at any point along the 360 degrees of rotation.

The description relates to hinged devices, such as hinged computing devices. One example can include first and second portions that rotate around a hinge shaft that is fixedly secured to the first portion and rotationally secured to the second portion. The second portion defining a first contact surface spaced apart from a second contact surface. Multiple friction clips friction fit around the hinge shaft and rotating with the hinge shaft between the first contact surface and the second contact surface.