A portable information device includes: a first chassis, a second chassis adjacent to the first chassis, and a hinge device that relatively rotatably connects the first chassis and the second chassis. The hinge device includes: a first torque generating part that generates a rotation torque in relative rotation of a first base plate and a first link plate by sliding resistance between the first base plate and the first link plate, and a second torque generating part that generates a rotation torque in relative rotation of a second base plate and a second link plate by sliding resistance between the second base plate and the second link plate.

An accessory device for an electronic device is disclosed. The accessory device includes multiple sections, with one section holding the electronic device, and another section having an input mechanism, such as a keyboard. The accessory device includes a hinge assembly that allows relative movement of the sections with respect each other. An additional hinge assembly is integrated with the section carrying the electronic device, and provides additional flexibility and range of motion of the section, thereby allowing a user to position the electronic device at multiple different angles relative to the section carrying the input mechanism. Also, each hinge assembly may include multiple roller and spacer elements, as well as a retention structure passing through each roller element and spacer element. The retention structure can provide tension to increase the frictional force between the roller and spacer elements, and/or provide counterbalance to offset the weight of the electronic device.

One aspect is an overmolded hinge device having a first and a second shaft, each having first and second ends. A first friction element is mounted on the first shaft. A first molded housing is at least partially enclosing the first shaft and a second molded housing is at least partially enclosing the second shaft. A first molded outer link is at least partially enclosing each of the first and second shafts and a second molded outer link is at least partially enclosing each of the first and second shafts. One of the first molded housing and the first molded outer link enclose the first friction element

A hinge includes a rotating shaft, two pivoting parts, and a seat. The rotating shaft includes a friction section and a protruding section coaxially extending from the friction section. Each of the pivoting parts includes a connecting piece and a sleeve piece. Each sleeve piece is extended from an edge side of the corresponding connecting piece, and bent and wrapped to form a sleeve hole. Each sleeve piece is configured to be sleeved on the friction section, and the two sleeve pieces on the peripheral surface of the friction section are bent and wrapped in different directions respectively. The seat includes a shaft hole. The friction section and the sleeve pieces are jointly arranged in the shaft hole, the connecting piece is fixed on the seat, and the protruding section protrudes out of the seat.

A thinned hinge includes a rotating part and a torsion supply part. The rotating part includes a base and two movable members arranged on the base, the base includes two tracks for the movable members to displace along arc-shaped trajectories to generate opening and closing actions, and ends of the two movable members where extend outward from the two tracks are provided with driving members. The torsion supply part supplies torsion required by the rotating part, the torsion supply part includes a support, two rotating shafts arranged in parallel on the support, and an idle gear arranged between the two rotating shafts, the two rotating shafts are provided with connecting pieces assembled with the driving members to enable the torsion supply part and the rotating part to simultaneously act and gears engaged with the idle gear, and the gears and the idle gear are crossed helical gear structures.

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 single-axis hinge includes a base, a movable plate, a limiting block, a rotating shaft and a stand set. The base includes a first shaft mounting hole, a stand drive shaft mounting hole and a path. The movable plate is formed with a second shaft mounting hole and a limiting notch. The limiting block is installed in the path. The rotating shaft passes through the first and second shaft mounting holes and includes a driving block and a first cam. An edge of the driving block is formed with a transmission teeth portion not completely surround the edge. The stand set includes a stand drive shaft disposed in the stand drive shaft mounting hole, and a support stand driven by the stand drive shaft. The stand drive shaft includes a gear and a second cam formed with a positioning notch.

A hinge includes two rotatable axle units disposed on a base seat and each having two rotatable hinge shafts, two movable bracket units each including a base plate, two rotary blocks non-rotatably sleeved on the hinge shafts, and two movable plates movable relative to the rotary blocks, and two synchronizing units for making synchronous rotations of the hinge shafts. Each synchronizing unit includes a first gear member having two end surfaces in form of bevel gears, and two second gear members each meshing with the respective end surface and fitted to the respective rotary block. Rotations of the hinge shafts at one side of the base seat result in rotations of the rotary blocks and the second gear members, and bring in rotations of the second gear members, the rotary blocks and the hinge shafts at the other side to make the synchronous rotations.

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.