A coupling assembly includes: a screw rod; a holder mounted on the screw rod; a shaft sleeve set and a connection rod set. The shaft sleeve set includes: a first shaft sleeve embedded in the holder; and a second shaft sleeve fitted over the screw rod at an outer side and slidable on the screw rod. The connection rod set includes: a first connection rod having an end fixedly coupled to the first shaft sleeve; and a second connection rod having an end fixedly coupled to the second shaft sleeve, the second connection rod and the first connection rod crossing and being coupled at a junction. The first connection rod and the second connection rod cross to form an angle.

The triaxial hinge includes a first hinge shaft attached to a first casing via a first bracket, a second hinge shaft attached to a second casing via a second bracket and a third hinge shaft coupled to one end portion of a first coupling part and one end portion of a second coupling part. Respective other end portions of both coupling parts are attached to the first hinge shaft. There is a gear type synchronous rotation unit for transmitting a rotation of one of the first hinge shaft and the second hinge shaft accompanied by an opening and closing operation of the both casings to the other hinge shaft via the third hinge shaft, which is made to move in a forward and backward direction as accompanied by an opening and closing operation of the both casings.

A hinged mobile computing device includes a first housing part and a second housing part coupled by a hinge assembly having a harness, a harness cover, a first hinge body, and a second hinge body. The harness is configured to accommodate flexible printed circuitry and a cable that extend from the first housing part to the second housing part via the hinge assembly. The hinge bodies include respective friction bands, each friction band being configured to engage a respective shaft formed on the harness and having a gear configured to mesh with a respective cog arranged within the harness cover to coordinate a timing of the rotation of the first and second housing parts between face-to-face and back-to-back orientations. The hinge assembly further includes a spring-loaded opening mechanism.

A door system includes a track, a sidelite panel, and a slide panel. The track spans across a doorway having a clear opening defined by a trailing jamb and a lead jamb. The trailing jamb includes a jamb face facing the lead jamb. The sidelite panel is coupled to the trailing jamb by at least one swing clear hinge including a fixed portion and a revolving portion. The fixed portion is offset away from the lead jamb with regard to the jamb face. The slide panel is operable to move along the track. The slide panel has an open configuration when positioned in the track. The revolving portion is at least partially offset away from the lead jamb with regard to the jamb face when the slide panel is in the open configuration. The sidelite and slide panels are configured to pivot out of the header into a breakout configuration.

A hinge member of a display device includes: first, second, and third plates which are spaced apart from each other; a first rotating shaft and a second rotating shaft to rotate the second plate; a third rotating shaft and a fourth rotating shaft to rotate the third plate; a first shaft support connected to one end of the first rotating shaft and one end of the second rotating shaft; a second shaft support connected to other end of the first rotating shaft and other end of the second rotating shaft; a third shaft support connected to one end of the third rotating shaft and one end of the fourth rotating shaft; a fourth shaft support connected to other end of the third rotating shaft and other end of the fourth rotating shaft. At least one of the first and second rotating shafts and at least one of the third and fourth rotating shafts are linearly movable in response to rotation of one of the second and third plates.

The present invention relates to a door hinge height adjusting device that can adjust the relative vertical position of a second support bracket with respect to a first support bracket in a door hinge that rotatably connects one side surface of a door forming a rotating door to a support frame in a door frame, the door hinge comprising: the first support bracket which is fixedly connected to the support frame side of a door frame; the second support bracket which is fixedly connected to the door side; and a hinge portion which is provided between the first support bracket and the second support bracket, for relative rotation.

A hinged mobile computing device includes a first housing part with a first display and a second housing part with a second display. The first and second housing parts are coupled by a hinge assembly that includes a spring-loaded opening mechanism configured to bias with a biasing torque the first housing part and second housing part to rotate away from each other when the first and second displays are in a closed face-to-face orientation. An electro-magnetic closure system is configured to retain the first and second displays in the closed face-to-face orientation against the biasing torque of the spring-loaded opening mechanism, and release of the electro-magnetic closure system permits the first housing part to rotationally separate from the second housing part to a predetermined angular orientation due to the biasing force of the spring-loaded opening mechanism.

The disclosure relates to a biaxial hinge mechanism including a positioning plate, a first main shaft, a second main shaft, a cam, and a linkage assembly. The positioning plate has a first through hole and a second through hole. The first main shaft is movably disposed through the first through hole. The second main shaft is rotatably disposed through the second through hole. The cam is fixed on the second main shaft. The linkage assembly is connected to the first main shaft and movable with the cam. When the second main shaft is rotated in a specific direction, the cam pushes the linkage assembly to force the first main shaft to move away from the second through hole so as to increase an axis distance between the first main shaft and the second main shaft. In addition, the disclosure relates to an electronic device having the biaxial hinge mechanism.

According to one embodiment, an electronic apparatus includes a first casing, a second casing, and a hinge which couples them rotatably from a first state to a second state. The hinge includes a first shaft, a first rotation engaging portion, a second shaft, a second rotation engaging portion, a housing, and a transmission unit. The transmission unit links the first engaging portion and the second engaging portion and rotates them with respect to a rotation angle of the housing from the first state to the second state.

A hinge for a mobile terminal having an inwardly bendable flexible screen comprises: a three-member mechanism consisting of a left supporting plate, a middle supporting plate and a right supporting plate which are rotatably and sequentially connected; a left supporting frame; a right supporting frame; and a middle U-shaped outer cover. Both ends of the three-member mechanism are free ends, such that the left supporting plate, the middle supporting plate and the right supporting plate are flexible screen supporting members capable of moving up and down. After moving up, the left supporting plate, the middle supporting plate and the right supporting plate form a flexible screen supporting face, and after moving down, the components are in a bent state, thereby providing a space for bending of the flexible screen. After moving down, the middle supporting plate reaches a bottom portion of the middle U-shaped outer cover. The present invention can provide a larger space for bending of the flexible screen such that the middle mechanism of the hinge is not exposed after folded, and it can be used in mobile terminals such as mobile phones, e-books, and computers, enabling the mobile terminal to achieve large-screen display in a small volume.