The present invention relates to a door hinge including: a fixed part having a body formed in an angular pipe shape of at least a triangle or more, a rack gear disposed parallel to the body on one side inner surface of the body, and an insertion hole formed on the side portion of the body in such a manner as to communicate with the interior of the body; and an operating part having a rotary shaft, a pinion gear disposed on the outer peripheral surface of the rotary shaft in such a manner as to correspond to the rack gear, and a moving piece protruding outwardly from the outer peripheral surface of the rotary shaft, wherein the rotary shaft is inserted into the insertion hole in such a manner as to allow the moving piece to outwardly protrude from the door hinge, and the moving piece rotates around the rotary shaft, so that the rotary shaft moves along the rack gear.

A hinge assembly for a swinging door includes a shifting pivot point movable between a first concealed positioned and a second extended position to provide clearance for protruding trim pieces and the like upon opening the swinging door. A double action spring mechanism energizes to drive the shifting pivot point between the first and second positions. An assembly including a link arm and a bell crank is driven by the double action spring mechanism to shift the shifting pivot point and locking mechanisms are provided to lock each of the link arm and the bell crank in their respective extended positions. A compartment assembly includes a swinging door, a fixed structure to which the swinging door is movably coupled, at least one hinge assembly according to the present disclosure.

A hinge assembly for a swinging door includes a shifting pivot point movable between a first concealed positioned and a second extended position to provide clearance for protruding trim pieces and the like upon opening the swinging door. A double action spring mechanism energizes to drive the shifting pivot point between the first and second positions. An assembly including a link arm and a bell crank is driven by the double action spring mechanism to shift the shifting pivot point and locking mechanisms are provided to lock each of the link arm and the bell crank in their respective extended positions. A compartment assembly includes a swinging door, a fixed structure to which the swinging door is movably coupled, at least one hinge assembly according to the present disclosure.

An electronic device is provided. The electronic device includes a housing including first and second housings, a display including a first display region connected to the first housing and a second display region connected to the second housing, and a hinge module connected to the first housing and the second housing. The hinge module may include a rotation bracket including a first accommodation space providing a first rotation axis and a second accommodation space providing a second rotation axis, a rotation member including a first rotation member connected to the first display region and a second rotation member connected to the second display region, and a rail member including a first rail member connected to the first rotation member and configured to rotate in the first accommodation space, and a second rail member connected to the second rotation member and configured to rotate in the second accommodation space.

An electronic device is provided. The electronic device includes a housing including first and second housings, a display including a first display region connected to the first housing and a second display region connected to the second housing, and a hinge module connected to the first housing and the second housing. The hinge module may include a rotation bracket including a first accommodation space providing a first rotation axis and a second accommodation space providing a second rotation axis, a rotation member including a first rotation member connected to the first display region and a second rotation member connected to the second display region, and a rail member including a first rail member connected to the first rotation member and configured to rotate in the first accommodation space, and a second rail member connected to the second rotation member and configured to rotate in the second accommodation space.

A hinge assembly includes a first hinged body, a pivot pin assembly, and a second hinged body. The first hinged body includes a channel. The pivot pin assembly includes a pin body configured to slideably engage the channel. The pivot pin assembly may be translated within the channel and adjustably secured along the channel. The pin body includes a downwardly extending pin. The second hinged body comprises a pin aperture configured to cooperatively receive the pin. The first hinged body and the second hinged body are configured to hingedly pivot along a hinge axis defined by the pin when the pin is received in the pin aperture. The pin body may include a pin body aperture configured to receive an alignment fastener such that the pin body may be tilt adjusted relative to the first hinged body.

A hinge assembly includes a first hinged body, a pivot pin assembly, and a second hinged body. The first hinged body includes a channel. The pivot pin assembly includes a pin body configured to slideably engage the channel. The pivot pin assembly may be translated within the channel and adjustably secured along the channel. The pin body includes a downwardly extending pin. The second hinged body comprises a pin aperture configured to cooperatively receive the pin. The first hinged body and the second hinged body are configured to hingedly pivot along a hinge axis defined by the pin when the pin is received in the pin aperture. The pin body may include a pin body aperture configured to receive an alignment fastener such that the pin body may be tilt adjusted relative to the first hinged body.

A multi-position hinge includes a base seat, a first axle, a second axle and a sliding assembly. The first and second axles rotatably extend through the base seat in a first direction and are spaced apart from each other in a second direction. The first axle has a first recess, a second recess and a first gear portion. The second axle has a third recess, a fourth recess and a second gear portion corresponding with the first recess, the second recess and the first gear portion, respectively. The sliding assembly includes a first sliding member engageable with the first and third recesses, and a second sliding member engageable with the second and fourth recesses. The first and second axles are rotatable in turn and then rotated synchronously to perform multi-position shifting.

A foldable hinge is described herein that includes a plurality of interconnected sliding links, wherein each of the interconnected sliding links comprise at least one curved extruding prong and at least one curved rail. The at least one curved rail of a first interconnected sliding link can be coupled to the at least one curved extruding prong of a second interconnected sliding link to form a torque engine. Additionally, the interconnected sliding links can be rotatable based on a pressure applied to the interconnected sliding links. The foldable hinge can also include a plurality of shafts coupled to the plurality of interconnected sliding links, wherein each shaft is coupled to a separate interconnected sliding link.

The description relates to hinged devices, such as hinged computing devices. One example can include a first portion including an electronic component and a second portion including a second electronic component. A hinge assembly can rotatably secure the first and second portions through a range of rotation from a closed orientation to an open orientation. A dumbbell-shaped shield assembly can be configured to provide an orientation-specific protective pathway between the first portion and the second portion for a conductor extending from the first electronic component to the second electronic component.