Disclosed is a biaxial hinge mechanism used on a mobile terminal, comprising a first shaft and a second shaft parallel to each other, and a first support and a second support, wherein the first and second supports are respectively connected to the connection ends of the first and second shafts; the first and second supports are provided with connection end faces facing side faces of the connection ends; riveting columns formed in an integrated manner are provided on the connection end faces; connection through holes are provided on the connection ends; and the riveting columns are connected to the connection through holes. The spaces of the side faces of the hinge, rather than the spaces in the thickness direction of the hinge, are fully used to connect the supports, providing a high space utilization rate and aiding in greatly reducing the thickness of the hinge, and the used connection structure facilitates installation of the supports on the side faces of the hinge, providing a high connection strength. A relatively large rotating torque can be realized by the relatively small size, for example, the torque can reach over 3.5 kg.Math.cm with the overall outer diameter within 3.3 mm.

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 for rotatably mounting an appliance door to a cabinet of an appliance includes a lower cam member coupled to a hinge support bracket and an upper cam member coupled to the appliance door. A pin assembly passes through the upper and lower cam members and is coupled to the hinge support bracket such that it defines an axis of rotation. The upper and lower cam members are configured to engage each other to urge the appliance door toward the closed position. The engagement may be a result of the weight of the door and the hinge assembly may further include a vertically oriented spring for assisting in the downward force of upper cam member.

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 arrangement for a switch cabinet, having a switch cabinet body and a switch cabinet door which is fastened thereto via at least two hinges arranged vertically one above the other, at least a first of the hinges, which is arranged above a second of the hinges, having a first body-side hinge half with a first hinge pin which projects vertically upwards from a first pin seat, onto which a first door-side hinge half is fitted, wherein the first hinge pin has an auxiliary mounting position in which it projects from the first pin seat by a first length which is greater than a second length by which a second hinge pin of a second body-side hinge half of the second hinge projects from its second pin seat. A corresponding method is also described.

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.

Friction hinge (21) for the pivotable connection of two components, comprising at least one first hinge sleeve (24) which is arranged in alignment with at least one further hinge sleeve (22), a shaft (11) which runs through the hinge sleeves (22, 24), and at least one friction spring for exerting a friction torque on the movable shaft (11), wherein at least two mutually aligned friction springs (10, 10′) are connected to the first hinge sleeve (24) via radial shoulders (16, 16′) and exert a friction torque on the shaft (11) mounted in the further hinge sleeve (22).

A hinge assembly (15) comprises a first part (12) having a first hinge member (16), and a second part (14) having a second hinge member (18). The first and first and second hinge members (16, 18) form a pivot arrangement (20) to allow the first part (12) to pivot relative to the second part (14). A hinge pin (22) extends across the pivot arrangement (20), thereby pivotally attaching the first part (12) to the second part (14). The hinge pin (22) and the pivot arrangement (20) include a securing arrangement (26) to inhibit extraction of the hinge pin (22) from the pivot arrangement (20).

Friction hinge (21) for the pivotable connection of two components, comprising at least one first hinge sleeve (24) which is arranged in alignment with at least one further hinge sleeve (22), a shaft (11) which runs through the hinge sleeves (22, 24), and at least one friction spring for exerting a friction torque on the movable shaft (11), wherein at least two mutually aligned friction springs (10, 10′) are connected to the first hinge sleeve (24) via radial shoulders (16, 16′) and exert a friction torque on the shaft (11) mounted in the further hinge sleeve (22).

Disclosed is a biaxial hinge mechanism used on a mobile terminal, comprising a first shaft and a second shaft parallel to each other, and a first support and a second support, wherein the first and second supports are respectively connected to the connection ends of the first and second shafts; the first and second supports are provided with connection end faces facing side faces of the connection ends; riveting columns formed in an integrated manner are provided on the connection end faces; connection through holes are provided on the connection ends; and the riveting columns are connected to the connection through holes. The spaces of the side faces of the hinge, rather than the spaces in the thickness direction of the hinge, are fully used to connect the supports, providing a high space utilization rate and aiding in greatly reducing the thickness of the hinge, and the used connection structure facilitates installation of the supports on the side faces of the hinge, providing a high connection strength. A relatively large rotating torque can be realized by the relatively small size, for example, the torque can reach over 3.5 kg.Math.cm with the overall outer diameter within 3.3 mm.