A multistage friction hinge is described. In at least some embodiments, the described hinge enables a support component to be adjustably attached to an apparatus. According to various embodiments, a hinge includes different activity stages where movement of the hinge is based on different activity mechanisms. For instance, the hinge includes different sets of components that form different friction engines that provide resistance to rotational and/or pivoting movement of the hinge.

An example device includes a first member, a second member, and a hinge. The hinge pivotably couples the first member to the second member. The hinge includes a damper. The damper includes core, and the core has a lobed portion. In another example, a device includes a first mounting member, a second mounting member, a first connector pivotably coupled to the first mounting member at a first hinge and to the second mounting member at a second hinge, a second connector pivotably coupled to the first mounting member at a third hinge and to the second mounting member at a fourth hinge, and a damper positioned at least at one of the first hinge, second hinge, third hinge or the fourth hinge, the damper including core with lobed portion.

Technologies are described relating to sequential multi-axis hinges that rotatably secure portions of a computing device. One example can include a set of hinges that rotate around a set of hinge shafts. The example can also include a shuttle cam through which an individual hinge shaft passes. The shuttle cam can be configured to move orthogonally relative to the individual hinge shaft to block rotation of the individual hinge shaft or an adjacent individual hinge shaft.

A friction hinge is described. Generally, the friction hinge provides a variable torque profile for a movable component.

The description relates to devices that include hinged portions and controlling rotation of the portions. One example can include a display coupled to a first end of an arm. The example can also include a base rotatably secured to a hollow shaft that is fixed to the arm. The hollow shaft defines an axis of rotation of the arm relative to the base. The base can also include first and second opposing axial cam elements positioned on the hollow shaft and a spring positioned on the hollow shaft. The first and second opposing axial cam elements can be oriented relative to one another such that rotation of the arm toward the base causes the first and second axial cam elements to move away from one another along the hollow shaft thereby compressing the spring.

A multistage friction hinge is described. In at least some embodiments, the described hinge enables a support component to be adjustably attached to an apparatus. According to various embodiments, a hinge includes different activity stages where movement of the hinge is based on different activity mechanisms. For instance, the hinge includes different sets of components that form different friction engines that provide resistance to rotational and/or pivoting movement of the hinge.

A hinge (100) including a first hinge leaf assembly, a second hinge leaf assembly pivotally coupled to the first hinge leaf assembly (101), a spring (138) operatively connected to the first and second hinge leaf assemblies, and a spring tensioning mechanism to adjust the bias of the spring (138). The first hinge leaf assembly includes a first hinge component (101) having a first mounting surface for securing to a first structure and a plurality of first knuckles (114, 115). The second hinge leaf assembly includes a second hinge component having a second mounting surface for securing to a second structure and a second knuckle (123). The spring biases the first hinge leaf assembly and the second hinge leaf assembly toward a closed position, wherein the spring is located with a hollow defined by coaxial alignment of the plurality of first knuckles (114, 115) and the second knuckle (123).

A multistage hinge is described. In at least some embodiments, the described hinge mechanism enables a support component to be adjustably attached to an apparatus, such as a computing device. According to various embodiments, a hinge mechanism includes different activity stages where movement of the hinge is based on different activity mechanisms. For instance, the hinge mechanism includes a spring-activated mechanism that controls movement of the hinge over a particular range of angles. Further, the hinge mechanism includes a friction mechanism (e.g., a friction engine) that controls movement of the hinge over a different range of angles.

A hinge mechanism of the present disclosure includes a pair of hinge units each having a hinge base, a hinge upper member, and a shaft, and the hinge mechanism holds an automatic document feeder to be openable/closable in up/down directions with respect to an image reading unit. The hinge base is supported on the image reading unit which reads a document image. The hinge upper member is supported on the automatic document feeder which feeds a document to the image reading unit. The shaft pivotably couples the hinge base and the hinge upper member together. By attaching the hinge upper member to the automatic document feeder, a groove formed in a circumferential surface of the shaft in an annular shape in a circumferential direction of the shaft and a rib provided on the automatic document feeder engage with each other, whereby axial movement of the shaft is restricted.

A door closer assembly includes a central shaft rotatingly mounted in an outer housing and which passes through at least one brake pad. One or more wedges are slidingly mounted on the central shaft by means of a fastener. The wedges, upon tightening of the fastener, wedge against an inclined surface, which forces the wedges downwards and applies a downwards force that causes a friction-enhanced surface to rub against the at least one brake pad.