There is provided a torque transmission joint configured to transmit torque between end portions of a driving shaft and a driven shaft arranged in series in an axial direction. An outer-diameter-side concave-convex portion is formed on an inner periphery of one shaft of the driving shaft and the driven shaft or a member fixed to the one shaft, an inner-diameter-side concave-convex portion is formed on an outer periphery of the other shaft or a member fixed to the other shaft, and the outer-diameter-side concave-convex portion and the inner-diameter-side concave-convex portion are engaged with a circumferential gap being interposed therebetween. An elastic member is provided between the end portion of the driving shaft and the end portion of the driven shaft either directly or via another member such that torque can be transmitted between the driving shaft and the driven shaft.

A driving tool is provided, including a tool set and a driving head. The tool set includes a connecting sleeve, an outer sleeve and at least one limitation member. The connecting sleeve has a receiving slot and a driving end. A plurality of protruding ribs extending axially and a plurality of recesses disposed between the protruding ribs are disposed on an inner wall of the receiving slot. The recesses are provided for a polygonal ball head to insert therein. A recessed portion and a protruding portion are disposed on the inner wall. The outer sleeve is slidable between a first position and a second position. When the outer sleeve is at the first position, the limitation member can restrict the polygonal ball head. When the outer sleeve is at the second position, the polygonal ball head is withdrawable from the receiving slot.

A connecting arrangement for connecting two parts (1, 5) by way of two connected sockets (2, 4), wherein parts and sockets have rotationally symmetrical engagement regions, not exceeding 180°, about engagement axes (11, 15 or 12, 14), which engagement regions are complementary between one part and one socket each, wherein one socket is rotated into one part each, and the complementary engagement regions hold the part on its socket so as to be pivotable about the respective aligned engagement axes and so as to withstand tensions in the direction of a zenith axis of the parts (10 or 16), and in that, after the parts and socket pairs are rotated into engagement and positioned with respect to each other, the sockets (2, 4) are connected to each other, the connection being rotationally and tensionally stiff with respect to the direction of the zenith axes.

A connecting arrangement for connecting two parts (1, 5) by way of two connected sockets (2, 4), wherein parts and sockets have rotationally symmetrical engagement regions, not exceeding 180°, about engagement axes (11, 15 or 12, 14), which engagement regions are complementary between one part and one socket each, wherein one socket is rotated into one part each, and the complementary engagement regions hold the part on its socket so as to be pivotable about the respective aligned engagement axes and so as to withstand tensions in the direction of a zenith axis of the parts (10 or 16), and in that, after the parts and socket pairs are rotated into engagement and positioned with respect to each other, the sockets (2, 4) are connected to each other, the connection being rotationally and tensionally stiff with respect to the direction of the zenith axes.

A motor drive unit, in which an output end of a motor drive system using an electric motor as a power source and a rotator rotatably supported by a bearing unit are arranged side by side in an axial direction, and the output end of the motor drive system and the rotator are drivingly coupled in a relatively displaceable manner by a coupling member in which a plurality of couplers spaced apart in an axial direction are set. The bearing unit of the rotator is arranged such that a center of displacement of the rotator defined by the bearing unit is located between an arbitrary pair of couplers among the couplers.

A torque transmitting coupling for an electric submersible pump equipment string. A torque transmitting coupling system includes a first adapter including a first inner diameter mated to a first shaft rotatable about a first axis of rotation, and a first splined outer diameter mated to a splined coupling inner surface, a second adapter including a second inner diameter mated to a second shaft rotatable about a second axis of rotation, and a second splined outer diameter mated to the splined coupling inner surface, the first and second splined outer diameter at least partially spherical such that when the first axis of rotation moves with respect to the second axis of rotation, at least one of the splined outer diameters rock along the coupling inner surface.

A universal joint (U-joint) assembly transmits torque from a drive component to a driven component across an articulating joint. The U-joint assembly includes male and female U-joint members, a central ball joint, and a retaining device configured to secure the assembly in an assembled configuration. The female U-joint member includes a cavity extending into a receptacle end thereof. The cavity terminates in a circular receptacle and includes a plurality of rectangular channels extending radially outward from the cavity at equal intervals, each channel defined by three planar drive surfaces. The male U-joint member has a drive end with a plurality of corresponding rectangular extensions protruding from an outer periphery of the drive end, each extension including a plurality of axial angular surfaces. When assembled, each of the angular surfaces of the drive end opposes a corresponding one of the drive surfaces of the cavity. Other embodiments are also disclosed.

A universal joint (U-joint) assembly transmits torque from a drive component to a driven component across an articulating joint. The U-joint assembly includes male and female U-joint members, a central ball joint, and a retaining device configured to secure the assembly in an assembled configuration. The female U-joint member includes a cavity extending into a receptacle end thereof. The cavity terminates in a circular receptacle and includes a plurality of rectangular channels extending radially outward from the cavity at equal intervals, each channel defined by three planar drive surfaces. The male U-joint member has a drive end with a plurality of corresponding rectangular extensions protruding from an outer periphery of the drive end, each extension including a plurality of axial angular surfaces. When assembled, each of the angular surfaces of the drive end opposes a corresponding one of the drive surfaces of the cavity. Other embodiments are also disclosed.

A corner module of a vehicle includes: a suspension configured to be coupled to a vehicle body; a case configured to be coupled to the suspension and configured to be to be supported on the vehicle body via the suspension; an in-wheel motor disposed inside the case; a steering motor disposed inside the case; a first power transmission mechanism configured to connect the in-wheel motor and a vehicle wheel and configured to transmit a rotating force of the in-wheel motor to the vehicle wheel to drive the vehicle wheel; and a second power transmission mechanism configured to connect the steering motor and the vehicle wheel and configured to transmit a rotating force of the steering motor to the vehicle wheel to steer the vehicle wheel.

Surgical tools having a two degree-of-freedom wrist, wrist articulation by linked tension members, mechanisms for transmitting torque through an angle, and minimally invasive surgical tools incorporating these features are disclosed. An elongate intermediate wrist member is pivotally coupled with a distal end of an instrument shaft so as to rotate about a first axis transverse to the shaft, and an end effector body is pivotally coupled with the intermediate member so as to rotate about a second axis that is transverse to the first axis. Linked tension members interact with attachment features to articulate the wrist. A torque-transmitting mechanism includes a coupling member, coupling pins, a drive shaft, and a driven shaft. The drive shaft is coupled with the driven shaft so as to control the relative orientations of the drive shaft, the coupling member, and the driven shaft.