A one way clutch comprises an outer race including a radially outer first annular part to which rotation is input from outside and a radially inner second annular part capable of rotating when receiving rotation from the first annular part, an inner race provided radially inside the outer race and rotatable relative to the outer race, a plurality of torque transmission members provided between the outer race and the inner race to transmit torque between the outer race and the inner race, and a coupling mechanism that couples the first annular part and the second annular part together to make them integrally rotatable when the speed of rotation input from outside is lower than a specific speed and decouples them when the speed of rotation exceeds the specific speed.

A one way clutch comprises an outer race including a radially outer first annular part to which rotation is input from outside and a radially inner second annular part capable of rotating when receiving rotation from the first annular part, an inner race provided radially inside the outer race and rotatable relative to the outer race, a plurality of torque transmission members provided between the outer race and the inner race to transmit torque between the outer race and the inner race, and a coupling mechanism that couples the first annular part and the second annular part together to make them integrally rotatable when the speed of rotation input from outside is lower than a specific speed and decouples them when the speed of rotation exceeds the specific speed.

The invention relates to pumping equipment and can be used in oil industry as part of submersible electric centrifugal pump units. Device for prevention of turbine rotation consists of interconnected head and base, inside of which two shafts are installed on bearing supportsupper and lower ones, connected to each other through a cam clutch with the possibility of free running in the circumferential direction. The overrunning clutch is installed in the head, providing torque transmission in the forward direction from the lower shaft to the upper one and preventing reverse rotation of the upper shaft. The overrunning clutch is connected with the upper shaft via a coupling clutch, movable part of which is mounted on the upper shaft with possibility of axial movement, and stationary part is rigidly connected to the overrunning clutch. Coupling of the coupling clutch is provided by a spring, and disconnection is provided by a pusher mounted on the upper shaft with possibility of axial movement, and on one side the pusher is connected to the movable part of the coupling clutch and on the other sidewith a bush sleeve having an inclined end surface rigidly installed on the lower shaft. The technical result is to increase reliability and safety of Electric Centrifugal Pumping Unit due to use of the apparatus for preventing rotation of the turbine.

A high-speed overrunning coupling and control assembly, coupling assembly and locking member which pivotally moves with substantially reduced friction are provided. At least one pivot projects from a main body portion of the locking member and enables pivotal motion of the locking member. The at least one pivot is sized, shaped and located with respect to the main body portion so that the at least one pivot makes contact with at least one bearing located between a pocket surface of a pocket and an outer surface of the at least one pivot to reduce friction during pivotal motion.

A slip clutch, including: an output hub; a first hub; a second hub non-rotatably connected to the output hub; an input hub arranged to receive rotational torque. The input hub includes: a first plurality of balls; a first plurality of springs urging the first plurality of balls radially outwardly into contact with the first hub; a second plurality of balls; and a second plurality of springs urging the second plurality of balls radially outwardly into contact with the second hub.

A slip clutch, including: an output hub; a first hub; a second hub non-rotatably connected to the output hub; an input hub arranged to receive rotational torque. The input hub includes: a first plurality of balls; a first plurality of springs urging the first plurality of balls radially outwardly into contact with the first hub; a second plurality of balls; and a second plurality of springs urging the second plurality of balls radially outwardly into contact with the second hub.

A one way clutch comprises an outer race including a radially outer first annular part to which rotation is input from outside and a radially inner second annular part capable of rotating when receiving rotation from the first annular part, an inner race provided radially inside the outer race and rotatable relative to the outer race, a plurality of torque transmission members provided between the outer race and the inner race to transmit torque between the outer race and the inner race, and a coupling mechanism that couples the first annular part and the second annular part together to make them integrally rotatable when the speed of rotation input from outside is lower than a specific speed and decouples them when the speed of rotation exceeds the specific speed.

A one-way overrunning alternator clutch includes a shaft that includes a flange disposed at a first end of the shaft. The one-way overrunning alternator clutch also includes an axle extending from a first side of the flange to a second end of the shaft and a spring set that engages the flange of the shaft. The shaft includes a first spring, a second spring, and a third spring. The one-way overrunning alternator clutch also includes a first retainer engaging the spring set, and a pulley that includes an inner bore that receives the shaft, the spring set, and the retainer.

Provided herein is a method for calibrating a clutch by searching for the minimum of a multi-dimensional surface including determining the error between a spline function and recorded data relating to clutch characteristics, creating a multi-dimensional surface corresponding to the error values, determining the minimum of the multi-dimensional surface using the steps of performing a Steepest Gradient & Direction determination step and conducting a Golden Section Search and Switch Direction Step to find a minimum that meets a predetermined closing condition. Additionally, provided herein is a computer-implemented system for calibrating the clutch.

Provided herein is a method for calibrating a clutch by searching for the minimum of a multi-dimensional surface including determining the error between a spline function and recorded data relating to clutch characteristics, creating a multi-dimensional surface corresponding to the error values, determining the minimum of the multi-dimensional surface using the steps of performing a Steepest Gradient & Direction determination step and conducting a Golden Section Search and Switch Direction Step to find a minimum that meets a predetermined closing condition. Additionally, provided herein is a computer-implemented system for calibrating the clutch.