A friction driven beltless grain spreader system is presented that includes a spreader cone having a pulley and a grain deflector configured to disperse the flow of grain. A motor having a driven wheel and an idler wheel are pivotally connected to the spreader cone in operative engagement with the pulley such that the idler wheel is positioned between the driven wheel and the pulley. A tension member applies a force that pulls the driven wheel and intermediary wheel into the pulley. As the motor rotates the driven wheel rotates the idler wheel which rotates the pulley. When forces spike, such as when the motor is turned on or a heavy flow of grain hits the system, one or more of the driven wheel, intermediary wheel and/or pulley slip with respect to the other wheels thereby preventing breakage of the system.

Embodiments of a friction drive system include a battery, a drive motor, a control unit, and a speed wheel. When the friction drive system is mounted on a wheeled vehicle, the speed wheel provides an accurate measurement of the vehicle speed by maintaining contact with a tire of the vehicle. An automatic traction control system, which may be part of the control unit, compares the speed of the speed wheel with the speed of the drive motor to determine whether slippage is occurring. If slippage is detected, then embodiments of an automatic traction control system automatically increase an amount of normal force between a contact surface on the drive motor and the tire, by advancing a position of the drive motor relative to a fixed mounting point. If no slippage is detected, then embodiments of an automatic traction control system automatically reduce the amount of normal force, by retracting a position of the drive r elative to a fixed mounting point. In embodiments of a friction drive system, the relative position of the drive motor may be controlled by powering a worm gear motor attached to a worm gear in response to commands from the control unit.

A sun roller of a friction roller-type transmission includes a movable sun roller element (23) capable of moving in an axial direction. Furthermore, the sun roller is provided with a loading cam mechanism which is formed along the circumferential direction of an input shaft (12), the loading cam mechanism having a first cam surface (75), a second cam surface (77) arranged facing the first cam surface (75) and secured to the input shaft (12), rolling elements (63) held between the first and second cam surfaces (75, 77), and an annular holding device (51), and the loading cam mechanism axially displacing the movable sun roller element (23). The holding device (51) has an inside-diameter-surface guiding part (81) for positioning the holding device relative to the input shaft by being fitted over the input shaft, the guiding part being provided to the inside diameter surface.

A sun roller of a friction roller-type transmission includes a movable sun roller element (23) capable of moving in an axial direction. Furthermore, the sun roller is provided with a loading cam mechanism which is formed along the circumferential direction of an input shaft (12), the loading cam mechanism having a first cam surface (75), a second cam surface (77) arranged facing the first cam surface (75) and secured to the input shaft (12), rolling elements (63) held between the first and second cam surfaces (75, 77), and an annular holding device (51), and the loading cam mechanism axially displacing the movable sun roller element (23). The holding device (51) has an inside-diameter-surface guiding part (81) for positioning the holding device relative to the input shaft by being fitted over the input shaft, the guiding part being provided to the inside diameter surface.

Compound planetary friction drive comprising an input shaft driving a sun wheel, wherein said sun wheel engages planetary wheels, which planetary wheels are arranged with a first part having a first radius and a second part having a second radius that differs from the first radius, and where-in a ring cylinder is provided that is engaged by the planetary wheels such that the sun wheel is in frictional engagement with the first part of the planetary wheels and the ring cylinder is in frictional engagement with the second part of the planetary wheels, wherein the planetary wheels are hollow and compressible.

A MTD unit according to a present disclosure includes a bearing member that has an inner ring, a plurality of rolling elements and an outer ring and is capable of bearing a radial load and a unidirectional axial load, a retainer that has a retaining part retaining the rolling elements such that the rolling elements are rotatable around their own axes and rotates around an axis of the inner ring in accordance with an orbital motion of the rolling elements around the inner ring, and a case that accommodates the bearing member and the retainer, wherein the case has a piston that is axially movable so as to push a movable body, which is either the inner ring or the outer ring, in a first axial direction, an oil chamber provided on an opposite side of the piston from the movable body, and an oil passage for guiding pressurized oil to the oil chamber.

The present application discloses an automobile steering simulator structure, comprising a simulator, a coupling and a steering wheel, wherein the coupling is fixedly connected to an output end of the simulator, and the steering wheel is fixedly connected to one end of the coupling, wherein a back cover is nested at a bottom of the simulator, a plurality of installation holes are provided at the bottom of the simulator, and a DC power interface and a USB interface are arranged in a middle of the back cover, wherein a first cavity and a second cavity are fixedly provided inside the simulator.

A transmission and components thereof are provided. In one aspect, the transmission component has one or more formations, the one or more formations being substantially elongate and running along an engagement face of the component, the formation(s) configured to be frictionally engagable with a substantially elongate recess of a second transmission component; and/or (ii) one or more recesses, the one or more recesses being substantially elongate and running along an engagement face of the component, the recess(es) configured to be frictionally engagable with a substantially elongate formation of a second transmission component. In a second aspect, the transmission has a first transmission component and a second transmission component having one or more substantially elongate recesses, wherein the formation(s) of the first transmission component are frictionally engageable with the recess(es) of the second transmission component, such that in use the first transmission component is capable of driving the second transmission component. In a third aspect, a method for improving the torque density of a transmission is provided by setting or adjusting an amount of frictional engagement between two components involved in the torque flow through the transmission.

A transmission and components thereof are provided. In one aspect, the transmission component has one or more formations, the one or more formations being substantially elongate and running along an engagement face of the component, the formation(s) configured to be frictionally engagable with a substantially elongate recess of a second transmission component; and/or (ii) one or more recesses, the one or more recesses being substantially elongate and running along an engagement face of the component, the recess(es) configured to be frictionally engagable with a substantially elongate formation of a second transmission component. In a second aspect, the transmission has a first transmission component and a second transmission component having one or more substantially elongate recesses, wherein the formation(s) of the first transmission component are frictionally engageable with the recess(es) of the second transmission component, such that in use the first transmission component is capable of driving the second transmission component. In a third aspect, a method for improving the torque density of a transmission is provided by setting or adjusting an amount of frictional engagement between two components involved in the torque flow through the transmission.

A friction transmission device includes: an input trajectory ring; a planetary rolling body that is disposed about a rotation axis line of the input trajectory ring and that comes into contact with the input trajectory ring; an output trajectory ring that comes into contact with the planetary rolling body and that is connected to an output member; and a first support trajectory ring and a second support trajectory ring that come into contact with the planetary rolling body; in which at least one of the input trajectory ring, the output trajectory ring, the first support trajectory ring, or the second support trajectory ring is a convex-concave contact trajectory ring that comes into convex-concave contact with the planetary rolling body.