A control system for an oil supply mechanism includes an oil pump, a hydraulic pressure sensor, a drive shaft, a pump pulley, a toothed belt, and an output shaft. An electronic control unit included by the control system detects an abnormality of the toothed belt based on a comparison result between an actual value and a theoretical value that are frequencies of pressure pulsations of oil. The actual value is a value calculated based on time fluctuations of a hydraulic pressure detected by the hydraulic pressure sensor. The theoretical value is a value calculated based on a rotational speed of the output shaft and the number of teeth of an inner rotor.

A drive system for driving a belt is presented. The system comprises a frame, a driving shaft connected to a motor, a controller, a driven shaft, two pulleys connected to the driven and driving shafts, and a belt. The frame supports the driving and driven shafts to mount the belt on the pulleys. A signal element is mounted on and drives with the belt. At least two detection elements are mounted on the frame so that when the signal element passes the detection elements, a signal is generated as the belt moves. The detector elements are connected to a controller which controls the motor so that when the system starts, the belt moves until the signal element generates a signal in a first detector element to fix a zero point of the belt movement. The signal of the second detector element checks the zero point during normal drive operation.

A sprocket guard assembly comprising a sprocket having sprocket radial spokes, and having teeth on an outer perimeter, the teeth disposed in a plane CL1, each sprocket radial spoke communicating with a first cylindrical surface, a circular member having circular member radial spokes, and each circular member radial spoke communicating with a second cylindrical surface, a collar having an outer cylindrical surface, a fastener engaging the collar, the first cylindrical surface and the second cylindrical surface engaging the outer cylindrical surface, all coplanar in a plane CL2, and plane CL1 is offset from plane CL2.

A method of fabricating a ball nut assembly is provided. The method includes providing a ball nut having a keyway slot. The method also includes forming a polymer pulley having an inner surface defining a bore, a cut-out formed in the inner surface, and a torque member extending radially inward from the inner surface, wherein the keyway slot is configured to receive the torque member therein.

A driven sprocket configured for rotational use in a linear actuator is provided. The driven sprocket includes an outer circumferential surface extending radially from a main body. The outer circumferential surface has a plurality of spaced apart gear teeth configured to engage corresponding structures of a drive belt. An upper rim and a lower rim bound the outer circumferential surface and are configured to maintain a drive belt in an engaged position with the gear teeth. A plurality of internal apertures extend therethrough and are configured to receive portions of a lead screw and portions of a torque limiter. A plurality of spaced apart apertures are configured to receive fasteners configured to secure the torque limiter to the driven sprocket in a manner such that rotation of the driven sprocket results in rotation of the torque limiter.

In some examples, a ball nut includes a first end and an outer cylindrical surface having a first diameter. A pulley may be mounted on the first end of the ball nut. The pulley may include an inner cylindrical surface having a second diameter larger than the first diameter of the ball nut and sized to engage with the outer cylindrical surface in a press fit. Furthermore, a circumferential groove may be formed in a portion of the first end of the ball nut extending beyond the pulley when the pulley is mounted on the first end of the ball nut. A retaining ring is disposed in the circumferential groove to prevent removal of the pulley from the first end of the ball nut. Furthermore, a portion of the ball nut may engage with a portion the pulley to prevent relative rotation between the pulley and the ball nut.

This helically toothed belt power transmitting device (1) has: a toothed belt (10) having a plurality of teeth (12) tilted relative to the width direction of the belt; a drive pulley; and a driven pulley. The width of the helically toothed belt (10) is 1 mm to 20 mm, inclusive. The core (13) of the toothed belt (10) is a twisted cord containing high-strength glass fibers or carbon fibers and has a diameter of 0.2 mm to 0.9 mm, inclusive. The compressibility of the teeth (12) of the toothed belt (10) compressed by the grooves of the drive pulley and the driven pulley is 0% to 5%, inclusive.

A torque transmitting assembly is provided. The assembly includes a ball nut having an outer diameter and keyway slot therein, and a pulley positioned on the ball nut. The pulley includes a cylindrical outer surface, a bore extending through the pulley such that the pulley includes an inner surface, and at least one torque member formed on the inner surface and projecting radially inward to be received by the keyway slot.

Toothed belt drive with a toothed belt and at least two toothed pulleys, wherein the toothed belt has at least one drive side provided with a toothed profile, the toothed belt wraps around the toothed pulleys over a partial area of their circumference and the teeth of the toothed belt meshingly engage in the tooth gaps of the toothed pulleys, wherein at least one of the toothings on the belt or pulley is formed as a series of tooth pitches varying along the circumference, wherein the individual tooth pitches are designed to vary by up to a maximum of 5% relative to the mean tooth pitch on the belt or pulley, and the absolute deviation of a varied tooth pitch from the mean tooth pitch on the belt or pulley is limited by the backlash of the toothing,
wherein the backlash E.sub.S results from the difference of the width e.sub.S of the tooth gaps of the respective toothed pulley and the width e.sub.R of the teeth of the toothed belt in the middle of the tooth height of the teeth of the toothed belt.

The invention relates to a chainwheel (1, 1) for transferring a drive output from an input shaft, more particularly from a drum motor (800), onto a synthetic modular belt (900), a drum motor (800) for driving a synthetic modular belt, a semi-finished chainwheel product (10) for a chainwheel (1, 1) and a method for producing a chainwheel (1, 1). The chainwheel comprises at least one toothed ring and an outer ring (200, 200) and an inner ring (300, 300) adjoining the toothed ring, wherein the inner ring (300, 300) and the outer ring (200, 200) are connected to one another via bridges (410, 410).