In an aspect, an electromechanical apparatus is provided, comprising an electromagnet, a magnetically permeable rotor, a drive, a current source, a current sensor and processing logic. The electromagnet includes a magnetically permeable housing and a wire coil disposed therein. The rotor spins and is disposed in the path of a magnetic circuit generated by the electromagnet. The drive rotates the rotor relative to the electromagnet housing. The rotor and electromagnet housing vary the reluctance therebetween as the rotor rotates. The current source applies a current to the electromagnet coil, wherein, during rotation of the rotor, fluctuations in the current result in the electromagnet coil due to the aforementioned varying reluctance are superimposed on the applied current. The current sensor senses fluctuations in current in the electromagnet coil. The processing logic reads the sensed current and determines the frequency of the fluctuations, which are correlated to rotor speed.

An isolating decoupler comprising a hub for connection to a shaft, a pulley journalled to the hub, the pulley having a belt engaging surface, a composite spring having a clutch portion, a transition portion and a variable diameter portion, the composite spring engaged between the hub and the pulley, the clutch portion diameter reducible in a loading direction for a frictional engagement with the pulley in the loading direction, the frictional engagement of the clutch portion progressively releasable from the pulley in an unloading direction, the variable diameter portion having a diameter which varies according to a torque load; and an inertial member engaged with the hub through a damping member.

An isolating decoupler comprising a hub for connection to a shaft, a pulley journalled to the hub, the pulley having a belt engaging surface, a composite spring having a clutch portion, a transition portion and a variable diameter portion, the composite spring engaged between the hub and the pulley, the clutch portion diameter reducible in a loading direction for a frictional engagement with the pulley in the loading direction, the frictional engagement of the clutch portion progressively releasable from the pulley in an unloading direction, the variable diameter portion having a diameter which varies according to a torque load; and an inertial member engaged with the hub through a damping member.

An engine accessory with a wrap spring clutch, which is configured for selectively transmitting rotary power between a drive member and a shaft, and an actuator that is configured to selectively control the clutch. The actuator has first and second rotary flux elements, a clutch control ring and an electromagnet. The first rotary flux element is rotatably coupled to the drive member and has a plurality of first teeth that are spaced circumferentially about the rotary axis. The clutch control ring is rotatable about the rotary axis and is coupled to the tang of the wrap spring. The second rotary flux element is rotatably coupled to the clutch control ring. The second rotary flux element has a plurality of second teeth that are spaced circumferentially about the rotary axis. The electromagnet is selectively operable to generate a magnetic field that is transmitted between the first and second teeth.

A high-load linear actuator includes a driving mechanism, a worm shaft, a worm wheel assembly, a lead screw, a telescopic pipe and an outer pipe. The driving mechanism includes a base and a motor. The base has a supporting portion and an accommodating portion. The motor is fixed to the supporting portion. The worm shaft extends from the motor into the supporting portion. The worm wheel assembly includes a worm wheel and two bearings for supporting the worm wheel in the accommodating portion. The worm wheel is engaged with the worm shaft. The lead screw is disposed through the worm wheel and driven by the motor for rotation. The telescopic pipe slips on the lead screw to be threadedly connected therewith. The outer pipe slips on the telescopic pipe. The rotation of the lead screw drives the telescopic pipe to linearly extend or retract relative to the outer pipe.

An air clutch cover for an air clutch assembly of an agricultural planter is provided. The air clutch cover includes a shell which may be removably installed onto the air clutch assembly. The shell has an opening sized to sealingly receive an air cylinder of the air clutch assembly therethrough. Sidewalls of the shell include cut-outs for allowing portions of the air clutch assembly to protrude outwardly from the air clutch cover.

An air clutch cover for an air clutch assembly of an agricultural planter is provided. The air clutch cover includes a shell which may be removably installed onto the air clutch assembly. The shell has an opening sized to sealingly receive an air cylinder of the air clutch assembly therethrough. Sidewalls of the shell include cut-outs for allowing portions of the air clutch assembly to protrude outwardly from the air clutch cover.

A clutch/brake assembly includes: an input shaft arranged to be rotated, in use, by a motor; an output shaft configured to be rotated by the input shaft when brought into engagement therewith; rotating clutch plate elements configured to transmit torque from the input shaft to the output shaft when engaged; a logarithmic spring mounted around the input shaft; a translating shaft around the spring; an output sleeve between the output shaft and the clutch plate elements; and a solenoid connected to the translating shaft. The solenoid can be in at least two states and either cause movement of the translating shaft to compress the spring in first or second directions control the assembly.

A clutch/brake assembly includes: an input shaft arranged to be rotated, in use, by a motor; an output shaft configured to be rotated by the input shaft when brought into engagement therewith; rotating clutch plate elements configured to transmit torque from the input shaft to the output shaft when engaged; a logarithmic spring mounted around the input shaft; a translating shaft around the spring; an output sleeve between the output shaft and the clutch plate elements; and a solenoid connected to the translating shaft. The solenoid can be in at least two states and either cause movement of the translating shaft to compress the spring in first or second directions control the assembly.

In an aspect, the invention is directed to a clutched device that includes a clutch input member, a clutch output member, and a wrap spring clutch. The wrap spring clutch is engageable with the clutch input member and the clutch output member and has a radially outer surface and a radially inner surface. One of the radially outer and inner surfaces is engageable with a clutch engagement surface on one of the clutch input member and the clutch output member. The clutch engagement surface has a surface finish that includes peaks and valleys, wherein the peaks engage the wrap spring clutch and each have a selected width.