General Description Industrial: Electromagnetic Particle Clutch
Magnetic particle clutches are unique in their design from other electromechanical clutches because of the wide operating torque range available. Like an electromechanical clutch, torque to voltage is almost linear; however, in a magnetic particle clutch, torque can be controlled very accurately (within the operating rpm range of the unit). This makes these units ideally suited for tension control applications, such as wire winding, foil and film tension control and tape tension control. Because of their fast response, they can also be used in high cycle applications, such as magnetic card readers, sorting machines and labeling equipment.
Ogura Features Industrial: Electromagnetic Particle Clutch
Fast response and accurate control: Voltage to torque is almost linear, so engagement is extremely fast, and controllability of magnetic particle units is very accurate.
Stable torque: Torque is independent of speed, but is proportional to the voltage/current applied to the field, allowing stable torque throughout the units operating rpm range.
Long life: Torque is driven via tooth, so slippage is non-existent when clutch is engaged.
Excellent slip capacity: Because of the units' excellent heat dissipation, and because of their construction, they can operate in a constant slip mode (within max. allowable wattage), which makes them ideal for tension controlling applications.
How It Works Industrial: Electromagnetic Particle Clutch
Engagement: Magnetic particles (very similar to iron filings) are located in the powder cavity. Without any voltage/current, they sit in the cavity; however, when voltage/current is applied to the coil, the magnetic flux that is created, tries to bind the particles together, almost like a magnetic particle slush. As the voltage/current is increased, the magnetic field builds, strengthening the bind of the particles. The clutch rotor passes through the bound particles, causing drag between the input and the output during rotation. Depending upon the output torque requirements, the output and the input may lock up, and torque transfer can be 100%.
Disengagement: When current/voltage is removed from the clutch, the input is free to turn with the shaft. Since magnetic particle powder is in the cavity, all magnetic particle units have some type of minimum drag associated with them.
Cycling: Cycling is achieved by turning the voltage/current to the coil on and off. Slippage should occur only during acceleration. When the clutch is running, there is no relative slip (if the clutch is sized properly), unless slippage is desired. Torque transfer is 100% efficient.