High Torque Large Magnetic Particle Brake
High Torque Large Magnetic Particle Brake
SKU:LAR-c35c7d
Precise and powerful magnetic particle brake for industrial torque control
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$849.99
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$849.99
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High Torque Large Magnetic Particle Brake
$849.99
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High Torque Large Magnetic Particle Brake
$849.99
Quantity: 1
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The High Torque Large Magnetic Particle Brake is a powerful solution designed for precise torque control in industrial applications. With a torque range of 4 to 140 lb-ft and slip heat dissipation of 350 to 500 W, this self-contained brake offers reliable and repeatable performance. Ideal for tension control, load simulation, and soft stops, it ensures smooth operation even under varying torque conditions. The hollow shaft configuration and maximum speed of 500 rpm make it versatile for a range of setups, while its robust build guarantees longevity and efficiency.
Product Specifications
Characteristics Characteristics
With no electrical excitation, the shaft freely rotates.With electrical excitation, the shaft becomes coupled to the case.While the load torque is less than the output torque, the shaft wonât rotate.When the load torque is increased, the brake will slip smoothly at the torque level set by the coil input current.
Determining Proper Brake Size Determining Proper Brake Size
Determining Proper Brake SizeThe proper sized brake mustâ¦Have sufficient torqueBe able to dissipate the heatNo run above rated speedTorqueFor load simulation, torque limiting and similar applications, torque is already known.For web handling, torque must be calculated. First determine the desired tension in your web (wire, fabric, film etc.).Calculate Torque: Torque (lb-inches) = Tension (lbs) x Roll Diameter (inches) x 0.5Use the Full Roll Diameter for calculating the maximum torque needed. For applications with the web running over a pulley or between nip rollers (pinch rollers), use the pulley diameter as the roll diameter in the formula above. Always be conservative - select the next larger model if the application requires nearly the rated torqueRPM (must be less than the maximum allowable)For load simulation, torque limiting and similar applications, RPM is already known.For web handling, usually linear speed (Web Speed) is known, and RPM must be calculated.Calculate RPM: RPM = 3.8 x WEB SPEED (feet per minute)/ROLL DIAMETER (inches)Use the Full Roll Diameter to determine the slowest speed. Use the Core Diameter (empty spool diameter), to determine the fastest speed. For applications with the web running over a pulley or between nip rollers (pinch rollers), use the pulley diameter as the roll diameter.Slip Heat Dissipation (model must be physically large enough not to overheat)For any application.Calculate Heat Input: HEAT (watts) = TORQUE (lb-inches) x RPM x 0.012For unwinding applications.Calculate Heat Input: HEAT (watts) = WEB TENSION (lbs) x WEB SPEED (feet/minute)/44Duty CycleThe average heat input must be below the brake's heat dissipation rating. If the motion is intermittent, use the average speed for thermal (SLIP) calculations.
Note Note
Mounting holes - Standard: Imperial (inch), Optional: Metric
Specifications Available Direct Current Dc Coil Voltage
24 V
Specifications Configuration
Hollow shaft
Specifications Current
2.4 A
Specifications Maximum Overhung
200 lb | 890 N
Specifications Maximum Speed
500 rpm
Specifications Resistance
8.2 Ω
Specifications Slip Heat Dissipation
350 to 500 W
Specifications Torque Range
4 to 140 lb·ft | 6 to 190 N·cm
Specifications Weight
62 lb | 28.1 kg
Torque Torque
Is proportional to input current.Is independent of RPM.
Applications Applications
Adjustable tension - for unwinding (payout) webs.Load simulation - for testing stepper motors, gear motors and mechanisms.Torque limitingSoft stops.