Stepper motor inductance is a crucial parameter that influences motor performance. Its primary functions are as follows:

1. Energy Storage

When voltage is applied to the motor, the inductance stores energy, generating a magnetic field. Upon voltage removal, the inductance releases energy, sustaining the magnetic field's decay for a period.

• Limiting Current Change Rate
• Impacting Motor Response Speed
• Influencing Motor Heat Generation

Inductance impedes abrupt current changes. According to Lenz's law, when current changes, the inductance generates a counter-electromotive force (CEMF) that opposes the current change. This is essential for stepper motor control as the motor requires rapid current direction changes to achieve stepping motion.

Inductance reduces the motor's response speed to control signals. This is because the inductance takes time to store and release energy. For high-speed applications, choose motors with lower inductance to enhance response speed.

Inductance increases the motor's copper losses, leading to heat generation. Therefore, consider inductance value and ambient temperature when selecting motors to prevent overheating and damage.

How to Select Proper Stepper Motor Inductance

Stepper motor inductance selection involves considering several factors:

1. Motor Speed

For high-speed applications, choose motors with lower inductance to improve response speed.

• Motor Load
• Ambient Temperature
• Control Method

For heavier loads, select motors with higher inductance to achieve greater torque.

For high ambient temperatures, choose motors with lower inductance to reduce heat generation.

For control methods requiring rapid current direction changes, select motors with lower inductance.

Generally, stepper motors with inductance values between 0.5mH and 5mH are suitable for most applications. If you have any questions regarding inductance value selection, consult the motor manufacturer or the motor driver's technical support.

Summary

Stepper motor inductance is a critical parameter affecting motor performance. Choosing the appropriate inductance value is essential for ensuring proper motor operation. When selecting inductance, consider factors such as motor speed, load, ambient temperature, and control method.