Difference between revisions of "Essential Basics"

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#* Digital servo drives are practically sophisticated switching step-down voltage regulators, and the torque controller takes care that the current to the motor (and thus the voltage) is correct.
 
#* Digital servo drives are practically sophisticated switching step-down voltage regulators, and the torque controller takes care that the current to the motor (and thus the voltage) is correct.
 
#* The HV can be at least five times the nominal motor voltage without any issues and reduced performance.
 
#* The HV can be at least five times the nominal motor voltage without any issues and reduced performance.
# The maximum current to the motor is not the maximum current of the PSU
+
# The maximum current to the motor is not the maximum current rating of the PSU
 
#* Considered as a step-down regulator, the digital servo drive transfers power, not current to the motor. Because of this, the PSU's current rating affects maximum power that can be driven into a motor, not maximum current.
 
#* Considered as a step-down regulator, the digital servo drive transfers power, not current to the motor. Because of this, the PSU's current rating affects maximum power that can be driven into a motor, not maximum current.
#* E.g. 48 V PSU with 10 A current rating can output 480 W power. If the required voltage to a motor to drive 24 A current is 20 V, the transferred power is the same what the PSU can supply.
+
#* In ideal world, e.g. 48 V PSU with 10 A current rating can output 480 W power. If the required voltage to a motor to drive 24 A current is 20 V, the transferred power is the same what the PSU can supply.
 
# Encoder <b>must</b> be attached directly to the motor shaft
 
# Encoder <b>must</b> be attached directly to the motor shaft
#* In practice, all gears and other similar mechanics have non-idelities such as play, torsion, and/or possibility of slipping.
+
#* In practice, all gears and other such mechanics have non-idelities such as play, torsion, and/or possibility of slipping.
 
#* Play and torsion will introduce delay to the feedback loop, and will cause oscillation due to which the tuning is impossible to get precise.
 
#* Play and torsion will introduce delay to the feedback loop, and will cause oscillation due to which the tuning is impossible to get precise.
#* Slipping encoder will cause false angle data, which will cause the motor to either stall or run loose.
+
#* Slipping encoder will give false data, which will cause the motor to either stall or run loose.
#* Encoder resolution must be exact for each rotation. Rounded data will also cause the magnetic angle to be lost, and the motor will stall or run loose after few turns.
+
#* Encoder resolution must be exact for each rotation. Rounded data will also cause the known magnetic angle to be lost, and the motor will stall or run loose after few turns.
 
# Torque tuning must be done properly
 
# Torque tuning must be done properly
 
#* Poor torque tuning will result in excessive current spikes and at worst mechanical oscillation
 
#* Poor torque tuning will result in excessive current spikes and at worst mechanical oscillation

Revision as of 11:57, 25 July 2018

These basics are the most fundamental steps to get a motor running in order for an application to work properly.

  1. Motor supply voltage (HV) can be higher than nominal motor voltage
    • Digital servo drives are practically sophisticated switching step-down voltage regulators, and the torque controller takes care that the current to the motor (and thus the voltage) is correct.
    • The HV can be at least five times the nominal motor voltage without any issues and reduced performance.
  2. The maximum current to the motor is not the maximum current rating of the PSU
    • Considered as a step-down regulator, the digital servo drive transfers power, not current to the motor. Because of this, the PSU's current rating affects maximum power that can be driven into a motor, not maximum current.
    • In ideal world, e.g. 48 V PSU with 10 A current rating can output 480 W power. If the required voltage to a motor to drive 24 A current is 20 V, the transferred power is the same what the PSU can supply.
  3. Encoder must be attached directly to the motor shaft
    • In practice, all gears and other such mechanics have non-idelities such as play, torsion, and/or possibility of slipping.
    • Play and torsion will introduce delay to the feedback loop, and will cause oscillation due to which the tuning is impossible to get precise.
    • Slipping encoder will give false data, which will cause the motor to either stall or run loose.
    • Encoder resolution must be exact for each rotation. Rounded data will also cause the known magnetic angle to be lost, and the motor will stall or run loose after few turns.
  4. Torque tuning must be done properly
    • Poor torque tuning will result in excessive current spikes and at worst mechanical oscillation
  5. Testing motor and encoder wiring in torque mode
    • Before velocity or position tuning, the system must be tested without any load in torque mode to ensure proper functionality.
    • Follow the instructions here: Servo motor torque mode test