Advanced" Parameter Group - Eaton Cutler Hammer PowerXL DC1 E1 Series Parameter Manual

5 Parameters

5.4 "Advanced" parameter group

5.4 "Advanced" parameter group
Parameter Designation
P-60 Motor Control Mode
P-61 Motor Identification
P-62 MSC Gain
P-63 I-CurrentLimit
P-64 Motor Stator Resistance
R1
P-65 Motor Stator Inductance
d-Axis
P-66 Motor Stator Inductance
q-Axis
P-67 f-DCBrake@Stop
P-68 DC-Brake Current
46
Table 27: "Advanced" parameter group
Min. value Max. value
0 4
0 1
0.00 % 200.00 %
0.10 % 175 %
0.00 Ohm 655.35 Ohm
0.0 mH 6553.5 mH
0.0 mH 6553.5 mH
0.0 Hz P-01
0.0 % 100.0%
DC1...E1 Variable Frequency Drives 11/16 MN040022EN www.eaton.com
Description
Motor Control Mode
An autotune must be performed if setting 2 up to 4
is used. It is recommended with setting 0
0: Speed Control with Torque Limit (vector)
1: Speed Control (V/f)
2: PM Motor Speed Control
3: Brushless DC Motor Speed Control
4: SyncRel Motor Speed Control
Motor Identification
When set to 1, the drive immediately carries out a
non-rotating autotune to measure the motor
parameters for optimum control and efficiency.
Following completion of the autotune, the
parameter automatically returns to 0.
Speed controller Gain for Kp and Ti as combined
value
Current limit in amperes x 10, one decimal place
Stator resistance of the motor
For induction and PM motors: phase to phase
resistance value [Rs] in Ohms. This value is
determined during the motor identification run.
Stator inductance of the motor, torque producing
For induction motors: Phase to phase inductance
value in Henry [H]
For PM-Motors: phase d-axis inductance value
[Lsd] in Henry [H]
Stator inductance of the motor, magnetizing
For PM-Motors: phase d-axis inductance value
[Lsd] in Henry [H]
Output frequency in Hz at which DC braking starts
during the deceleration phase.
If "Stop Mode" is set to coasting, DC braking starts
at stop command immediately.
Amount of DC current as a percentage of the
"Motor Nom Current" that is injected into the
motor during DC braking.
DS
1
0
50.00 %
150 %
f(I )
e
f(I )
e
f(I )
e
0.0 Hz
20.0%