Function
Parameter no.
Setting
Selection of Motor Control Principle
1-01 Motor Control
Principle
[3] Flux w motor feedb
5) Configure and scale the reference to the Speed Control
Set up Analog Input 53 as a reference Source
3-15 Reference
Resource 1
Not necessary (default)
Scale Analog Input 53 0 RPM (0 V) to 1500 RPM (10 V)
6-1*
Not necessary (default)
6) Configure the 24V HTL encoder signal as feedback for the Motor Control and the Speed Control
Set up digital input 32 and 33 as encoder inputs
5-14 Terminal 32
Digital Input
5-15 Terminal 33
Digital Input
[0] No operation (default)
Choose terminal 32/33 as motor feedback
1-02 Flux Motor
Feedback Source
Not necessary (default)
Choose terminal 32/33 as Speed PID feedback
7-00 Speed PID
Feedback Source
Not necessary (default)
7) Tune the Speed Control PID parameters
Use the tuning guidelines when relevant or tune
manually
7-0*
See the guidelines below
8) Finished!
Save the parameter setting to the LCP for safe keeping
0-50 LCP Copy
[1] All to LCP
Table 4.18 Speed Control Settings
4.4.3 Tuning PID Speed Control
The following tuning guidelines are relevant when using
one of the Flux motor control principles in applications
where the load is mainly inertial (with a low amount of
friction).
The value of
30-83 Speed PID Proportional Gain
is
dependent on the combined inertia of the motor and load,
and the selected bandwidth can be calculated using the
following formula:
Par. 7 − 02 = Total inertia kgm
2 x par. 1 − 25
Par. 1 − 20 x 9550
x Bandwidth rad / s
NOTE
1-20 Motor Power [kW]
is the motor power in [kW] (i.e.
enter ‘4’ kW instead of ‘4000’ W in the formula).
A practical value for the Bandwith is 20 rad/s. Check the
result of the
30-83 Speed PID Proportional Gain
calculation
against the following formula (not required if you are
using a high resolution feedback such as a SinCos
feedback):
Par. 7 − 02MAX =
0.01 x 4 x Encoder Resolution x Par. 7 − 06
2
x π
x Max torque ripple %
A good start value for
7-06 Speed PID Lowpass Filter Time
is
5 ms (lower encoder resolution calls for a higher filter
value). Typically a Max Torque Ripple of 3 % is acceptable.
For incremental encoders the Encoder Resolution is found
in either
5-70 Term 32/33 Pulses per Revolution
(24V HTL on
standard drive) or
17-11 Resolution (PPR)
(5V TTL on
MCB102 Option).
Generally the practical maximum limit of
30-83 Speed PID
Proportional Gain
is determined by the encoder resolution
and the feedback filter time but other factors in the
application might limit the
30-83 Speed PID Proportional
Gain
to a lower value.
To minimize the overshoot,
7-03 Speed PID Integral Time
could be set to approx. 2.5 s (varies with the application).
7-04 Speed PID Differentiation Time
should be set to 0 until
everything else is tuned. If necessary finish the tuning by
experimenting with small increments of this setting.
4.4.4 Process PID Control
The Process PID Control can be used to control application
parameters that can be measured by a sensor (i.e.
pressure, temperature, flow) and be affected by the
connected motor through a pump, fan or otherwise.
shows the control configurations where the
Process Control is possible. When a Flux Vector motor
control principle is used, take care also to tune the Speed
Control PID parameters. Refer to the section about the
Control Structure to see where the Speed Control is active.
Application Examples
VLT
®
Decentral Drive FCD 302
MG04H102 - VLT
®
is a registered Danfoss trademark
55
4
4