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MG.10.J8.02 – VLT is a registered Danfoss trade mark
Programmable SyncPos motion controller
2. A closed-loop PID control. The PID controller
monitors the difference between the actual
position and the setpoint position. Based on
this information it calculates a control signal to
minimize the position deviance. Thus the
SyncPos option is able to compensate for
changes in load or friction. The PID controller is
also necessary to compensate for any position
deviance caused by inaccurate setting of the
open-loop feed-forward controller.
In short: The feed-forward control is used to handle
changes in the setpoint reference (especially impor-
tant in synchronization applications), while the PID
control is used to handle changes in load conditions
or inaccuracies of the feed-forward control.
Proportional factor KPROP (11)
The
Proportional factor
Proportional factor
Proportional factor
Proportional factor
Proportional factor
is multiplied with the posi-
tion deviance and the result is added to the con-
trol signal (the internal speed-reference to the VLT).
Since the calculated control signal is proportional
to the position deviance (or error) this kind of con-
trol is called proportional control. The behavior of
the proportional control is similar to that of a spring
– the further the spring is extended the stronger
the counter-force it produces.
Influence of the Proportional factor
Proportional factor
Proportional factor
Proportional factor
Proportional factor:
KPROP too small large position deviation due to
non-compensatable load and
frictional moment;
KPROP larger
quicker reaction, smaller
steady-state deviation, larger
overshoot, lesser damping;
KPROP too great heavy vibrations, instability.
Derivative factor KDER (12)
The
Derivative factor
Derivative factor
Derivative factor
Derivative factor
Derivative factor
is multiplied with the deriva-
tive of the position deviance (the 'velocity' of the
position deviance) and the result is added to the
control signal. The behavior of the derivative con-
trol is similar to that of an absorber – the faster the
absorber is extended the stronger the counter-
force it produces. Thus using the
Derivative factor
Derivative factor
Derivative factor
Derivative factor
Derivative factor
increases damping in your system.
Influence of the Derivative factor
Derivative factor
Derivative factor
Derivative factor
Derivative factor:
KDE R small
no effect;
KDER larger
better dampening, lesser over-
shoot; if KPROP is increased
simultaneously: faster reaction
to control deviation at the same
level of vibration;
KDER too large
heavy vibrations, instability.
Integral factor KINT (13)
The sum of all error is calculated every time the
control signal is updated. The
Integral factor
Integral factor
Integral factor
Integral factor
Integral factor
is
then multiplied with the sum of all positioning
errors and added to the overall control signal. Thus
in case that steady-state position errors occurs in
your application, make sure you use the integral
part of the controller. Steady-state errors will be
levelled out as the summed error increases over
time until the control signal eventually matches the
load.
It is possible to set a limit for the control signal
generated by the integral part of the controller
(anti-windup).
Influence of the Integral factor
Integral factor
Integral factor
Integral factor
Integral factor:
KINT very small
steady-state position deviance
is very slowly regulated to zero;
KINT larger
faster regulation towards zero
steady-state position deviance,
larger overshoot;
KINT too large
heavy vibrations, instability.
Integration limit KILIM (21)
The
Inte
Inte
Inte
Inte
Inte gration limit
gration limit
gration limit
gration limit
gration limit
sets a limit for the control sig-
nal generated by the integral part of the controller.
This helps to prevent the so called 'wind-up' pro-
blems which typically occurs in applications where
the overall control signal (the internal speed-refe-
rence) is maxed out for long periods of time.
This feature is also very helpful in applications where
the power to the motor is turned off and on while the
option card is controlling the VLT. Cutting of power to
the motor (by setting terminal 27 low) while little posi-
tioning deviance is present in the controller, could
result in an enormous control signal being generated
once the power is turned back on.
Velocity Feed-forward FFVEL (36)
The
V
V
V
V
Velocit
elocit
elocit
elocit
elocity feed
y feed
y feed
y feed
y feed ----- forward
forward
forward
forward
forward
factor is a scaling factor
that is multiplied with the derivative of the setpoint
position (the velocity of the setpoint). The result of
this operation is added to the overall control signal.
This feature is especially useful in applications
where there is a good correlation between the
control signal (the VLT speed reference), and the
speed of the motor. This is indeed the case with
most applications using an asynchronous motor.
N B!
The scaling of the FFVEL parameter is de-
pendent on the correct setting of the maxi-
mum reference (VLT parameter #205) as well as
the SyncPos parameters VELMAX (1) and
ENCODER (2).
Optimizing the P
ID contr
oller
