Lenze MC1000 Series User Manual

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13435742_EDBM101_v24

19.4

SET POINT REFERENCE SOURCES

The set point reference input can be one of the following:

1. Keypad

2. 4-20 mA signal at TB-5B

3. 0-10 VDC signal at TB-5A

4. Potentiometer signal at TB-5A
In order to use TB-5A or TB-5B for a set point input, one of the terminals must be

programmed for the appropriate signal. Closing the TB-13 terminal to TB-2 will then

select that signal as the set point reference. If the contact closure is not made to

TB-2, the set point reference source will default to the keypad. See Parameters 47

- TB13A, 48 - TB13B, and 49 - TB13C.
Remote set point reference inputs at TB-5A and TB-5B can only be used if that

terminal is NOT being used for the process feedback signal from a transducer. The

MC1000 has only one analog input of each type, so the same type of signal cannot

be used for transducer feedback and set point reference. For example, a 4-20 mA

signal from a transducer could not be used as a feedback signal if the set point is

being controlled by a 4-20 mA signal from a PLC.

19.5

TUNING THE PID CONTROL

Once the PID control is set up correctly, it needs to be tuned in order to maintain the

process set point. First, set the Integral and Differential Gains to zero, and increase

the Proportional Gain (Parameter 77) until the system becomes unstable, then lower

the gain until the system stabilizes again. Set the Proportional Gain about 15% less

than that value that stabilizes the system. If only Proportional Gain is used, and

the system is operating in a steady-state condition (set point is fixed and process

variable has settled to a fixed value), there will always be a certain amount of error

in the system. This is called the steady-state error.
Integral Gain (Parameter 78) is used to force the steady-state error to zero by

increasing the output speed command with respect to time. Over time, the error

will be forced to zero because the Integral term will continue to change the speed

command, even after the Proportional term reaches steady state and no longer

affects the speed command. The Integral Gain affects the rate of rise of the output

speed command from the Integral term. Small amounts of Integral Gain can cause

large changes in PID performance, so care must be taken when adjusting Integral

Gain. Too much Integral Gain will result in overshoots, especially if large step

changes in error occur.
Typically, Proportional and Integral Gain are all that is needed to fine-tune the

system. However, it may be necessary to use Differential Gain (Parameter 79) to

further stabilize the system, especially when quick responses are required. The

Differential term responds to the rate of change of the error, not the actual error

itself. Differential Gain acts like a “shock-absorber” to dampen overshoots that can

occur when the PID tries to react quickly to changes in error or set point. This allows

fast PID response, with reduced risk of becoming unstable due to overshoots. The

Differential term is very sensitive to electrical noise on the feedback signal and to

digitizing errors, so it must be used with caution.
The other parameter setting that affects the response of the PID control is Parameter

80 - PID ACC. This sets the acceleration (and deceleration) rate of the set point

reference into the PID unit. When the set point changes, this function will “filter” the

input to the PID unit by ramping the set point reference from the previous value to

the new value. This will help prevent overshoots that can occur when the PID control

attempts to respond to step changes in set point, resulting in smoother operation.

If PID ACC is set to 0.0 seconds, it is effectively disabled.