4 method of operation – Siemens SIPART PS2 6DR52xx User Manual

Design and Functional Principle

23

SIPART PS2 Manual

A5E00074631--06

2.4 Method of Operation

The electropneumatic positioner SIPART PS2 forms a control circuit

with the pneumatic actuator in which the actual value x is the position

of the actuator bar in linear actuators or the position of the actuator

shaft in part-turn actuators and the command variable w is the

actuating current of a controller or a manual control station of 4 to

20 mA.
The stroke or part-turn movement of the actuator is transferred by the

appropriate mounting accessories, the feedback shaft and a play-free

switchable gearwheel to a high quality conductive plastic potentiometer

and to the analog input of the microcontroller. The current position can

also be preset for the positioner via an external sensor. The detection

of the stroke or rotation andle is performed by a non-contacting posi-

tion sensor (Non Contacting Position Sensor) directly at the actuator.
This may correct the angle error of the stroke tap, compares the

potemtiometer voltage as actual value x with the setpoint w fed in at

the terminals 3 and 7 and calculates the manipulated variable

increments Δy. Depending on the size and direction of the control

error (x-w) the piezo-controlled supply air or exhaust air valve is

opened. The volume of the actuator integrates the positioning

increments to actuating pressure y open which moves the actuator bar

or actuator shaft approximately proportionally. These positioning

increments change the actuating pressure until the control error

becomes zero.
The pneumatic actuators are available in single and double-acting

versions. Only one pressure chamber is aerated or deaerated in the

single-acting version. The resulting pressure operates against a spring.

In the double-acting version, two pressure chambers are counteractive.

In this case the one volume is deaerated when the other volume is

aerated. See the block diagram figure 2-10, page 25.
The control algorithm is an adaptive predictive five-point switch

(see figure 2-9, page 24).
The valves are controlled with continuous contact at large control errors

(fast step zone). At medium control errors the valve is controlled by

pulse length modulated pulses (short step zone).
No actuating pulses are output in the small control error zone (adaptive

dead zone). The dead zone adaptation and the continuous adaptation

of the minimum pulse lengths in automatic operation cause the best

possible control accuracy to be achieved at the lowest switching fre-

quency. The start parameters are determined during the initialization

phase and stored in a non-volatile memory. These are basically the real

travel with the mechanical limit stops, the travel times, the size of the

dead zone etc.
In addition the number of fault messages, changes in direction and the

number of strokes are determined and stored every 15 minutes during

operation. These parameters can be read out and documented by the

communication programs such as PDM and AMS. Conclusions as to

the wear on the fitting can be drawn (diagnostic function) especially by

comparing the old value with the currently determined values.