DE19617867A1 - Speed regulation method for DC and AC electric motors - Google Patents

Abstract

The revs regulation method uses superimposed current and torque regulation, with direct correction of the difference between the actual revs (Nist) and the required revs (Nsoll) by a proportional element (2), compensation of the load moment by a load- dependent pre-control signal (a15) and elimination of the rev disparity by an integral element (4). The load rotation rate (nL) and the load torque (mL) are determined for an oscillatory drive train via an inverse model (23).

Description

The invention relates to a method for overshoot free speed control of DC and AC motors with subordinate current or torque control.

The decisive factors for the control dynamics of a speed control are Rise and settling time of the controlled variable after a speed or a load surge. The control quality comes with a conventional one PI controller still overshooting the speed after a Füh shock and the drop in speed after a load surge (see Buxbaum, Arne / Schierau, Klaus: Calculation of control loops of the Drive technology, 4th edition, AEG-Telefunken AG, Berlin, Frankfurt am Main 1980, pictures 11, 12, 177 and 178).

As is well known, a PI controller combines the quick reaction of a P controller with the correction of an I controller after a fault. The integral component ensures the control deviation is corrected as the difference between the setpoint and the actual value of the controlled variable. Since the integral part of the PI controller changes the Control signal does not allow, is the integration behavior of Integral component cause for the overshoot of the control signal and therefore also the controlled variable.

To find a balance between the overshoot a guide surge and the drop in speed after a load surge to get, the controller is based on the method of symmetrical Optimums set, an overshoot of approx.  40% of the jump in speed after a lead impact (see Buxbaum / Schierau, p. 116 ff.). Should the overshoot be smaller, the controller must be set more slowly, and depending The slower the speed control is - the greater the start-up and Settling time - the greater the drop in speed after a load surge. If the speed overshoot is unacceptable either a speed surge should be avoided (For example, the speed setpoint is sent to a ramp function led) or a very slow speed control is inevitable. However, a slowly set speed controller often has a problem wanted a large drop in speed after a load surge.

The object of the invention is to provide a method mentioned in the introduction ten kind so that an overshoot of the speed actual value after a jump in the speed setpoint is avoided becomes; the control dynamics should be better than one after the PI controller set using the symmetrical optimum method.

According to the invention, this object is achieved by the in claim 1 marked features solved.

Due to the limitation depending on the state of the speed deviation of the output signal of the integral element and the load compensation rende pilot control is advantageously the overshoot of the Ver actual speed value after a jump in the speed setpoint avoided, at the same time by the now easily possible Adjustment of the proportional gain of the speed controller Drop in speed after a load surge can be kept smaller.

Advantageous embodiments of the method according to the invention are characterized in claims 2 to 4.

An example of a circuit arrangement for carrying out the method according to the invention is shown in FIG. 1 as a basic circuit diagram and is explained below: integral behavior is assumed for the mechanical controlled system 15 , the speed control with subordinate current or torque control consists of the modules 1 until 11 . A current or torque regulator is 13 and the electrical path is designated 14 . The difference between the specified speed setpoint n _setpoint and the measured speed _actual value n _actual is formed in a subtractor 1 for the speed deviation Δn, amplified in a proportional element 2 and possibly limited with a limiter 3 , in order then to be present to a summer 10 as the first input signal a3. The _actual speed value n _actual is differentiated in a differential element 7 and then subtracted from the feedback of the subordinate current or torque control in a subtra here 8 (signal a8). With corresponding parameterization of the differential element 7 , in accordance with the mechanical section 15 , the determined value a8 corresponds to the load torque acting on the motor. After smoothing in a low-pass element 9 , a pilot control signal a9 is available to summer 10 as a second input signal. The task of the pilot control signal a9 in the steady state of the controlled system corresponds to the integral part of a PI controller: the subordinate current or torque control loop to specify the compensation component in accordance with the load torque, while the control deviation Δn is virtually zero.

The task of a control part F is to influence the limits of a limiter 5 , which determines the maximum or minimum output variable of an integral element 4 , depending on the state of the speed deviation: they are controlled smaller with increasing speed deviation.

Fig. 2 is, for example, a possible solution for sym metrical control of the upper and the lower limit of the limiter 5 is: better operationalization sake in a block 61, the speed deviation .DELTA.n in its magnitude | .DELTA.n | formed, this is then at the input of blocks 62 and 63 . In block 62 , depending on the amount of the speed deviation | Δn | An output signal a62 is formed in accordance with the curve shape a of FIG. 3: is the speed deviation in the quasi-stationary range (ie if | Δn | becomes smaller than a certain value | Δn * |, which quasi covers the entire range from | Δn | -stationary and a dynamic range under divides), the output signal a62 and the output signal a65 of a block 65 determine the maximum upper limit of the limiter 5 . On the other hand, | Δn | in the dynamic range, signal a62 becomes zero; this closes the limits of the limiter 5 , which suppress the integral part of the speed control.

In order to avoid an abrupt opening and closing of the limits, the transition (quasi-stationary / dynamic) of the curve of the dependent variables a62 is smoothed or at least provided with a ramp function. Blocks 63 to 66 help to avoid the fluttering of the borders. Module 63 acts like a two-point switch with hysteresis. The output signal is

a63 = 1 for | Δn | <| Δn * | and
a63 = 0 for | Δn | <| Δn * | (see curve b of FIG. 3).

Switching back and forth around the switching point | Δn * | is avoided by installing a hysteresis around it. Block 64 is a timer with a switch-on delay function. The value one of the input signal a63 is only available after a delay time T at the output of the module 64 as the signal a64. This avoids an unnecessarily frequent switching in the transition phase quasi-stationary / dynamic (see curves c and d of FIG. 3). In the low-pass filter 65 (for example in the form of a 1st order delay element), the signal a64 is smoothed into the signal a65, which is multiplied by the signal a62 to the signal a66 as the upper limit of the limiter 5 . The lower limit as signal a67 is then obtained by negating signal a66 in module 67 .

In the control part F, the upper and lower limits of the limiter 5 are determined as a function of the state of the speed deviation (dynamic / quasi-stationary). In the dynamic state, ie when the speed deviation lies outside a certain bandwidth, the limits of the limiter 5 are activated, this suppresses the integral part of the speed control (the value of the signal a5 is zero) and thus the overshoot.

With a PI controller, the stability limit depends on the quality of the measured controlled variable (noise, etc.) and on the sampling time of the control if the control works digitally. The stability limit is defined by the smallest possible integration time constant T _I, k at a certain gain _min and to swing by the maximum gain factor k _max at a certain integration time constant T _I, without the speed begins. The limit gain k _{max will} be smaller the smaller the integration time constant T _I is set. In the speed control method presented here, the integral component is suppressed in the dynamic state, which corresponds to an infinitely high integration time constant, which allows the limit gain k _max to be increased without the control system becoming unstable. The increase in gain has an advantageous effect on the control and settling time as well as on the speed change after a load change (ie there is only a smaller drop in speed after a load surge).

Fig. 4 shows the speed curve after a command and a load surge through curve a with a (set by the method of symmetrical optimum) PI controller and through curve b with the speed control method according to the invention.

In the quasi-steady state, when the speed deviation lies within a certain bandwidth, the upper and lower limits of the limiter 5 are opened, so that the integral element 4 can compensate for the control deviation that occurs. The output signal a5 of the block 5 is the third input signal of the sum 10 . The sum of a3, a5 and a9 may be restricted in a limiter 11 . The constant speed of the method presented here reaches the value of a PI controller (down to less than 0.02%, depending on the measuring device).

Claims (4)

1. Process for overshoot-free speed control of DC and AC motors with subordinate current or torque control, characterized in that a deviation of the actual speed value from the setpoint is corrected by a proportional element immediately that the attacking load torque is compensated by a load-dependent pilot control signal and that a speed deviation is corrected by an integral element, the maximum output variable of which is controlled by the state of the speed deviation. 2. The method according to claim 1, characterized in that the Proportional element is connected in parallel with the integral element. 3. The method according to claim 1, characterized in that the Output of the proportional element to the input of the integral link is returned. 4. The method according to any one of claims 2 or 3, characterized records that the maximum output of the integral element a fixed value less than one is limited.