DE102017203990A1 - Method for controlling the speed of a centrifugal pump - Google Patents

Abstract

The present invention relates to a method for controlling the speed of a centrifugal pump operated in an open hydraulic circuit, wherein the controller of the pump control calculates a target speed of the pump drive taking into account a desired and actual head and the actual speed, wherein the controller for the Calculation of the setpoint speed takes into account a correction parameter for describing the geodetic height.

Description

The present invention relates to a method for controlling the rotational speed of a centrifugal pump operated in an open hydraulic circuit, wherein the controller of the pump controller determines a desired rotational speed of the pump drive taking into account a desired and actual delivery head and the actual rotational speed.

Today's prior art variable speed centrifugal pumps use predominantly PI controllers to determine the desired speed. The P component determines how quickly the pump reaches its setpoint. By means of the I component, it is possible to set how dynamically remaining control deviations are to be eliminated. With an I component of zero, there is always a permanent control error.

Since the configuration of both controller parameters influences the dynamics of the overall system, the controller parameters can not be set separately, but only under a holistic view of the system dynamics. In practice, the correct setting of these parameters is therefore an enormous challenge. Also, the classic setting rules for PI or PID controller refer to linear systems, otherwise a linearization must be carried out in advance in one operating point. If the latter is the case, then the controller parameters found are usually optimally set only in the vicinity of the selected operating point.

For the reasons mentioned above, the use of a PI controller for a variable-speed centrifugal pump is not the optimal solution. On the one hand, pumps have a strongly non-linear behavior, on the other hand, pumps must be able to be operated stably in different operating ranges. For example, the operating point when pumping up may be different than during constant pump operation. The setting of the controller parameters of a PI or PID controller is therefore always based on a compromise between these different operating points of the pump.

Due to the problem described above, other approaches have been tested. An example are so-called affinity regulators which operate on the basis of affinity laws. These controller types are considered to be robust, especially in different operating situations, and make obsolete the previously discussed elaborate setting of the controller parameters. A disadvantageous limitation of these types of regulators, however, is that they can only be used in closed hydraulic circuits. In the open circle, where a geodetic height may need to be overcome, the mathematical relationship between the sizes mentioned above changes and the regulation does not lead to a satisfactory result.

It is therefore searched for a suitable controller modification to solve the above problem.

This object is achieved by the method having the features of claim 1. Advantageous embodiments of the method are the subject of the dependent claims.

According to the invention, a method for controlling the rotational speed of a centrifugal pump operated in an open hydraulic circuit is proposed. The basis of the method is a controller of the pump control, which calculates a target speed of the pump drive taking into account a desired and actual delivery and an actual speed. This controller is neither a PI nor a PID controller. The controller modification provides for the extension by at least one correction parameter for the consideration and compensation of a geodetic height to be managed by the pump. Using this correction parameter, the control approach can also be used for open hydraulic circuits.

It is particularly preferred if a displacement of the delivery height-speed curve, in particular a vertical displacement of the delivery height-speed curve, is effected by means of the correction parameter. This makes it easy to compensate for the geodetic height.

The proposed extension of the rule approach is particularly advantageous for those types of controllers that make use of the affinity law for the setpoint or setpoint determination, hereinafter referred to as affinity controllers. According to an advantageous embodiment of the control approach is based on a quadratic relationship between speed and delivery height for the control value calculation. The result is a parabolic control curve, which is selectively shifted up or down by the correction parameter.

Further preferred in such controller types for the desired speed calculation, the quadratic relationship between the setpoint speed and the setpoint conveying height is set in relation to the quadratic relationship between the actual speed and the actual delivery height. Based on this ratio, the target speed can be determined. By inverting the quadratic relationship, the non-linear behavior of the pump can be compensated at the same time. This allows the pump to stabilize like a linear system.

According to a further preferred embodiment of the invention, by the square Relationship between speed and delivery height defined parabola of the control curve shifted by the correction parameter in the coordinate origin, whereby a geodetic height can be compensated either on the pressure or suction side of the pump.

In practice, the correction value depends on the conditions of the entire hydraulic system. Also, the geodetic height and thus the required value of the correction parameter in the current pump operation can change. For this reason, it is desirable that the value of the correction parameter is automatically determined by the pump controller in the current pump mode.

One way to automatically determine the correction parameter is to first assign the correction parameter when commissioning the pump with a definable initial value. A suitable initial value is, for example, the value zero. The required value of the correction parameter for the compensation of the geodetic height can then be determined during operation from the resulting control error, because both the desired delivery height and the actual delivery amount are known to the pump controller. Subsequently, the value of the correction parameter can be adjusted until the desired delivery head is reached.

beschreiben. Der Ausdruck err charakterisiert hier den Fehlerwert, der sich zwischen Soll-Förderhöhe und sich einstellender Ist-Förderhöhe einstellt. Durch Erfassen der Differenz zwischen Soll- und sich einstellender Ist-Förderhöhe ist der Pumpensteuerung demzufolge der aktuelle Fehlerwert bekannt und die Pumpensteuerung kann auf Grundlage der obigen Gleichung den Korrekturwert k berechnen.Mathematically, the determination of the correction parameter k can be determined by means of the following equation $$k=err\cdot {\left(\frac{H_{SOll}}{H_{Ist}}-1\right)}^{-1}$$

describe. The term err characterizes here the error value, which is set between the nominal delivery head and the actual delivery head. Thus, by detecting the difference between the desired and actual delivery head, the pump controller is aware of the current error value and the pump controller can calculate the correction value k based on the above equation.

It is particularly preferred if the determination of the correction parameter takes place regularly, particularly preferably repeated at periodic intervals. This is particularly useful if the geodetic height can change during pump operation. A determination of the correction parameter immediately after initial commissioning is also useful. Alternatively, a determination of the correction value at indefinite random times is appropriate.

In addition to the method according to the invention, the present invention also relates to a centrifugal pump with a pump control for carrying out the method according to the invention. Accordingly, the same advantages and properties arise for the centrifugal pump as have already been discussed in detail above with reference to the method according to the invention. A repetitive description is omitted for this reason.

• 1: eine Drehzahl-Förderhöhenkennlinie im geschlossenen hydraulischen Kreis;
• 2: eine Drehzahl-Förderhöhenkennlinie im offenen hydraulischen Kreis;
• 3: ein Zeit-Förderhöhediagramm zur Verdeutlichung der Regelungsqualität der erfindungsgemäßen Regelung gegenüber konventionellen Regeltechniken.

Further details and advantages of the invention will be explained in more detail below with reference to several figure representations. Show it:

• 1 a speed-elevation characteristic in the closed hydraulic circuit;
• 2 a speed-elevation characteristic in the open hydraulic circuit;
• 3 : a time-delivery height diagram to illustrate the control quality of the control according to the invention over conventional control techniques.

The core idea of the present invention is the use of a novel controller type for the speed control of a centrifugal pump. Unlike in the prior art proposed, is currently not resorted to a PI or PID controller, but instead uses a so-called affinity controller, which relies on the affinity laws for the setting / setpoint determination and therefore of a quadratic relationship between speed and resulting Head of the centrifugal pump runs out.

beschreiben lässt. Zudem ist in der Figurendarstellung der 1 exemplarisch eine Ist-Drehzahl n_ist sowie eine Soll-Drehzahl n_soll angedeutet. Aufgrund des quadratischen Zusammenhangs ist das Verhältnis zwischen den Soll- und Istwerten gemäß der folgenden Gleichung festgelegt: $$\frac{H_{soll}}{H_{ist}}=\frac{n_{soll}^2}{n_{ist}^2}$$

The functional description of this affinity controller is based on the 1 directed. In the diagram, the delivery head is plotted against the set pump speed. The diagram here shows in detail a quadratic relationship between the head H and the rotational speed n, which is expressed by the equation $$H~n^2$$

can describe. In addition, in the figure representation of 1 by way of example, an actual rotational speed _n and a target rotational speed n _soll indicated. Due to the quadratic relationship, the ratio between the setpoint and actual values is determined according to the following equation: $$\frac{H_{sOll}}{H_{ist}}=\frac{n_{sOll}^2}{n_{ist}^2}$$

During operation, setpoint and actual conveying heights are always known. The current actual speed is also known. The setpoint speed ( Control value), the affinity controller calculates according to Eq. 3 as follows: $$n_{sOll}=\sqrt{\frac{H_{sOll}}{H_{ist}}}\cdot n_{ist}$$

In this way, the controller permanently sets the correct nominal delivery height. By inverting the quadratic relationship between head and speed, the non-linear behavior of the pump is compensated and the pump can be stabilized like a linear system. The controller is robust in different operating situations and the complex setting of the controller parameters is eliminated.

A limitation of the affinity controller is that it can be used in the previous embodiment only in closed hydraulic circuits. In the open circle, where a geodetic height has to be overcome, the H / n curve shifts off 1 and the mathematical context changes.

The idea of the present invention is to modify the affinity controller so that it also leads to passable results within an open hydraulic circuit. This is achieved according to the invention by the extensions of the affinity controller by a parameter for describing the geodesic height.

The curve in 2 shows the relationship between head and speed on the assumption that a suction-side geodetic height prevails. Due to the geodesic height, the parabolic curve no longer runs through the coordinate origin, but is shifted downwards by the value k. $$H~n^2-k$$

If a pressure-side geodetic height prevailed, then the curve would be shifted upwards. If the affinity controller applied in its previous form, so would not reach the target head, but a delivery height, which is shifted by an error value (err).

This error (err) can be corrected by taking the relationship from Eq. 1 and Eq. 2 is extended by the parameter k: $$\frac{H_{sOll}+k}{H_{ist}+k}=\frac{n_{sOll}^2}{n_{ist}^2}$$

In this way, the parabola is shifted back to the origin and the calculation of the setpoint speed takes place according to Eq. 6: $$n_{sOll}=\sqrt{\frac{H_{sOll}+k}{H_{ist}+k}}\cdot n_{ist}$$

One challenge is that the geodetic head and thus the necessary parameter k may not be known. Therefore, it is proposed in the context of this idea to determine the parameter k during operation. For this purpose, k is initially assumed to be zero when the controller is switched on. As in 2 shown, the actual delivery height is therefore missed by an error value (err). By detecting the difference between the set and actual actual delivery head through the pump control, the error value (err) is known. By equating Eq. 2 and Eq. 5, the correction value k can be determined based on the error value. $$k=err{\left(\frac{H_{sOll}}{H_{ist}}-1\right)}^{-1}$$

The determination of k takes place regularly in pump operation, since the geodetic head can change during operation.

3 shows a test result with three different controller types. The tested controlled system is a pump that has to overcome a geodetic head. As a controller, a PI controller, a conventional affinity controller and an affinity controller with the extension according to the invention are tested for the correction parameter. The desired nominal delivery height is the lowest for all controller types 5 m.

3 represents a time diagram of the actual delivery head set by the individual controller types. The curve 2 The conventional affinity controller without correction of the geodetic height initially shows a very strong overshoot, due to the iterative correction of the deviation, the target head is still achieved. The PI controller with the curve 3 also reaches its setpoint, but this result requires a lot of effort in properly setting the controller parameters. The curve 1 the affinity controller with consideration of the geodetic height shows the best result. There is no overshoot, no permanent control deviation and the target head is reached quickly. In addition, it is not necessary to set controller parameters. As a result, a high stability of the controller is ensured even with a changing performance.

Claims (10)

Method for controlling the speed of a centrifugal pump operated in an open hydraulic circuit, wherein the controller of the pump control determines a desired speed of the pump drive taking into account a desired and actual delivery and the actual speed, characterized in that the controller for calculating the Target speed takes into account a correction parameter for describing the geodetic height. Method according to Claim 1 , characterized in that the controller for the control value determination is based on at least components of the affinity law, in particular assumes a quadratic relationship between rotational speed and delivery head for the manipulated variable calculation. Method according to Claim 2 , characterized in that the controller determines the desired rotational speed from the ratio of the quadratic relationship between the target rotational speed and the nominal delivery head and the quadratic relationship between the actual rotational speed and the actual delivery head. Method according to Claim 2 or 3 , characterized in that the parabola defined by the quadratic relationship is shifted by the correction parameter into the origin of the coordinates. Method according to one of the preceding claims, characterized in that the value of the correction parameter in the current pump operation is determined. Method according to Claim 5 , characterized in that the correction parameter is assigned at startup of the pump with a known initial value, in particular assumes the value zero. Method according to Claim 5 or 6 , characterized in that the correction parameter in the current pump operation from the control error, in particular the difference between the desired and actual delivery is derived. Method according to Claim 7 , characterized in that the correction parameter by means of the equation $k=err\cdot {\left(\frac{H_{sOll}}{H_{ist}}-1\right)}^{-1}$

is calculated. Method according to one of the preceding Claims 5 to 7 , characterized in that the determination of the correction parameter during pump operation at first commissioning and / or regularly takes place at periodic intervals and / or random. Centrifugal pump with a pump control for carrying out the method according to one of the preceding claims.

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