DE4337614A1 - Differential-pressure control for a pump system - Google Patents

Abstract

The invention relates to a circuit arrangement for the differential-pressure control of a pump system. This pump system is driven by a single-phase capacitor with a main winding and an auxiliary winding, in which case several operating points for reducing the motor output can be set by connecting the auxiliary winding or its sectional windings. According to the invention, both the actual value of the main-winding current and the actual value of the main-winding voltage are fed to an adding circuit, which in turn has an integrator connected downstream of it. The output signal of the integrator is compared with threshold values and, as a function of the results of the comparison, sectional windings of the auxilliary winding are connected ahead of the main winding or the sectional windings are separated from the main winding in order to thereby keep the differential pressure in the pump system constant.

Description

The invention relates to a circuit arrangement for Differential pressure control one from a single-phase con pump motor driven by the capacitor according to the Ober Concept of claim 1.

Such circuit arrangements for differential pressure control are used for example in heating systems where where the capacitor motor works as a pump motor. There the pump medium in a closed system rotates, the pump motor must be regulated so that the differential pressure of the system even with difference Lich flow remains approximately constant.

In a known circuit arrangement according to DE-OS 40 31 709 becomes the one flowing through the main winding Current as well as the occurring on this main winding Voltage drop detected as actual value and by forming the quotient of these two actual values Main winding impedance proportional third ter actual value generated. This third actual value is with compared to a reference voltage and dependent integrated this comparison positively or negatively. Of the resulting rising or falling chip The course of the development is then shown using comparators evaluates this voltage curve with each of these Compare reference voltages supplied to comparators chen. Depending on this comparison, the control  Comparators a locking logic, which in turn controllable switch controls so that a partial winding is connected to the main winding or ge is separated, which either increases engine performance or is degraded. The engine delivers its maximum performance when the main winding directly on the Mains voltage is present.

A disadvantage of this known circuit arrangement be is that a divider to form the quo It is very difficult to compare the actual values mentioned is and also causes high costs.

The object of the invention is a scarf specify the arrangement of the type mentioned at the beginning, which is a good matchability during manufacturing leaves and is inexpensive to produce.

This task is carried out according to the characteristic features of claim 1 solved. After that a Dif reference between the first actual value and the second actual worth formed by the first positively rectified an adder circuit and the second negative aligns the adder circuit is supplied. At the end Gang this adder circuit is an integrator closed, the output signal with at least one Threshold value is compared. Depending on the ver the partial result of the auxiliary winding upstream of the main winding as a choke or separate this partial winding from the main winding, to keep the differential pressure constant nen. Thus, the divider is replaced by the State of the art according to DE-OS 40 31 709 described above just an adder circuit, where only to invert the actual value for the main winding current is. This leads to an easier and therefore cost  cheaper construction and also leaves a simple Adjustment to.

An improvement of the rule property is with one Embodiment of the invention achieved in that a third actual value is generated, the value of which is propor tional to the winding temperature of the main and auxiliary is winding. This actual value also becomes the adder circuit fed.

Furthermore, the offset compensation is used Control property improved by according to another advantageous embodiment, a fourth actual value is generated with an adjustment of the shift points, i.e. switching to a different power stage of the engine is achieved.

Furthermore, in another advantageous embodiment the circuit complexity is reduced, that instead of an adder and an integra tors a sum integrator is used.

Preferably the comparison between the output signal of the integrator or the sum integrator and the threshold value using at least one comparator carried out. These comparator signals become one Logic circuit fed and processed by it. For Switching the partial winding on and off is controlled Switches, preferably provided by the triacs Logic circuit can be controlled.

For better synchronization of the controlled switches a current zero crossing detector is provided, the the signal indicating the current zero crossing also the Logic circuit is supplied.  

A resistance bank is provided for offset compensation see their resistors each via a switch ver with the adder circuit or the sum integrator can be bound. These switches are preferred trained as an analog switch and are by the Logic circuit controlled.

Finally, at a last advantageous out embodiment of the invention as an operating voltage source for the circuit arrangement one to one "floating" zero potential symmetrical voltage he testifies. This leads to a simple structure of the network part.

In the following, the invention is based on an embodiment Example in connection with the drawings are shown and explained. It shows:

Fig. 1 is a block diagram of a voltage Ausführungsbeispie les of the present invention Schaltungsanord,

Fig. 2 is a circuit diagram of the adder and the Integra tors according to Fig. 1,

Fig. 3 is a detailed circuit diagram of the power supply according to Fig. 1 and

FIG. 4 shows a detailed circuit diagram of a further power supply unit according to FIG. 1.

Fig. 1 shows a circuit arrangement for Steue tion of a pump motor, as the single-phase capacitor motor, a main winding L1, has an auxiliary winding L2 and a starting capacitor C. Here, a series circuit comprising the main winding L1, a shunt resistor R _s and a triac T4 is connected in parallel to the starting capacitor C, the connection point of the triac T4 with the shunt resistor R _{s being} at the reference potential of the circuit. The latter parallel circuit is connected on the one hand to the neutral conductor N of an AC network and on the other hand is connected to the phase R, that is to 220 V, via the auxiliary winding L2.

The auxiliary winding L2 is equipped with two taps N1 and N2, each of which is connected via a triac T2 and T3 to the circuit branch which is at reference potential and connects the shunt resistor R _s to the triac T4. A fourth triac T1 connects the circuit branch he mentioned directly to the phase R of the AC network, which means that when the triac T1 is switched on, the series circuit from the main winding L1 and the shunt resistor R _{s is} supplied with 220 V. This represents an operating state of the capacitor motor, where it is operated at its highest speed and thus has reached its highest performance level. In contrast, if only the triac T2 or T3 is turned on, a partial winding L2a or L2b of the auxiliary winding L2 is connected in series with the main winding L1, so that this partial windings develop a throttling effect. Finally, with the triac T4 switched on, the entire auxiliary winding L2 is connected in series with the main winding L1 via the shunt resistor R _s , so that the entire auxiliary winding L2 acts as a choke.

Thus, through this optional connection of partial windings of the auxiliary winding or the entire auxiliary winding, four operating points of the capacitor motor can be set, which differ in the same operating voltage due to different pump outputs. A gradual reduction in power is thus achieved by connecting the auxiliary windings L2a or L2b until the lowest power level is reached when the entire auxiliary winding L2 is switched on. The triacs T1 to T4 are controlled by a control unit 5 , which are each switched at the zero crossing of the main winding current I _H. The trigger pulses required for this are generated by a current zero crossing detector 9 , which is connected to the circuit branch connecting the shunt resistor R _s to the main winding L1. By using the zero current instead of the zero crossing of the operating voltage of the motor, an improvement in the synchronization is achieved.

The tapped at the aforementioned circuit branch voltage potential corresponds to the voltage drop of the shunt resistor R _s, which for generating a Istwer tes I _is the main winding current I _H of a rectifying terschaltung is supplied. 1 This actual value I _ist is fed to an adding circuit 3 .

In order to produce an actual value of U _is the main winding voltage U _H is the connected to the neutral conductor N end of the main winding L1 with a scarf rectifier device 2 connected, whose output signal as actual value U _is also forwarded to the adder circuit. 3

Since the windings heat up during operation of the capacitor motor, this leads to an increasing winding resistance, which in turn leads to a decrease in the power of the motor. To compensate for an increase in temperature, an NTC resistor is therefore arranged in the electronics, which _supplies an actual value U _{temp of} the winding and is likewise supplied to the adder circuit 3 .

Finally, a fourth actual value U _{offset of} the adder circuit 3 is supplied, which is generated by means of a resistance bank 7 , consisting of four resistors R1 to R4, by using a switch S _i = 1, 2, 3, 4 associated with each resistor the adding circuit 3 can be connected, these switches S1 to S4 being controllable by the control unit. The function of the resistance bank 7 consists in the correction of offset errors and will be described in more detail below.

The adding circuit 3 is an integrator 4 downstream, which integrates the sum signal generated by the adding circuit. This integrated sum signal of the integrator 4 is fed to three comparators K1, K2 and K3, which are designed as Schmitt triggers. Each comparator K1, K2 and K3 is supplied with a reference voltage U₁, U₂ and U₃, the comparator K1 having the highest reference voltage U₁ and the comparator K3 having the lowest reference voltage U₃. These reference voltages U₁ to U₃ are generated by means of four resistors R5 to R8 connected in series. These comparators K1 to K3 now compare the output voltage of the integrator 4 supplied to them with their own reference voltage. These comparators K1 to K3 each generate one of two logic levels at their outputs, namely an L or an H level. Depending on the position of the output voltage of the integrator 4 compared to the three reference voltages U₁ to U₃, these comparators K1 to K3 output a digital word which is supplied to the control unit 4 for processing. This control unit 5 controls the triacs T1 to T4 so that only one triac is switched through.

In order to be able to set these switchover points precisely, the control unit 5 closes a specific switch S _{i of} the resistance bank 7 at each operating point of the capacitor motor, as a result of which a specific resistor R _{i is} connected to the adder circuit 3 in order to thereby offset a specific offset voltage signal produce. Since four operating states are provided, a resistor can be assigned to an operating point via the assigned switch.

The circuit arrangement according to FIG. 1 can also be operated by means of a remote control 11 , in that the output signal from the integrator 4 is supplied with an external voltage U _ext . As a result, the actual value which is decisive for the comparators is changed, with the result that a different differential pressure is established, which must now be regulated constantly.

FIG. 2 shows a sum integrator 8 , which is used instead of the adder circuit 3 and the integrator 4 according to FIG. 1. Such a structure can be implemented with a few components, is easy to adjust and therefore leads to an inexpensive circuit. The summa tion integrator 8 contains an operational amplifier OP with a capacitor C1, which connects its inverting input to the output. The actual values I _ist , U _ist and U _{emp of} the main winding _current, the main winding voltage and the temperature are each fed via a resistor R9, R10 or R11 to the inverting input of the operational amplifier OP. This input is also acted upon by the offset voltage U _offset generated with the resistance bank 7 . Finally, the non-inverting input of this operational amplifier OP is placed on the reference potential, that is, on the floating zero point of the operating voltage source of the circuit arrangement, while the input of the operating voltage source is supplied via a resistor R 12 with the positive pole V _DD .

The power supply 10 of FIG. 1 generated from the AC 220 V symmetrical to a floating zero operating voltage V _DD and V _SS. This offers the advantage that the zero point can be either potential-related to N or L or to intermediate values and still a supply current can be taken in all positions of the zero point.

The circuit of such a power supply 10 is shown by way of example in FIG. 3, which contains a bridge circuit comprising two diodes D1 and D2 and two Zener diodes D3 and D4. A bridge point of this bridge circuit lies in each case via a series circuit comprising a capacitor C2 and a resistor R13 or a capacitor C3 and a resistor R14 at the potential of the phase R or the neutral conductor N, while the opposite bridge point forms the floating zero point. The positive or negative operating voltage V _DD or V _SS is available at the other two jumper points. Finally, two smoothing capacitors C4 and C5 are provided, which are each connected in parallel to the Zener diodes D3 and D4.

Fig. 4 shows the circuit diagram of another network part, which has a bridge rectifier 11 instead of that of FIG. 3 instead of the two diodes D1 and D2. The other components of this circuit correspond to those of FIG. 3. According to FIG. 4, the two capacitors C2 and C3 are not connected, but are each led to the input of the bridge rectifier 11 . A higher current can be supplied with this alternative circuit than with that according to FIG. 3.

A flexible characteristic curve setting is possible with the exemplary embodiment according to FIGS. 1 to 4. Thus, by appropriate programming of the control unit, any characteristic curve taking into account the present conditions can be set.

The embodiment described above is used for re gelung a heating pump, the differential pressure with different flow rates with a tolerance of approx. 10% of the maximum pressure can be corrected. Such a regulation according to the invention is not only for Pumps, but also suitable for fan systems.

Claims (13)

1. Circuit arrangement for differential pressure control of a pump system which is driven by a single-phase capacitor motor having a main winding (L1) and an auxiliary winding (L2), with the following features:

• a) to reduce the motor power, the auxiliary winding (L1) has at least one partial winding (L2a, L2b) which is connected in series as a choke to the main winding (L1),
• b) there are first means (R _1,1 ) for generating a signal proportional to the main winding current (I _H ) as the first actual value (I _ist ) and
• c) there are also second means ( 2 ) for generating a signal proportional to the main winding voltage (U _H ) as the second actual value (U _ist ),

characterized in that

• d) the first actual value (I _ist ) as a negative value of an adder circuit ( 3 ) and the second actual value (U _ist ) as a positive value are fed directly to this adder circuit ( 3 ),
• e) an integrator ( 4 ) is connected to the output of the adder circuit ( 3 ),
• f) the output signal of the integrator ( 4 ) with little least a reference value (U₁, U₂, U₃) is compared and
• g) third means ( 5 , T1,..., T4) are provided which, depending on the comparison result, connect the partial winding (L2a, L2b) to the main winding (L1) in series or separate this partial winding from the main winding (L1) thereby keeping the dif ferential pressure constant.

2 Circuit arrangement according to claim 1, characterized in that fourth means ( 6 ) for generating a to the winding temperature of the main winding (L1) and the auxiliary winding (L2) proportional third actual _value (U _temp ) are provided. 3. Circuit arrangement according to claim 1 or 2, characterized in that fifth means ( 7 ) for generating a fourth actual value (U _offset ) are provided for offset compensation. 4. Circuit arrangement according to one of the preceding claims, characterized in that instead of an adding circuit ( 3 ) and an integrator ( 4 ) a sum mationsintegrator ( 8 ) is used. 5. Circuit arrangement according to one of the preceding claims, characterized in that at least one comparator (K1, K2, K3) is provided which compares the Ver between the output signal of the integrator ( 4 ) or the summation integrator ( 8 ) and the reference value ( U₁, U₂, U₃) performs. 6. Circuit arrangement according to claim 5, characterized in that the third means comprise a control unit ( 5 ) and switches controlled by this (T1,..., T4), said control unit ( 5 ) providing the output signal of the comparator (K1 , K2, K3) processed. 7. Circuit arrangement according to claim 6, characterized in that a current zero crossing detector ( 9 ) is seen before, the signal indicating the current zero crossing is used for switching the switches (T1,..., T4). 8. Circuit arrangement according to claim 7, characterized records that the controllable switch as a triac (T1,..., T4) are trained. 9. Circuit arrangement according to one of claims 2 to 8, characterized in that an NTC resistor ( 6 ) is provided as fourth means. 10. Circuit arrangement according to one of claims 3 to 9, characterized in that a resistance bank ( 7 ) is provided as the fifth means, wherein at least one resistor (R1,..., R4) via at least one switch (S1,..., S4) can be connected to the input of the adding circuit 3 or the summation integrator ( 8 ). 11. Circuit arrangement according to claim 10, characterized in that the switch (S1,..., S4) is designed as ana log switch and is controlled by the control unit ( 5 ). 12. Circuit arrangement according to one of the preceding claims, characterized in that an operating voltage (V _DD , V _SS ) symmetrical to a floating zero potential is generated as the operating voltage source for the circuit arrangement.