CH672959A5 - - Google Patents

Description

DESCRIPTION The present invention relates to a circuit arrangement for generating at least one current-proportional voltage with at least one shunt in a three-phase power supply arrangement with three electrical lines.

A circuit arrangement of the type mentioned at the outset is known from DE-OS 2 657 784. In this circuit arrangement, the currents of a power supply arrangement for a building heating device are passed through shunts in order to detect the currents flowing in the lines and thus at least switch off the overloaded line when a maximum current value is reached. The AC voltages that occur at the terminals of the shunts are proportional to the currents flowing through the shunts and through the associated lines and are each applied to three amplifiers. The incoming AC voltage is rectified there according to the peak values into a DC voltage, which is led to a photodiode of an optocoupler. The optocoupler ensures the transmission of the current-proportional signals and the electrical isolation between the power supply arrangement of the building and an electronic protection and control device for switching off the overloaded lines. Galvanic isolation between the shunt connections and the electronic protection and control device io is necessary because the full chained voltage of the power supply arrangement prevails between the shunts in the individual phase lines. The electronic protection and control device would be too expensive if it had to be designed for this voltage. However, the optocouplers used here for electrical isolation are also relatively expensive and the switching arrangement required for this is complicated, so that this circuit arrangement is disadvantageous overall.

The object of the present invention is to provide a scarf arrangement of the aforementioned type which is simple and economically advantageous.

The object is achieved in that at least one section comprising all lines is provided in the power supply arrangement, with a 25 shunt impedance being present in each section, which are connected in a different line in several sections in each section but having the same impedance value in each section and at each section boundary on each line a measuring impedance having the same impedance value is connected, the other connections at each section boundary of which are each electrically conductively connected to one another at a common point, with one between the common points belonging to the successive section boundaries the voltage proportional to the current flowing in the current section belonging to the respective section occurs. With this simple circuit arrangement, galvanic isolation between the shunt impedances and an electronic protection and / or control device is not necessary.

because the current-proportional voltages are tapped between the common points, which apart from the small current-proportional voltages have the uniform potential of the star point of the three-phase power supply arrangement. The simplicity and the economic advantages of this circuit arrangement are striking. 45 Three sections are advantageously provided, with a voltage proportional to earth current flowing from one of the shunt impedances on the consumer side from the power supply arrangement occurring between the common points belonging to the section boundaries lying before the first section and after the last section. This circuit arrangement can advantageously be used to supply an electronic protective relay with overcurrent and earth fault current tripping.

In the three-phase power supply arrangement 55 there can also be only two sections, a voltage proportional to the current flowing in the shunt-free third line occurring between the common points belonging to the section boundaries lying before the first section and after the last section. This simplified m circuit arrangement also allows the detection of the current flowing in the shunt-free third line, although only two shunt impedances are present.

Each shunt impedance is advantageously an ohmic resistance. Each measuring impedance can also be an ohmic resistance.

An amplifier connected to the associated measuring impedance on the output side can be connected to the connections of each shunt impedance.

3rd

672 959

zen all amplifiers are equal to each other. This measure allows higher deviations between the impedance values of the measuring impedances used while maintaining the measuring accuracy of the entire circuit arrangement.

Exemplary embodiments of the invention are described in more detail below with reference to the accompanying drawings. Show it:

I shows a circuit arrangement for generating a current-proportional voltage in a three-phase power supply arrangement with a shunt impedance,

2 with three shunt impedances,

3 with two shunt impedances,

Fig. 4 shows the circuit arrangement with two shunt impedances and with two amplifiers.

The three-phase power supply arrangement shown in FIG. 1 contains the three electrical lines R, S, T and is used to supply the load 1 with electrical energy. The circuit arrangement has a section comprising all lines R, S, T, between the section boundaries 2, 3 in the line T a shunt impedance Z is switched on. At the two section boundaries 2, 3, measurement impedances M are connected to each line R, S, T. All measuring impedances M have the same impedance value. The other connections of the measuring impedances M facing away from the lines R, S, T are each electrically conductively connected to one another at a common point 4, 5 for each section boundary 2, 3. It can be derived that the voltage Ut between points 4 and 5 is proportional to the current It flowing in the line T and a third of the product of the impedance value of the shunt impedance Z in the line T and the current It, Ut = ZX It / 3 is. If no current flows in the lines R, S, T, the common points 4 and 5 have the same potential, namely the potential of the star point of the power supply arrangement. At the common points 4 and 5, an electronic measuring, protection and / or control device, not shown, can be connected without electrical isolation.

The circuit arrangement according to FIG. 2 is divided into three sections, between whose section boundaries 6, 7, 8, 9 three shunt impedances Z are connected. In each section, a shunt impedance Z is arranged in a different line R, S, T, however. The impedance values of the shunt impedances Z are identical to one another. Measuring impedances M are connected to each line R, S, T at the section boundaries 6, 7, 8, 9, and each have the same impedance value. The connections of the measuring impedances M facing away from the lines R, S, T are each electrically conductively connected to one another at a common point 10, 11, 12, 13 for each section boundary 6, 7, 8, 9. Between the section limits 6 and 7, the shunt impedance Z lies in the line T. Between the common points 10 and 11 belonging to these section limits 6, 7, a voltage Ut proportional to the current It flowing in the line T will occur. Their size is a third of the product of the impedance value of the shunt impedance Z and the current It. Similarly, between the common points U and 12 the current Is and between the common points 12 and 13 the current Ir proportional to the current Ir and Ur. The magnitude of these voltages Us and Ur is in each case one third of the voltage drop present at the shunt impedance Z, Us = Z x Is / 3 and Ur = Z x Ir / 3. Between the common points 10 and 13, which lie before the first section, at the section boundary 6, or after the last section, at the section boundary 9, a voltage Ue will occur which, according to one of the shunt impedances Z, in the line R on the consumer side earth current Ie flowing from the power supply arrangement is proportional. Therefore, the voltage Ue can be used in a protective relay (not shown) for earth fault protection purposes.

The magnitude of the voltage Ue is again a third of the product of the impedance value of the shunt impedances Z and the earth current Ie. The circuit arrangement shown in FIG. 2 can indicate the three-phase current transformer in the prospectus of Fir-5 ma Sprecher + Schuh AG, 5001 Aarau / Switzerland, No. 1.1012 d.SSA / 3.87 / 55/10 (2252) on page 25 Replace switching arrangement, this switching arrangement can be supplemented with an earth fault protection.

3 shows a simplified circuit arrangement with two shunt impedances Z, which are accommodated in two sections. These two sections are delimited by the three section boundaries 14, 15, 16. In this circuit arrangement, too, measuring impedances M are connected to the lines R, S, T at the section boundaries 14, 15, 16, which are electrically conductive with their other connections per section section 14, 15, 16 in the common points 17, 18, 19 are connected. The first section includes the shunt impedance Z in line T, the voltage proportional to the current It occurring between the associated common points 17 and 18, Ut = Z x It 20/3. The shunt impedance Z in the line S belongs to the next section lying between the section limits 15, 16. Between the associated common points 18 and 19, a voltage Us proportional to the current Is can be measured, the magnitude of which Us = Z X Is / 3. A voltage Ur proportional to the current Ir in the shunt-free line R can be detected between the common 25 points 17 and 19 which belong to the section boundary 14 before the first section and to the section boundary 16 after the last section. The magnitude of this voltage is Ur = Z X Ir / 3. This circuit arrangement, which is only provided with two shunt 30 impedances Z, can already replace a three-phase current transformer.

As a rule, purely ohmic resistances are used for the shunt impedances Z and for the measuring impedances M.

In order to achieve sufficient accuracy of the current proportional voltages Ur, Us and Ut, high demands are placed on the tolerances of the impedance values and on the temperature coefficients of the measuring impedances. In order to achieve a measuring accuracy for the currents Ir, Is, It in a 430V power supply arrangement of 5%, the tolerance of the Impedan-40 values between the individual measuring impedances M should not exceed 0.00025% and the tolerance of the temperature coefficients between the individual measuring impedances M not exceed 0.16 ppm / ° C. These tolerance values can be set much higher if the voltage drop across the shunt impedances Z is increased. 4 shows such a circuit arrangement. The supply-side connections of the shunt impedances Z are connected to the non-inverting connections of the operational amplifiers 20, 21. Measuring impedances M are connected to the outputs of the operational amplifiers 20, 21, which in the arrangement according to FIG. 3 were still directly connected to the supply-side connections of the shunt impedances Z. An ohmic divider with resistors Ri and R2 is connected between the outputs of operational amplifiers 20, 21 and the load-side connections of shunt impedances Z. The tap of the divider located between the 55 resistors Ri and R2 is led to the inverting input of the operational amplifier 20, 21. The partial ratio Ri / R2 gives the effective amplification factor of the operational amplifier. Between the common points 25, 60, 26, 27 of the measuring impedances M belonging to the section boundaries 22, 23, 24, the voltage drop across the shunt impedances Z, which is increased by the ratio Ri / R2, appears between the common points before the first and after the last section Points 25 and 27 are also measured in this arrangement, as in the arrangement according to FIG. 3, ei-65 ne voltage Ur proportional to the current Ir flowing in the shunt-free line R but amplified in the ratio of Ri / R2.

2 sheets of drawings

Claims (6)

672 959 2nd PATENT CLAIMS 1. Circuit arrangement for generating at least one current-proportional voltage with at least one shunt in a three-phase power supply arrangement with three electrical lines, characterized in that at least one section comprising all lines (R, S, T) is provided in the power supply arrangement, with a section in each section Shunt impedance (Z) is present, which is connected to a different line (R, S, T) for several sections in each section but has the same impedance value in each section, and at each section boundary (2, 3, 6, 7, 8 , 9, 14, 15, 16, 22, 23, 24) on each line (R, S, T) a measuring impedance (M) with the same impedance value is connected, the other connections of which at each section boundary (2, 3, 6 , 7, 8, 9, 14, 15, 16, 22, 23, 24) each in a common point (4, 5, 10, 11, 12, 13, 17, 18, 19, 25, 26, 27) with each other are electrically conductively connected, between which to the one after the other following section boundaries (2, 3, 6, 7, 8, 9, 10, 14, 15, 16, 22, 23, 24) common points (4, 5, 10, 11, 12, 13, 17, 18, 19 , 25, 26, 27) a voltage (Ur, Us, Ut) proportional to the current flowing in the shunt impedance (Z) belonging to the respective section occurs. 2. Circuit arrangement according to claim 1, characterized in that three sections are present, one between one of the shunt impedances between the common points (10, 13) belonging to the section boundaries lying before the first section and after the last section (Z) voltage (Ue) proportional to the consumer current flowing from the power supply arrangement (Ie) occurs. 3. Circuit arrangement according to claim 1, characterized in that two sections are present, whereby between the common points (17, 19, 25) belonging to the section boundaries (14, 16, 22, 24) lying before the first section and after the last section , 27) a voltage proportional to the current flowing in the shunt-free third line (R) occurs (Ur). 4. Circuit arrangement according to one of claims 1 to 3, characterized in that each shunt impedance (Z) is an ohmic resistance. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that each measuring impedance (M) is an ohmic resistance. 6. Circuit arrangement according to one of claims 1 to 5, characterized in that an amplifier (20, 21) connected to the associated measuring impedance (M) on the output side is connected to the connections of each shunt impedance (Z), with several shunt impedances (Z ) all amplifiers (Z) are identical to each other.