DE898168C - Procedure for measuring the electrical phase shift, active and reactive power in AC circuits - Google Patents

Description

Method for measuring the electrical phase shift, the active and Reactive power in alternating current circuits To the phase shift as well as the active and It is well known to measure reactive power in AC circuits, electricity and Voltage (if necessary via current and voltage converters) Active and reactive power meters, cos-q; -meters and current and ammeters. The various types mentioned above Measurements as they are carried out today have a number of disadvantages. In many cases the self-consumption of the measuring instruments used is so great that a measurement cannot be taken at all or incorrect measurements occur, z. B. when using conventional cos - # knives without tubes. Also is the measurement as such by switching on various measuring devices cumbersome and in the evaluation difficult, since the measured values are usually only used arithmetically after reading can be. Another disadvantage of the above measurements is that most measuring instruments, z. B. cos - # meters, reactive power and active power meters, only for low frequency (z. B. 5o Hz), so that, for example, the measurement of high-frequency circuits is not possible with the help of these known measuring instruments.

The invention overcomes these disadvantages. It enables by means of a Measuring device, all measurements required for an alternating current circuit with a simple Perform the operation. First, in a known manner, from the stream and from the voltage of the AC circuit has two measuring tensions formed, one of which is proportional to the voltage and the other to the current. The two Measurement voltages are phase-shifted from one another by electrical degrees. then apply vector, the sum and the difference of the measuring voltages are formed. According to the In the invention, the two rectified measurement voltages become a zero indicator supplied, whereby the size equality of the binding measurement voltages (the sum or Differential voltages) by an additional variable phase shifter accordingly the phase shift of the two input voltages, which are from the current and from the voltage of the circuit, it is changed until the size is equal of the two voltages arises or until the zero indicator shows 0. From the position of the variable phase shifter is then the phase shift between currents and voltage of the circuit.

If, according to the invention, the variable phase shifter is set to 0 ° (i.e. H. Phase equality between U3 and U4) is set, the zero indicator deflects, where the size of the deflection is proportional to the reactive power of the current crisis.

If the changeable phase shifter is set to go "phase shift, the whirling power can be read off from the deflection of the zero indicator.

If the voltage fluctuates in the circuit, this is the result of the measurement of active and reactive power measurement errors. In an embodiment of the invention, these Errors eliminated by using part of the voltage in the circuit Measurement voltage is branched off and rectified.

The DC voltage generated in this way controls the other, generated by the electricity Measurement voltage by means of controllable switching elements, for example control tubes, such that a voltage increase of the first-mentioned measuring voltage is a voltage increase of the Measurement voltage, which is obtained from the current, is generated. So there is a multiplication of the two measuring voltages.

In a further embodiment of the invention, they can use the zero indicator through flowing direct currents of alternating polarity to control any electrical Changes in the AC circuit are used.

For example, phase changes can be made using simple relay circuits causes or servomotors, excitation windings of control generators, reactance tubes controlled at high frequency, etc. Because the sum-difference circuit of deep Frequencies away (e.g. 50 Hz) up to the highest frequencies (e.g. 30 MHz) realized can be used, an application of the measurement method in the broadest n scope is made possible. In the case of low-frequency voltages, the sum-difference figure is generated using transformers made, for high-frequency voltages, best with electron tubes, whereby especially the difference is achieved by a phase reversal tube.

Finally, writing implements can also be used in a particularly simple manner operated by the zero indicator or by the currents flowing through it.

Fig. I shows an embodiment of the invention. The consumer r is fed via the neutral conductor 0 and the phase u or v or w. From the stream of the circuit is proportional to the current by means of the transformer 2 Measurement voltage gained. This is amplified by means of the amplifier 3 and the transformer 4 supplied. The voltage of the circuit is taken off by means of the transformer 5, wherein the secondary side of the transformer has a center tap on which the two measuring voltages U1 and U2 are. The ends of the secondary winding lie in each case on a variable resistor 6 and on a capacitor 7.

The mean budget of the transformer 5 and the link performance between variable resistor 6 and 7 nd capacitor are the transformer 8 supplied. The structure consisting of the switching elements 5, 6, 7 and 8 works as a variable phase shifter with the mode of operation according to Fig. 2.

Fig. 2 shows the vector diagram. The alternating voltages Ut and U2 are in phase and add up. The voltage UR at the variable resistor 6 and the voltage U, at the capacitor 7 are perpendicular to one another. Will the resistance. 6 changes, the geometric location of point A is above the stress vector U1 and U2 a struck semicircle. The connection A-B in the vector diagram in Fig. 2 results the size and phase position of the voltage U3.

One can see from the vector diagram that the one formed from 5, 6, 7 and 8 Phase shifting depending on the size of the variable resistor 6 is a constant to generate controllable phase shift between U1, U2 on the one hand and U3 on the other hand allowed, the size of the voltage U3 regardless of the position of the changeable Resistance 6 is.

The transformers 8 and 4 each have two exactly the same secondary windings, which are interconnected so that the first secondary winding of the transformer 8 connected together with the first secondary winding of the transformer 4 in such a polarized manner becomes that the vector sum of U3 and U4 arises; the second secondary winding of the transformer 8 is connected to the second secondary winding of the transformer 4 connected or poled in such a way that the vectorial difference between the voltages U3 and U4 is created.

By means of the double diode 9, the sum and the difference voltage rectified. The total voltage goes through the anode loder double diode 9 and appears rectified at resistor 11. The differential voltage goes over the Anod) e 12 of the double diode 9 and appears rectified at the resistor 13. Sum- and differential tension are the same size or generate #equally large 'DC voltages at m and 13, if U3 and U4 have a 90 ° phase shift The zero indicator 14, z. B. a direct current milliammeter with zero point in the middle, then shows the deflection 0. Depending on whether the total voltage is greater than the differential voltage or vice versa, the zero indicator 14 points left or right at what a conclusion on inductive or capacitive phase angle between U3 and U4 or the phase angle in the circuit.

Fig. 3 a and 3 b show the vector diagram for a better understanding the sum and difference circuit.

As can be seen from Fig. 3a, the sum voltage is U3 and the differential voltage Ud is the same if the voltages originating from transformers 8 and 4 U3 and U4 have a 90 ° phase shift. Do not have 90 ° as in the vector diagram Fig. 3 b, it can be seen without further ado that the sum voltage Us and the difference voltage Ud are of different sizes, so that a deflection occurs at the zero indicator 14, which is indicated by After rotating the changeable phase shifter it is brought back to 0.

If you set up the measurement circuit Fig. I in such a way that, apart from the additionally generated by means of the phase shifter phase shift between the transformer 5 and 8 on the one hand and 2 and 4 on the other hand have no or a constant phase shift prevails, the variable resistor 6 of the phase shifter or the position its acceptance grinder with a calibration in electrical degrees phase shift or directly provided in cos #, which is a measure of the respective phase shift is in the consumer circuit 1.

Is the phase shifter like this in this way. calibrated that out of position the phase shift in the circuit can be read off the acceptance grinder, so with a purely real consumer i the pointer of the acceptance grinder is set to phase shift 0 must be turned when the instrument shows 14 zero deflection. Will now be the changeable resistor 6 of the phase shifter changed so that the voltage Us is rotated by 90 "(cf. vector diagram Fig.2), the zero indicator shows the maximum limit at. The size of this deflection is a measure of the active power or the size the measuring voltage delivered by the transformers 5 and a. Own these in addition against each other still a phase shift resulting from the circuit, then the Deflection can be changed accordingly. So it is possible by adding 90 ° phase shift compared to the 0 ° position of the phase shifter, the real power or by setting the phase shift to 0 °, the reactive power at the deflection of the Measure zero indicator. The zero indicator 14 can be in reactive and active power to be calibrated. In the interests of the accuracy of these measurements, it is important to keep the to keep the measurement voltage originating from the current lower than the other measurement voltage.

If the measuring voltage supplied by the transformer 5 fluctuates, then in order to avoid incorrect measurements of active and reactive power, from the tube carrier 5 by means of a third winding a part. branched off therefrom and by means of the rectifier 15 rectified. The rectified voltage is fed to the amplifier 3, which is shown in in this case as a regulator amplifier, for example with a hexode, is supplied. When the control DC voltage is high, the value of the supplied DC voltage higher gain and with lower DC control voltage lower gain by means of. the control tube or the control switching element generated. The one from the tension and the measuring voltages resulting from the current in the circuit are in this way multiplied. Fig. 4 shows as an embodiment of the invention, how by means of s an amplifier connected downstream of the sum-difference circuit measures the power consumption of the measuring device can be reduced. According to fig. I-be by means of the transformers 8 and 4 in turn show the vector sum and the vector difference between the two Voltages U3 and U4 formed. Exactly as in, Fig. I, the two voltages are a double diode 9 supplied; at the resistors m and I3 then arise in a rectified manner Sum and difference voltages. The difference between these voltages is shown instead of the zero indicator the control grids of the tubes 16 and 17 are fed. The tubes work as a direct current cathode amplifier, d. H. their anodes lie directly on the plus pole of the anode voltage + A. The essential increased control grid power of both tubes can then be applied to the ends of the resistors Ig and rg or on the cathodes of the tubes 16 and 17 by means of the zero indicator 14 be removed. The control grid power can be kept very small because the resistors 13, 11 and 20, 21 can be very large.

Especially when measuring active and reactive power, it is important to in this way the current through the zero indicator from the sum-difference circuit keep away, as its effects on the transformers 8 and 4 cause measurement errors.

Fig.5 shows as an embodiment of the invention how the sum-difference circuit especially with high-frequency measuring voltages instead of transformers with tubes is realized. The voltage U3 (see Fig. 1). a control grid of the double triode (or double pentode) 22 and the control grid of the phase inversion tube 23 is supplied. The one offset by r8o ° Control grid voltage of 23 is applied to resistor 24 via capacitor 2. 5 a Control grid of the other double tube. 26 supplied. The voltage ! becomes in phase the control grids that are still free. the Do. ppelrohren22. and 26 supplied.

The two anodes of a double tube are connected to one another. Thus arises at the anodes of the double tube 22. the vectorial sum voltage of U3 and U4, at the anodes of the double tube 26 the vectorial differential voltage.

These two voltages are again similar to Fig. I across the capacitors. 27 and 28 and the capacitor 29 are fed to a double diode 9 and rectified. At the cathode resistors 11 and 13, rectified sum- and Difference voltage, which if via the resistors 30 and 31 the zero indicator 14 press as described.

Claims (7)

PATENT CLAIMS 1. method for measuring the electrical phase shift as well as the active and reactive power in alternating current circuits, with a measuring voltage the voltage to be measured, the other measuring voltage proportional to the current to be measured and the two measurement voltages are phase-shifted from one another by g electrical degrees and vectorially the sum and the difference thereof are formed, characterized in that, that after rectification at a zero indicator the size of the sum and Differential voltages by an additional variable phase shifter accordingly the phase shift of the two input or Measurement voltages is produced and that besides reading the input phase shift on the changeable Phase shifter by adjusting it to 0 ° (i.e. phase equality between U3 and U4) the blind line and by adjusting the variable phase shifter active power on go'dite is read from the deflection of the zero indicator (Fig. i to 3). 2. Arrangement for performing the method according to claim 1, characterized characterized in that when the voltage in the circuit fluctuates from that of the voltage Part of the resulting measuring voltage is branched off, rectified and controlled via Switching elements (e.g. regulating tubes) the measuring voltage resulting from the current in this way affects that voltage increases in the circuit an increase in the resulting from the current Cause measuring voltage, and vice versa (Fig. I). 3. Arrangement for performing the method according to claim 1, characterized characterized in that tube amplifiers, in particular to reduce power consumption Cathode amplifiers, the sum-difference circuit are connected upstream or downstream (Fig. 4). 4. Measuring method according to claim T, characterized in that the Zero indicator or its current flowing through it to influence the measured Circle causes phase changes or servomotors, excitation windings of control generators, Reactance tubes at high frequency, etc. controls. 5. Arrangement for performing the method according to claim i, characterized characterized in that the sum-difference formation at low-frequency voltages or current is carried out by means of transformers. 6. Arrangement for performing the method according to claim 1, characterized characterized in that for the formation of sums and differences in the case of high-frequency voltages respectively. Stream electron tubes, especially using a Phase reversal tube for the formation of differences (Fig. 5). 7. Arrangement for performing the method according to claim 1, characterized indicates that the zero indicator or the currents flowing through it are writing implements actuate. References: U.S. Patent Nos. 20935I2, 2'2I7477.