DE588305C - Arrangement for capturing the parallel or opposing components of an asymmetrical multi-phase system - Google Patents

Description

ISSUED ON NO VEMBER 17, 1933

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21 d ² GROUP 43

Patented in the German Empire on January 12, 1930

It is known that every asymmetrical multiphase system can be divided into two symmetrical multiphase systems can be traced back to a so-called co-rotating system in which the vectors of the individual phases in the same sense as in the overall system and on a so-called counter-rotating system in which the Vector sequence is reversed.

To the parallel or counter-rotating system for measuring purposes, relay circuits, etc. for itself It is well known that a multiphase motor with synchronously rotating motor can only be obtained (sifted out) Squirrel cage can be used. However, this arrangement has the disadvantage that the grooving of the machine numerous harmonics of considerable size, which will affect the measurement. Another well-known facility There is a special art circuit to record the system running in parallel or in opposite directions of inductors or capacitances and ohmic resistances.

Such an artificial circuit for a three-phase system is shown, for example, in FIG. 1. R, S, T are the three phase lines; The resistors r and r 'are connected in series between each two phase lines. The resistance r is an ohmic resistance, the resistance r ' consists of an ohmic resistance of the size } _f r and an inductive resistance of the size ^] / 3r in ohms. As a result, the voltage prevailing between each two phase lines is broken down into two components, which in the voltage triangle correspond to the connecting lines of the relevant corner points with the center of gravity of the triangle. 3ΐ> This voltage triangle is shown in Fig. 2. If there is a symmetrical voltage system with the phase sequence R, S ₁ T clockwise on the three phase lines, the points R ', S', T 'have the same potential, namely that of the center of gravity of the Voltage triangle. Voltmeters switched on between points R ', S' and S ', T' and T, R ' in Fig. 1 show zero.

If a symmetrical voltage system with the opposite phase sequence T, S, R is applied to the three phases R, S, T with unchanged switching of the resistors, the voltage components come between two phases each.

*) The patent seeker stated as the inventor:

Or. B. Meng'ele in Vienna,

sen lines to lie to the outside in the voltage triangle, as Fig. 3 shows. Between the points R ', S', T ' one obtains a voltage system of the same size as the system T, S, R.Therefore, there is both a (clockwise) voltage system R, S, Γ and an opposing (counterclockwise) voltage system on the three lines T, S, R present, only the opposing system T, S, R appears at the points R ', S', T ' . In this case, the opposing system is detected and the parallel system is suppressed.

If, on the other hand, you want to capture the co-rotating system, you only need to swap the resistances r and r '. In this case, the opposing system is suppressed and only the concurrent system is displayed.

. The known circuit arrangement described above, however, has the disadvantage that its information is only correct as long as the frequency maintains a certain value. If the frequency deviates, which must always be expected in practice, the relationship between the resistances r and r 'is disturbed and the circuit supplies incorrect information.

The subject matter of the invention is an arrangement for detecting the components moving in the same direction or in the opposite direction an asymmetrical multiphase ο system by means of an in their mode of operation frequency-dependent artificial switching, in which for the formation of the counter-rotating (concurrent) Component the difference (sum) of two such voltages is used, whose vector endpoints have the same parallel displacements for small frequency changes Experienced. With such an arrangement, the influence of frequency deviations is on the display of the symmetrical system components rotating in or in opposite directions over a certain amount Frequency range suppressed or only very low. With the right choice of resistors and their circuitry, the partial voltages (partial currents) occurring across them are among each other or together with voltages (currents) of the multi-phase system in the event of frequency deviations within a certain range a possibly phase-shifted in their Size, however, approximately the same result supply as a measure for the system to be recorded, for the system to be suppressed but practically cancel each other out or result in only a small residual value.

An embodiment of the invention for> detecting the parallel or opposing voltage component in a three-phase system is shown in FIG. 4. R, S, T are the three phase lines; the phase line T is connected with the two other phase lines R and S via a respective <voltage distributor, made of a ohmic resistance R or / and an inductor L or is L '. The secondary winding F of a transformer, the primary winding U of which lies between the phase lines R and 5, is connected between the two tapping points R 'and S' of the voltage divider. Z is a voltmeter.

Fig. 5 shows the voltage polygon for the co-rotating system in this circuit. The code letters of the voltage vectors indicate the points in the circuit arrangement between which the voltage in question occurs, e.g. B. Eχs is the voltage between points R and 5. The potential of the tapping points R ' and S' corresponds to the vertex of the associated voltage triangle, which must be on a semicircle above Etr or Es τ. By appropriately sizing the resistors such that a phase angle ψ 'of about 30 ^0, and the other a phase angle ψ of 6o ° has, s is ₀ so it is achieved that the vector Er · $, the voltage between the tap points R', and S 'the voltage divider is parallel to the voltage vector Ens . Eris · must then also be half of Ens .

If the transformer U, V translates by half between R and S and its secondary winding is connected to the points R ', S' in the sense of FIG. 4, the voltmeter Z shows zero. The co-rotating system R, S, T is completely suppressed at the nominal frequency. If the frequency changes, the points R ' and S', which are the vector endpoints of the partial voltages of the voltage divider, shift in the same sense in the voltage diagram , i.e. the voltage vector Eris> shifts approximately parallel to itself and remains approximately the same _{wE RS} , because the centers of the two semicircles are separated from each other by £ E _R s. So even if the frequency changes, in the present case z. For example, the parallel system is almost completely suppressed if the frequency deviation is not too great, but very largely suppressed at a higher frequency and is therefore only included as a very small error when measuring the opposing system (which, for example, is to be displayed in the present case).

For the opposite system, the voltage diagram is shown in FIG. 6. This arises simply from the fact that the voltage triangles over Εχη and Est according to FIG. 5 are folded over by 180 ° from the plane of the drawing. In this case, only the voltage Eri τ is displayed on the voltmeter Z at nominal frequency, while the voltages £ 5 / r and iE _K s (on the transformer) cancel each other out. The voltage Eri τ is approximately - ^] / 3 of the linked voltage and serves as a measure for the opposing system. Here too, if the frequency deviation is not too great, the magnitude of the voltage Eri χ resulting from the voltages E _R r _S ' and ± E _RS (the measure for the average

current system) has not changed anything, it only changes its phase position.

At the voltage vector Z is therefore within

of a certain frequency range of the one system to be screened out, one in theirs Size approximately constant voltage, only changed in phase, indicated by the other system that should not be screened out, but only a small residual stress with-

xo measured.

If one determines, starting from - tg -

and = tg - ^ - for nominal frequency, after which "

Diagram of FIGS. 5 and 6, the resulting voltages of each system for different frequency deviations, one arrives at the diagram shown in FIG. The distance R ', T this corresponds to the distance R', T in FIG. 6 and illustrates the direct reading at the nominal frequency on the voltmeter voltage of auszusiebenden system represents one plots of R 'from the at different frequency offsets (relative to the nominal frequency as. Unit) on the voltmeter at the same time acting on the resulting voltages of each system according to size and phase, then the end points of these vectors are on the curve K. For example, a frequency of 0.7 of the nominal frequency of the voltage vector R ', P ₁ of the correspond system to be detected and the voltage vector R ', P ₂ from the system to be suppressed. The part of curve K lying below the horizontal axis corresponds to the system to be detected, the part lying above this axis corresponds to the system to be suppressed.

Both systems are assumed to be of the same size. Even under this condition, the error element (voltage component R ', P ₂ ) resulting from the system to be suppressed is very small in the actually measured voltage and, because of its phase position, has little influence on the total voltage amount. If the frequency deviations are not too great, a system with a lower voltage can be practically separated from a system with a higher voltage that is to be suppressed. The conditions are of course most favorable when the system to be suppressed is smaller than the one to be detected.

It can be seen from the diagram that the error resulting from the system to be suppressed increases faster with the same absolute deviation of the frequency from the nominal value when the frequency is reduced than when the frequency is increased. This can be changed by choosing ψ slightly smaller than 60 °. FIG. 8 shows a diagram otherwise corresponding to the diagram in FIG. 7, but with the resistance ratios

ω !. η, ωL ',

■ y, - = 1.40 and —-, · - = 0.49 are used as a basis. Here the point R 'is not a turning point, but a self-intersection.

FIG. 9 shows the error resulting from the component to be suppressed, based on FIG the real size of this system component as a function of the frequency. On the The frequency is plotted as a percentage of the nominal frequency on the abscissa axis, on the ordinate the measurement error as a percentage of the real symmetrical component. The curve I corresponds to the described embodiment of the invention when the phase angles of the resistors are 30 ° and 60 ° (diagram Fig. 7), the curve II the same embodiment at phase angles of about 26 ° and 56 ° (Diagram Fig. 8); curve III corresponds to the known arrangement according to FIG. 1.

From Fig. 9 it can be seen that according to the invention, the measurement error at a different frequency In contrast to the known arrangement, it is completely suppressed or at least kept very small over a certain frequency range can be. By choosing the resistance

conditions -.

and

you have it m the

Hand, the error-free frequency range as required to be determined. For example, one can measure the degree of asymmetry or for counting purposes Resistance ratios go accordingly of curve I, as this does not occur in the case of small fluctuations around the nominal frequency Deliver errors. On the other hand, protection circuits are used in the event of a fault, i.e. with larger Frequency deviations should work correctly, resistance ratios accordingly Recommend curve II.

The measurement error for the component to be detected, which over a substantial frequency range consists almost entirely of an angle error, i _O o, has no effect on its own in voltage or current measurements. In the case of power or quotient measurement (of current and voltage), the voltage and current sieves are also subject to the same angle error, so that this does not have a disruptive effect here either.

The invention is not restricted to the stated resistance ratios. these can can also be chosen differently, and the resistances can also be changed in a different way be arranged.

The invention can also be used in artificial circuits for detecting the symmetrical current components. FIG. 10 shows a corresponding embodiment which represents a corresponding transfer of the tension strainer according to FIG. 4. The phase lines R and S are each via an ohmic resistance r and / and an inductance L or L ' with a center on. the third phase T connected to transformer U , which acts as a current divider. The resistances r and r '

are connected on one side, the inductances L and Z / on the other side of the transformer U. The proportions - /

and

ω L '

tons functional like for example

Tension sieve according to FIG. 4 can be selected according to the phase angles of about 60 ° and 30 °. The ammeter Y is connected at points R ' and S'. The current diagram for this circuit corresponds accordingly to the voltage diagram according to FIG. 5 or 6. The phase currents correspond to the interlinked phase voltages there. The currents flowing together at points R ' and 5' correspond accordingly to the voltages occurring between R ' and 5' according to FIGS. 5 and 6 at the resistors and at the transformer. The one flowing into the ammeter

ao residual current from the nodes !? ' and S ' corresponds to the residual stress in the stress strainer.

Claims (5)

Patent claims: i. Arrangement for detecting the parallel or opposing component of an asymmetrical Multiphase system by means of a frequency-dependent in its mode of action Art circuit, characterized in that for the formation of the 'opposite The (concurrent) component is the difference (sum) of two such voltages whose vector endpoints are the same parallel with small frequency changes Experiencing shifts. 2. Arrangement according to claim 1 for detection the opposing component of the voltages of an asymmetrical three-phase system, characterized in that two or three voltages of the three-phase system each with one from an ohmic and an inductive or capacitive resistor connected in series with it existing voltage dividers are loaded and those between the tapping points of both Voltage divider voltage taken off with one of the third voltage, which is with a voltage divider is not directly loaded, proportional voltage, e.g. B. by means of a transformer. 3. Arrangement according to claim 2, characterized in that the inductive and the Ohmic resistances of each voltage divider are dimensioned so that the phase angle one voltage divider is about 30 °, the other is about 60 °, and that the a difference voltage existing between the taps of the voltage divider Voltage generated by means of a transformer with a transformation ratio of 2: 1 is connected against that of the third, with a voltage divider not directly loaded voltage is taken. 4. Arrangement according to claim 1 for detecting the opposing current component of an asymmetrical three-phase system, ■ characterized in that two phase lines each via an ohmic resistor and an inductance with a transformer lying on the third phase (current divider U) are connected in such a way that the. Inductance on one side, the ohmic resistances on the other side of the transformer are connected. 5. Arrangement according to claim 4, characterized in that the two-phase lines connected resistor combinations phase angles of about 30 ° and 60 ° own. For this purpose ι sheet of drawings