DE893090C - Symmetry measuring device for the calibration and testing of three-phase current meters or the like. - Google Patents

Description

Symmetry measuring device for the calibration and testing of three-phase electricity meters or the like

The invention relates to a symmetry measuring device for calibration and testing of three-phase meters or the like. For calibration or testing of reactive consumption meters or the like by means of a wattmeter or single-phase calibration or test counters, it is necessary that, the voltage triangle of the three-phase system, to that of the test and the test device be connected, is very precisely symmetrical, because usually because of the different Internal adjustment of the reactive consumption meter and the test device the voltage coils these devices can be connected to different voltages of the three-phase system have to. Also for other measuring, testing and monitoring purposes of electrical systems it often depends on a more or less exact symmetry of the voltage triangle.

So far one has the symmetry either with the help of three voltmeters or precision voltmeters monitored; but this monitoring is cumbersome and often difficult to carry out because it causes the deflections of three devices at the same time must be constantly adjusted to a certain value. A perfectly accurate one Measurement will hardly be achievable because of the inevitable friction of the measuring devices. Special measuring devices have also been suggested, in which three voltmetric Systems via cables or the like. Act on a common display part, which according to the force polygon of the three systems adjusts. Such devices work very imprecisely.

Does it matter, for example for the purpose of testing or calibrating a Reactive consumption meter, the voltage triangle for a long time while of the test period, to be kept exactly symmetrical, then the deflections of the are continuously adjusted accordingly during this period. This is particularly annoying because the examiner hardly has time to deal with the current load to adjust to the correct value or to observe the test and the test device.

The invention avoids these shortcomings. According to the invention, the 5 ymmetriemeßein'einrichtung for the calibration and testing of three-phase meters or the like. of at least two integrating null devices with mechanical straightening forces free armature, on which at least two torques act in opposite directions and each other only cancel if the measured variables causing these torques are equal, thereby the one integrating zero device monitors the equality of two sides of the three-phase voltage triangle or star, the other the equality of two other sides of the tension triangle or-sterns. The internal circuitry of the devices can then easily be chosen so that their torque is proportional to I the side difference, in particular I the difference , the squares, is. Such a circuit has the advantage that you can look at the displays the device can easily recognize which voltage to restore the symmetry must be regulated that, the displays of the two integrating devices as a result, regulation of the corresponding voltages is returned to zero independently of one another can be.

Similar to the chained tensions, i.e. the sides of the tension triangle, You can also use the phase voltages, the star vectors, for symmetry monitoring can be used. In a corresponding way one lets through the one integrating Device the equality of one pair of star vectors, by integrating the other Device monitor the equality of another pair of star vectors, and one ensures that the information from each device is proportional to the difference between two star vectors, especially the difference of the squares.

In order to achieve the most precise symmetry measurement possible, send two more special remedies. One means is to have the internal matching of the systems of the integrating devices so that the in, the Torque formula c # # 1 # # 2 # cos # of the individual devices according to known laws Occurring angle function cos # the phase angle? between the individual tensions and instinctual flows as large as possible, d. H. as much as possible equal to I. The other means consists in doing the circuitry and the internal balancing of the integrating Selects devices so that in the case of symmetry in the integrating devices not only no resulting, but no torque at all. By this measure one achieves that even very small deviations from the symmetry case result in considerable Torques and therefore result in relatively large measuring distances. The torques can can easily be increased so that the friction of the devices for the measurement result is negligible.

The accuracy can easily be taken so far, Id; already ate one Change of symmetry of 1 # on one side of the voltage triangle or less clearly perceptible Rashes.

For the purpose of a more detailed explanation of the invention, reference is made to the drawing Examples shown are referred to.

In Fiig. I am with I and. II the two drive systems of an integrating one Device denotes the phase equality or concatenated voltages ST and RT monitor. The second integrating device that is the equality of another couple monitored by concatenated voltages, for example by RS and RT, is simplicity omitted for half; it is made in the same way, only to be appropriately cyclical. swapped Phases connected. Every system consists, as with the well-known Ferrari meter, from two drive magnets, one of which through winding II, the other over a series resistor 10 is excited by the winding 12. The winding 11 is between R and S, the winding 12 connected between R and T. According to the vector diagram the Fiiig. 7, the voltage URS acts on winding II, the system has an equalization, his instinctual flow #UI 1 rushes as a result Ider excite the tension by 90 °. The winding 12 is connected to the voltage URT, its driving magnet is matched to 300; consequently the corresponding instinct flow #I rushes by 30 ° according to the exciting tension. As long as the voltage triangle is symmetrical, are the two instinctual rivers of system I, as FIG. 7 shows, develop in phase and consequently no torque according to known laws.

One winding 21 of system II is connected between S and T, is there on or voltage UST, your drive magnet is adjusted to 90 °; Consequently hurries, the relevant instinctual flow #UII by 90 ° after the exciting tension. The other Winding 22 is across resistor 210 at the line-to-line voltage between R. and S, i.e. at the voltage URS, Fiig. 7. The drive system in question is at 300 matched; consequently slelin Tniebfluss #II rushes by 300 of the exciting tension after. With a symmetrical tension triangle, the two instinctual flows are for system II in opposition and do not develop torque. How easy to prove by invoice even with small asymmetries of the clamping triangle a torque results, that is proportional to the difference or squares of the triangle sides RT and ST, multiplied with the sine of the difference between the phase angles for the internal adjustment of the systems II, I2 or 2I, 22. Since in one case the phase angle is 90 °, in the other case 30 °, results as a factor for the square of the side difference sin, 6o0. The statement also shows that a change in the voltage RS without any influence the display of the device is. There would also be no change in the phase voltage TO Have influence on the device, but this can change the phase RT compared to the Phase ST, the deflection of the device directly influenced or brought to zero will. The same applies to the regulation of the phase voltages RO and SO.

In the embodiment according to FIGS. I and 7, the aforementioned are Two means are used to increase the measurement accuracy, because on the one hand is the Angular function, which occurs as a factor in the torque generation, if possible is chosen to be large and is close to I, on the other hand the systems are connected in this way and balanced that in the case of symmetry, the individual moments of systems I and II disappear. The same applies to the second integrating device, the. For example that monitors the equality of the triangle sides RS and RT. If you like the tension like that adjusted so that the deflections disappear on both integrating devices, then the voltage triangle is exact, possibly up to 1 # and less symmetrical. Since the two devices can be controlled independently of each other, the setting is on symmetry easy and simple to perform. The circuits of the integrating Devices can be carried out in a variety of ways; some implementations FIGS. 2 to 6 show. The possible cyclical exchanges are omitted. In FIGS. 2 to 6, only one integrating device is shown in the circuit diagram; for the second integrating device, the circuit would be reversed cyclically of the phases received. In all figures are the internal adjustments of the individual Drive magnets the same as with Filg. I.

In Fig. 2 the winding 11, of the system I between R and T, is the Winding 12 connected between R and 5. In system II the winding is 2I connected between R and S and the winding 22 between S and T. The mode of action is essentially the same as according to vector image Fig. 7, but with the difference that here in the case of symmetry the individual moments do not disappear, but the resulting ones do Torque of systems I and II becomes zero.

In Fig. 3, the winding 11 for Idas system I is between R and S, winding 12 also between R and S, for system II the windings are located 21 and 22 between S and T. The individual moments are here, like, the circuit diagram without further shows, proportional to the square of the voltages RS and ST, since the Systems I and II form what are known as E2 systems. Even. here disappears in the case of symmetry the resulting moment, but not the individual moments. In Fig. 4 is the winding 1 1 of the system between 5 and 0, the winding 12 connected between 0 and R. In system II, the weight 21 is between T and 0, the winding 22 between S and 0. The effect is similar to that according to vector image 7, but occur here Place the phase voltages for the linked voltages.

The device according to FIG. 4 monitors the equality of the phase voltages RO and TO. The second zageordinate device would, for example, have the equality of Monitor phase voltages SO and TO.

Here, in the case of symmetry, both the reusable and the idie vanish Part moments.

In Figure 5, winding 11 is like winding 12 of the system I connected between R and 0. At. System II are the two windings 21, 22 between S and 0. As a result, so-called E2 systems arise again, and the device monitors the equality of the star voltages RO and SO. In the case of symmetry the resulting moment disappears, but not the partial moments.

In FIG. 6, winding 11 lies between 0 and R, winding 12 between S and '0, the winding 21 between S and O and I the winding 22 between T and 0. The mode of action is again similar to {in FIG. 7, but disappears here in the case of symmetry only (the resulting moment, but not the individual moments.

Of course, other circuits are also possible; in certain circumstances Systems I and II can be combined in a common system in each device will. However, this is less advantageous because then the two devices are not can be regulated more independently of each other and the adjustment of the zero position Makes trouble.

In the exemplary embodiments, internal adjustments of 90 or 30 ° used for the individual drive magnets. However, you can also if you are on special measuring accuracy and high torque values, phase adjustments of Select I20 or 300, from 100 or I01 ° etc.; the sine function of the angle differences the adjustments will then be equal to I. On the other hand, if you deal with small Torques are satisfied, including internal adjustments of 90 and 6o0 or 60 and 300 wsw. use. How the various innards alignments are made is known in meter technology and will therefore not be explained in more detail will. For example, the 90 ° adjustment is carried out in the exemplary embodiment Use of the voltage drive magnets customary for Ferrari meters, the 30 ° adjustment by using the known current iron with a correspondingly high number of turns and upstream ohmic resistors 10, 20 achieved.

Since the two systems I and II are similar in each device and counteract each other, any errors in the two systems cancel each other out. This also boils for the so-called temperature, voltage and frequency errors. The invention also offers the following advantages: The torque of the devices grows with the square of the tension. As a result, there are small voltage imbalances already strong rashes. The two devices can be operated independently each other can be set, and from the specification of the device it can be easily seen which voltage has to be readjusted. During calibration or testing of a Blind consumption meter or the like need not be monitored by the two devices so that any imbalances are integrated in time and use it for an accurate The test is completely sufficient if the deflections are at the end of the test period at the latest of the two devices can be made to zero. The devices are also free of mechanical ones Retraction forces, that is, from springs or the like, which are known to be easy temperature errors or other disturbances and require precise adjustment.

Claims (4)

PATENT CLAIMS: I. Symmetry measuring device for calibration and testing of three-phase meters od. The like., characterized in that they consist of at least two integrating null devices with an anchor free of mechanical straightening forces, act on the at least two torques in opposite directions and only if they are equal the measured variables causing these torques cancel, and that one integrating Null device is the equality of two sides of the voltage triangle or star, the other monitors the equality of two other sides of the voltage triangle or star. 2. Symmetriemeßeinrichtung according to claim I, characterized by such a circuit and internal balancing of the integrating devices that the Angle occurring in the torque formula function of the phase angle between the voltages and flows of the individual devices as large as possible, and as much as possible is equal to I. 3. Symmetriemeßeinrichtung according to claim I and 2, characterized by such a connection and internal adjustment of the integrating devices that in every device in the case of symmetry not only no resulting, but at all no torque occurs. 4. symmetry measuring device according to claim 1 and 2, characterized in that that every integrating device has two counteracting at least in the case of asymmetry Drive systems with two magnetic windings each, which either are connected to the same Voltage or connected to two voltages that differ in phase by 600 are.