DE969874C - Method for measuring alternating current quantities - Google Patents

Description

Procedure for measuring alternating currents The invention relates to a method for measuring alternating current quantities using the secondary voltage a transformer connected in series with an air gap choke to an AC voltage with an iron core showing a sharp saturation knee, the primary side up to is magnetized in the saturation range and its residual rise of the induction above of the saturation knee by an additional, from the primary current to the secondary winding induced voltage is compensated, as a comparison voltage. Such an equivalent stress enables the measurement methods for direct current quantities to be carried out using of normal elements, for example the Weston normal element, analog measurements of alternating currents, such as alternating voltage, alternating current resistances and the like.

The use of transformers magnetized down to the saturation area, the iron cores of which have a sharp saturation knee, preceded by a Air gap choke for voltage stabilizers in power supply units, for keeping voltage constant in three-phase networks and the like is already known. Through the present invention The secondary voltage of such transformers is now a measurement method for AC quantities used as a basis for comparison, which is directly included in the measurement process, whereby Precision measurements of alternating current quantities are possible, which are based on the comparison measurements of direct current quantities based on a normal element are equivalent are. The inventive method for measuring alternating current quantities using the secondary voltage of an alternating voltage in series with an air gap choke lying transformer with a showing sharp saturation knee Iron core, which is magnetized on the primary side up to the saturation area and its Residual increase in induction above the saturation knee by an additional, vom Primary current in the secondary winding induced voltage is compensated as Comparison voltage is characterized by the fact that one of the alternating current values to be measured proportional AC voltage after rectification with a mechanical precision rectifier with the rectification of the temporal mean of the size of the Primary current independent secondary voltage of the transformer with a mechanical Precision rectifier obtained with appropriate setting of its contact time corresponding to their arithmetic mean and the frequency of the primary current proportional normal stress is compared. The circuit is expediently like this selected that the voltage of the frequency proportional to the alternating current variable to be measured the alternating current quantity to be measured or the frequency of the voltage applied to it is proportional. Have both the reference voltages and the one to be measured AC magnitude proportional voltage the same frequency, so can the whole Measurement process can be carried out independently of the frequency, and it allows the absolute measurement of alternating current resistances, alternating currents or alternating voltages. This is also a particular advantage of the proposed method over others, Compensation measurement methods of alternating currents using rectifiers on the basis of normal elements, since this method is not in the present Type are frequency independent. If the alternating current quantity to be measured is not itself AC voltage or no AC current, e.g. an AC resistance, so it must be fed by a suitable voltage.

It is advantageous to use a chopped direct current for this purpose, its amplitude using one the same number of contacts as the chopping one mechanical rectifier owning further mechanical rectifier means Normal element and normal resistance can be measured absolutely in a known manner. Any temperature dependency of the saturation induction of the transformer that may still occur can be achieved by a combination of resistances of different temperature coefficients compensate in its secondary circuit.

The method according to the invention is explained in more detail with reference to a few drawings explained. Fig. I shows the circuit for obtaining an arithmetic mean time constant voltage from an alternating voltage. The I is the iron core of a transformer with an approximately right-angled kinked magnetization characteristic as shown in Fig. 2, for example. The primary winding this iron core is connected to an alternating voltage via a series reactor 2 with an air gap U.

The secondary winding 3 of the iron core is in a circuit in Series with a periodically synchronously operated mechanical rectifier 4, at the contact time and its phase relation to the voltage U within wide limits adjustable (vector knife). There is also a moving coil instrument in this circuit 5 and a series resistor ".

If the series reactor 2 is used to increase the current i in the primary circuit an amount so large that the iron core I is almost saturated is obtained a voltage on the secondary winding 3, the instantaneous value of which is dB = wq dt Darin w is the number of turns of winding 3, q is the iron cross-section of core I. The voltage With a sinusoidal supply voltage U, X does not have a sinusoidal shape, but a temporal one Course, as shown for example in FIG. 3. If you put the voltage X over the synchronously operated measuring contact 4 to the moving coil instrument 5 and one sets his Switching times so that switched on at time t1 and switched off at time t2 the moving-coil instrument shows a voltage? so = fd t = 2fwqBs.

Here f is the frequency of the alternating voltage U and Bs the maximum value the induction, up to which the current i magnetizes the iron core 1. When the stream i is sufficiently large, Bs is the saturation induction of the iron, which is then practical becomes independent of small fluctuations in the current. In this case the tension is X practically almost independent of the voltage U and almost proportional to it the frequency f.

To the low dependence of the induction Bs on the current i and at the same time to eliminate their dependence on the temperature, an arrangement according to Fig. 4 can be selected. I is again the iron core, 2 the series reactor, the are in series with the input AC voltage U. The secondary winding3 of the iron core is connected opposite in series with the secondary winding of a mutual inductance M. rl, r2 is a voltage divider. The mutual inductance M is one of the current i in the primary circuit proportional voltage to the additionally induced which is so matched and is of such a direction that it is that of the small rise in the saturation induction Bs with the current i resulting voltage just compensated. The voltage divider rl, r2 consists of a copper resistor rl, which is wound together with the toroid I is kept at the same temperature as the iron, and off an upstream manganine resistor r2. One denotes the temperature coefficient with fl of iron at the induction of saturation and with a the temperature coefficient of the Resistance rl, then r2 = ß ru afp must be made so that the dependence of the Induction Bs is being compensated by the temperature. That way it gets one a voltage «, its arithmetic created with the mechanical rectifier Average value independent of the input voltage U and independent of the temperature a largely constant, the frequency exactly proportional amount Has. The arrangement can consequently be referred to as normal alternating voltage. Instead of the voltage divider r1, r2 one can also use the voltage «*, the temperature Measure the iron core and attach a corrector.

The temperature coefficient of iron-nickel alloys as they are for suitable for the present purpose is about 5 Io-4 / ° C.

This normal voltage is used to measure alternating currents compared to an alternating voltage proportional to the alternating current variable to be measured. Such a circuit for the absolute measurement of mutual inductances is shown in FIG. 5. The circuit in the left part is essentially identical to the circuit Fig. 4. At the resistor r1 a voltage is tapped, which by means of a mechanical Synchronous rectifier K1 rectified and a further voltage divider, consisting from the resistors R1, R2, R3 is supplied. At one of these resistors, and although at R1, a voltage X is tapped. The right part contains the circuit a circuit consisting of a battery B, a normal resistor Rn, a variable series resistor Rv, a mechanical synchronous switch K4 and the Primary winding of the mutual inductance to be measured M2.

The secondary winding of the mutual inductance M2 is via another mechanical synchronous rectifier K2, a resistor vn, a galvanometer G and a choke D connected to the voltage X.

The voltage drop across the resistor Rn is measured by means of a normal element NE, a mechanical synchronous rectifier K3 and a galvanometer G2. Through the contact K4, the primary current J of the mutual inductance M2 is periodically interrupted and closed in time with the alternating voltage U. This creates a pulsating current, the course of which is shown over time in FIG. 6. Tk denotes the contact time of switch K4. At the switch-on and switch-off times tein and tau, this current generates voltage pulses on the secondary winding of the mutual inductance M2, the course of which is shown in FIG. If the mechanical rectifier K2 is set in such a way that it closes at time tal and opens at time t2, a voltage develops across resistor rn, the mean value of which over time is: If this voltage is compensated for against the normal voltage, as indicated in FIG. 5, the equilibrium condition obtained, ie for the case of no current in the galvanometer G1: u = const R1 = fMJ, R1 + R2 + R3 tr1 M = const RJ Rl + R2 + R3 + rl The constant can be determined by calibration with a normal element at normal frequency. The current J can also be compensated with a normal element in the manner indicated in FIG.

A measuring contact K3 is used in the compensation circuit Contact time is set to times t3 and t4. If you choose, for example R 1 Q (normal resistance), then J becomes I, OI83 A. In this way, M can be derived from the Calculate the resistance ratio R1 R1 + R2 + R3 $ r1. The resistance rn (for example rn = 10000 Q) is necessary in order to flow a continuous direct current in the galvanometer G. allow. It loads the mutual inductance M, the resulting voltage drop can be made up of rn and the ohmic resistance of the secondary winding of the mutual inductance be calculated.

For the absolute measurement of capacitances, a circuit according to Fig. 8 can be used. The left part of the circuit corresponds to that of FIG.

In the right part the circuit contains a battery B, resistors R and Rv, a normal element NE, a galvanometer G2 and synchronously operated mechanical ones Switches K3 and K4. The unknown capacity is denoted by C. The measurement takes place similar to the arrangement of FIG. that is, the voltage appearing across the resistor rn is countered the normal stress compensates. Does one have capacities or in the specified manner Mutual inductances measured absolutely, they can be used with the inventive Method of measuring alternating currents or voltages absolutely with great accuracy. For this purpose, for example, the mutual inductance M2 in FIG. 5 is fed with chopped direct current with the alternating current to be measured.

The voltage rectified with K2 then becomes In this way the peak value f ,,, ax of the alternating current is measured in its absolute value with the accuracy of the compensation method. In this case, somewhat higher requirements are placed on measuring contact K2. Its contact time must be as precise as possible I80 ". The secondary voltage at M2 is indeed zero even with a sinusoidal profile of J at switching times t1 and t2, but the slope of the voltage curve with respect to the zero line is greater than in FIG. 3 or 6.

As with all compensation methods, the specified procedure must the most careful attention to grounding.

Claims (4)

PATENT CLAIMS: I. Method for measuring alternating current quantities using the secondary voltage one in series with an air gap choke at an alternating voltage transformer with a sharp saturation knee having iron core, which is magnetized on the primary side up to the saturation area and its residual increase of induction above the saturation knee by an additional voltage induced by the primary current in the secondary winding is compensated, as a comparison voltage, characterized in that one of the to measuring alternating current quantity proportional alternating voltage after rectification with a precision mechanical rectifier with the by rectifying the in their Secondary voltage independent of the magnitude of the primary current over time obtained from the transformer with another mechanical precision rectifier, if its contact time is set accordingly, its arithmetic mean corresponding normal voltage proportional to the frequency of the primary current is compared. 2. The method according to claim I, characterized in that the AC variable to be measured voltage proportional to the frequency of the to be measured Alternating current magnitude or the frequency of the voltage applied to it is proportional. 3. Process according to Claims I and 2, characterized in that the alternating voltage corresponding to the alternating current quantity to be measured by a generated by a mechanical rectifier chopped up direct current, its amplitude using another mechanical rectifier by means of Normal element and normal resistance is measured absolutely. 4. The method according to claimI, characterized in that the compensation the temperature dependence of the saturation induction by a combination of resistors different temperature coefficients takes place. Publications considered: German Patent No. 593 073; U.S. Patent No. 2,058,302; Krönert: "Measuring bridges and compensators", 1935, Vol. I, pp. 6016I and I421I43; Maier: "Trockengleichrichter", 1938, pp.24I, 242; "Archives for technical measuring" (ATM), sheet J 921-11 (November 1936); "Magazine for technical physics «, 1933, volume II, pp.474 to 477; "Siemens Zeitschrift", vol. I8, August 1938, issue 8, p.399; Journal "Elektrotechnik", Vol. 2, 1948, issue 1, pp. II to 14. Older Patents Considered: German Patents No. 756 373, 856 336.