DE1056739B - Electrical compensation circuit - Google Patents

Description

GERMAN

The invention relates to a compensation circuit in which the power meter test to compensating voltage equal to the sum of the voltage drops at the normal resistor and at The divider resistance of the voltage circuit is, in the following, the total voltage compensation circuit called. Such compensation circuits are described in the publication »Stufenkompensatorkreiskreis for power meter testing with a single compensator setting "from" Scientific papers der Physikalisch-Technische Bundesanstalt ”, Vol. 8, 1956, Part 1, became known. In the Fig. 1 of the drawings is a compensator circuit for power meter testing with those disclosed in the publication known features shown.

According to FIG. 1, the circuit consists of the voltage circuit 1, the test circuit 2 and the compensator 3. The voltage circuit 1 consists of the source 4, which feeds the voltage path of the power meter 6 to be tested via a variable resistor 5. A voltmeter 7 and a voltage divider consisting of resistors 8, 9 are connected in parallel to the voltage path of the test object. The test circuit 2 consists of a current source 10 to which the current path of the test object 6 and a normal resistor 12 are connected via a variable resistor 11. Voltage circuit 1 and P call circuit 2 are galvanically connected to one another by line 13. The line 13 results in a series connection of the resistor 9 of the voltage circuit with the normal resistor 12. The compensator 3 is shown in greatly simplified form and essentially consists of the auxiliary power source 14, which is supplied via a variable resistor 15 to feed a compensation resistor 16, for example, provided with several taps serves. The prescribed auxiliary current is set by means of the compensation circuit consisting of resistor 17, normal element 18 and galvanometer 20, this being done in position H of switch 19. The test of the instrument 6 takes place in the position P of the switch. The zero galvanometer 20 is then arranged between the connection point of the normal resistor 12 and the current path of the test object and a fixed point of the compensation resistor 16. The variable tap 21 of the compensation resistor 16 is connected to the variable tap 22 of the divider resistor 9.

To set the pointer deflection of the power meter to be tested to the various scale divisions, the current / is changed. The voltage drop across the normal resistor 12 then changes proportionally to the current J, that is to say also proportionally to the electrical compensation circuit

Applicant:

LICENTIA Patent-Verwaltungs-G. m. B. H., Hamburg 36, Hohe Bleichen 22

Gerhard Busse, Berlin-Tempelhof,
has been named as the inventor

with the pointer deflection of the test item. The partial voltage to be compensated also becomes corresponding the voltage on the voltage path of the test object proportional to the deflection of the test object changed by adjusting the tap 22 on the voltage divider 9. The sum is compensated the voltage drops across the resistors 12, 9.

In order to achieve a simple operation of this device, the grinder 21 is expediently of the compensation resistor 16 is mechanically coupled to the wiper 22 of the divider resistor 9. This means that the divider resistor 9 must also be arranged in the compensator 3.

In principle, this results in a new compensation device which "is known" from Step compensators are distinguished by the fact that the compensation voltage occurring at the compensation resistor 16 adapted to the sum of the voltage drops occurring at the resistors 9 and 12 have to be. Furthermore, the testing of ammeters and voltmeters is not possible with this device possible.

The invention has set itself the task of performing the method for testing Power meters, in which the sum of the voltage occurring at the normal and divider resistance is compensated, new compensation devices with specially designed compensation resistors and the step compensators already used in practice for this process to be used for testing power, current and voltage meters. These well-known StufenkO'Hipensators. are known to be designed in such a way that their compensation resistor only a compensation voltage adapted to the voltage drop at the normal resistor or at the divider resistor occurs. The invention has also set itself the task that an application of these known per se Step expansion joints without interfering with

909-50W192

Claims (2)

these ready-to-use and calibrated body actuators should be possible with the above method Power meter test according to the total voltage compensation method the voltage of the auxiliary power source is doubled. The invention is explained in more detail with reference to the embodiments shown in FIGS. The basic design corresponds to the arrangement of the compensator according to FIG. 1. In contrast to the design of the compensator according to FIG. 1, however, in the known step compensators according to FIG. 2, the auxiliary circuit with the compensation resistor is designed and can be different cannot simply be used for testing power meters using the total voltage compensation method. This is due in particular to the fact that the compensation voltage occurring at the compensation resistor 16 (FIG. 2) is too small. In order to still enable a test of power meters according to the specified method without intervening in this known step compensator according to FIG. as indicated in FIG. 2 by the two auxiliary power sources 14 'and two normal elements 18'. If ammeters or voltmeters are to be tested, the compensator according to FIG. 2 is used again in its original form; That is, only one battery is used as the auxiliary power source, and again only one normal element is also used. The invention thus ensures that step compensators known per se, which are not readily suitable for the total voltage compensation method, are used to test power meters according to the total voltage compensation method by measures that do not require any intervention in the already operational and calibrated step compensators drive and be made suitable for testing ammeters and voltmeters according to the previously known method. 3 shows a further implementation of the concept of the invention. A step compensator 3, known per se, is used again, which cannot be used per se for the total voltage compensation method. This is made usable by the invention for testing power meters according to the total voltage method and also for testing ammeters and voltmeters without interfering with the internal circuit. The power meter test takes place again by means of the auxiliary batteries 14 'and the normal elements 18, 18', which are switched to the compensator by a switch 26 arranged outside the compensator (position L). When testing ammeters or voltmeters, switch 26 is thrown (position S), whereby a normal element is switched off. Furthermore, the auxiliary current flowing through the resistors 16, 17 is halved by the resistors 27, 28 which are then switched on, so that the compensation voltage occurring at the resistor 16 is reduced to half even during the current or voltmeter test switching is obviously not necessary. Patent claims: 1. Compensation circuit, in which the voltage to be compensated for testing the power meter equal to the sum of the voltage drops across the normal resistance and the partial resistance of the Voltage circuit is characterized by the use of a step compensator known per se, its compensation voltage in a known manner only that of the normal resistor or Partial resistance occurring voltage 'is adapted and at which for the power meter test the voltage of the auxiliary power source is doubled according to the total voltage compensation method is. 2. Compensation circuit according to claim 1, characterized in that all types of test the current drawn from the auxiliary power source remains constant. 1 sheet of drawings < 909 509/182 4.5Ϊ