DE853180C - Method for setting quantities in electrical circuits to a value multiplied by a fraction of the original quantity without calculation, in particular for setting magnetic motor or electrolyte counters - Google Patents

Description

Method for setting quantities in electrical circuits a value of the original size multiplied by a fraction without an invoice, in particular for setting magnetic motor or electrolyte meters The electrolyte meters have a parallel resistor to the measuring cell. The parallel resistance must be used for calibration adjusted so that the meter measures the current correctly. You go in As a rule, the electrolyte meter is used as the test item for a certain period of time is connected in series with a correctly pointing normal counter under load. The differences between the start and end points of the two counters are then determined. In addition, the voltage drop across the parallel resistor is determined when the load is set measured in the cell. In general, the details of both counters will not match and the voltage drop across the parallel resistor of the test object becomes more or less deviate significantly from the nominal value that is decisive for correct measurement. This setpoint can be determined arithmetically if you compare the actual value with that of the normal counter displayed power consumption multiplied and by the displayed by the test object Power consumption divided. The actual value of the parallel resistance must also be included be multiplied by a fraction. Only then can it be adjusted to the setpoint will. Since high measuring accuracy is required of electrolyte meters, this calculation must be made be carried out very precisely. This is time-consuming and includes sources of error. The same applies to the setting of magnetic motor counters and all the like Measurements, tests and calibrations for which a nominal value one The size of an electrical circuit multiplied by a certain fraction Actual value must be adjusted.

The invention has the task of reducing the time required for such a method to shorten, to exclude sources of error and to avoid arithmetic work.

According to the invention, in a compensator a denominator of Ides fraction corresponding resistance set and by equation of the Kompensatonstrons the voltage drop across this resistor of a voltage proportional to the actual value equalized, then the resistance of the compensator is maintained while maintaining the Current adjustment is set to a value corresponding to the numerator of the fraction and the actual value, i.e. the original variable, changed until equilibrium is reached again with the voltage drop of the newly set resistance.

Often the denominator or numerator of the fraction become algebraic sums be. So z. B. with integrating measuring devices that do not appear at the beginning of the measurement Zero can be set, but where z. B. the power consumption by forming the difference the end and start display must be determined.

In order to avoid calculating this difference, used a compensator or a compensator combination with two or more tapping points, however, such a circuit that at all points in the regulation of the compensator current this current changes evenly.

If one uses such a method for setting electrolyte or magnetic motor counters, then the shunt resistance is used as the actual value or original variable of the test item or the voltage drop on this test item, however, as the denominator of the Fraction by which the original size must be multiplied, the difference of the Test specimen information poor Start and end of an adjustment period during which the test specimen is connected in series with a normal counter, and as a numerator of the fraction the difference The start and end display of the standard counter within the same adjustment time used. Instead, you can also specify the normal counter for this adjustment time can be used if the normal counter is set to zero at the beginning of the measurement.

The invention is based on an example for the setting of a Magnet motor counter explained in more detail.

In the bottom of the drawing, Q is the current source (a rectifier circuit) the measuring arrangement indicated. The dot-dash rectangle P corresponds to a to testing magnetic motor counter (test item), the rectangle N a correctly measuring normal counter, which is connected in series with the device under test P, and the rectangle of no direct current compensation measuring device with the galvanometer G, the compensation resistors I, 2 and their taps 10, 20. The compensator current lnnn can be regulated by a resistor 3.

Resistors 4 are used to limit the current, i.e. to protect the galvanometer G if the adjustment is insufficient. The compensator K consists of the combination of two compensators I and II, the currents of which are equal to each other and through common the resistance 3 can be regulated.

5 is the test object's motor, 6 is its adjustable parallel resistor. The tap 7 of this resistor is with the tap 10 of the resistor I, the the other pole of the resistor 6 via the galvanometer G to the tap 20 of the resistor 2 connected. The resistor 8 can be used to set the load current of the counters P, N will. For the sake of simplicity, various switches, changeover switches, etc. are omitted, also measuring devices for currents, etc.

The setting of the test item P now proceeds as follows: The display device of the normal counter N is set to zero. The tap 20 is set according to the initial display of the test item P. The setting is made easier by a scale, decadic derailleurs or the like. To a decadal To enable setting, instead of the simple one shown in the drawing Resistor 2 in a known manner a cascade connection of resistors, like them is common for expansion joints.

Then the desired load current is regulated by means of the resistor 8 and remains switched on until the display device of the test object P is sufficient has moved on to get an accurate reading. According to the end position the display device of the test object P, the tap 10 is now adjusted. Simultaneously the end position of the display device of the normal counter N is read and noted or this counter is switched off so that its final display is retained. Resistance 3 is now adjusted until the galvanometer deflects G disappears. Then the tap 20 is set to zero and the tap 10 accordingly the end display of the normal counter N is set and finally the resistor 6 while maintaining the initially set load current until the deflection of the galvanometer G disappears for the second time. The test item P measures then right.

This can be explained as follows: After the attack has stopped 20 on the start display and the tap 10 on the end display lies between the two Attacks a voltage that corresponds to the power consumption measured by the test object P. This quantity is designated with B and corresponds to a resistance. Designated with e the original size of the voltage drop across the parallel resistor 6 and with i is the compensator current after the first adjustment has taken place, then if the The deflection of the galvanometer G has disappeared, e = c i B, where c contains the corresponding constants of the compensator. This gives e c # B After resetting the tap 20 to zero, the tap 10 to the end position of the normal counter N and after such an adjustment of the parallel resistance 6, that the galvanometer deflection G disappears the second time, the result is Voltage drop E across this resistor to E c i A, where X is the specification of the normal counter N let.

If one replaces i in this equation with the value calculated above, so we get E = e # A / B; d. H. the final setpoint value E is the same the original value e multiplied by a fraction, the denominator of which is that of the test item measured power consumption B and its counter is the power consumption measured by the standard meter A is. The setpoint therefore has the required size.

The invention offers the advantage that such measurements can be carried out without computing, Calculation errors and can be carried out in a relatively short time.

Claims (3)

PATENT CLAIMS: 1. Method for setting quantities in electrical circuits to a value of the original quantity multiplied by a fraction without calculation, characterized in that a compensator (K) has a denominator (B) of the fraction Corresponding resistance (I, set, by adjusting the compensator current (for example by means of resistor 3) the voltage drop across this resistor (I, 2) is made equal to a voltage proportional to the original variable (e.g. voltage drop at Wilderstand 6), then the resistance (I , 2) the compensator (K) while maintaining the current adjustment on one of the counter (A) of the fraction corresponding value is set and the original size (resistor 6) is changed until equilibrium with the voltage drop of the newly set resistor (I, 2) is achieved. 2. The method according to claim 1, characterized in that in the case of breaks, whose numerator or denominator forms an algebraic sum, this sum through application a compensator (K) with two or more tapping points (10, 20) or one Compensator combination (I, II) is formed. 3. Application of the method according to claim I and 2 to the setting of magnetic motor or electrolyte meters as the test item, characterized in that the difference as the original value of the shunt resistance (6) of the test item (P), as the denominator (fl) of the fraction (aluminum) the test specimen information at the beginning and end of an adjustment period during which the test specimen (P) is connected in series with a normal counter (N) under load, and as a counter (A) of the fraction the difference between the start and end display of the normal counter (N) is used within the same adjustment time.