DE733025C - Arrangement for compensating the angle of error of a resistor - Google Patents

Description

Arrangement for compensating the angle of error of a resistor is known A wire resistance always has an angle error, even with a bifilar winding, which is among other things with the strength of the wire, i.e. the resilience of the resistor grows. As is also known, this error can be eliminated by connecting a suitable one in parallel Capacitor to eliminate resistance, the capacitor to be the larger must, the smaller the resistance and the higher its resilience. One comes like that with small, highly resilient resistors to capacitance values that are around 100 µF.

That means a considerable amount of material and space, which is special has a disadvantageous effect when it comes to using a large number of resistors, z. B. that of a precision resistor box to make angular error-free. aside from that The more difficult the capacitor increases with the required capacitance value to match exactly to the required size.

The invention is based on the idea that there is a measuring circuit, in which a voltage taken from the circuit, like the adjustment voltage at a bridge circuit, which is practically not subject to current, is not required, the current flowing through the resistor in phase with the voltage drop across the resistor to bring, but that in this case it is sufficient if one is always connected to the current proportional and in-phase voltage generated. According to the invention is therefore the series connection laid parallel to the resistance I, which is afflicted with the angular error of the compensation capacitor 2 and compensation resistor 3 are dimensioned in such a way that that the voltage to be tapped at the compensation capacitor is in phase with the total current is.

The circuit is shown in FIG.

In the above-mentioned dimensioning of the compensation elements, the Voltage to be tapped off at the compensation capacitor, i.e. at terminals 4 and 5 in phase with the current flowing through resistor 1.

Since the capacitance of the compensation capacitor becomes smaller, the greater the compensation resistance in relation to the wrong angle Resistance is chosen, the compensation resistor is preferably so dimensioned so that it is a multiple of the value of the resistance subject to incorrect angles amounts to.

An error compensation by a counter was connected in parallel Series connection of a compensation capacitor and a grain compensation resistor is known in DC rectifier measuring circuits, the compensation capacitor and the compensation resistor are dimensioned so that a to the rectifier circuit connected DC current meter correctly displays over a wide frequency range. Here, however, no voltage is tapped from the compensation capacitor.

The size of the capacitor required depends on the size of the The error angle and the operating frequency depend on the size of the compensation resistor 3 from. Since this can be made many times larger than the resistance I, it is therefore possible through the arrangement according to the invention to compensate for an incorrect angle to achieve with relatively small capacitors. Another advantage is that here a simple and easy adjustment for base equality by changing of the compensation resistor is possible, so that with large capacitance values particularly annoying balancing of the capacity is no longer necessary.

Another advantage is to be seen in the possibility of the offset angle compensation can be achieved for any frequency by readjusting the compensation resistor, while in the birch arrangement, which only used a fixed capacitor, a sufficiently precise error angle compensation only for a limited frequency range entered. Appropriately, the variable compensation resistor is given an in Assign frequencies to calibrated scale.

As an example of the application of the invention, FIG. 2 shows its use shown in a Schering bridge, except for the error angle compensation according to the invention of the resistor I located in one branch of the bridge is built up in the usual way is. 2 and 3 are here again the corresponding compensation elements as in Fig. 1.

In general, it will be desirable to select a larger or larger to be able to put smaller resistance in the bridge branch.

An expedient embodiment of the arrangement according to the invention for this case is shown in Fig., in which only the urgent bridge branch is drawn out.

The resistance is in the chosen representation in six in series lying partial resistors 6 to 11 divided, to which the compensation resistors 12 to I7 are assigned in the manner shown in FIG.

The compensation resistors 12 to I 7 are adjusted so that that there is always angular freedom with the same capacity, so that despite different Resistance values in the bridge branch with a compensation skondensator 2 gets by.

It is expedient to use one of the six stages in the above example Provide step switches with contacts 18 to conveniently set the individual resistance values to be able to set, and him with a second corresponding step switch couple the contacts 19, so that inevitably always the correct compensation resistor is switched on for the resistance value that has just been set.

Of course, you can also use a double plug instead of a tap switch Use pins that are appropriately unequal in strength, the one in appropriately arranged and connected socket pairs 18, 19 fits.

Claims (2)

PATENT CLAIMS: I. Arrangement for compensating the angle of error of a resistor, a series connection of a Kolmpensationsko ndensators and a compensation resistor is connected in parallel, in a measuring circuit in which one removed from the circuit Voltage, like the adjustment voltage in a bridge circuit, is practically not subject to current is, characterized in that the compensation capacitor and preferably a multiple of the value of the resistance subject to incorrect angles be bearing compensation resistance are dimensioned such that the voltage to be tapped off at the compensation capacitor r is in phase with the total current. 2. Arrangement according to claim 1, characterized in that with steady or a gradual change in the resistance associated with the defective angle Compensation resistance is inevitably also changed so that angle error compensation always occurs with the same compensation capacity.