DE1285615B - DC compensator measuring arrangement and procedure for automatic control and subsequent calibration of the same - Google Patents

Description

The invention relates to a DC compensator measuring arrangement, which have a self-adjusting zero indicator and at least two separately fed Compensation circles contain in which variable resistors and decades of compensation resistors and the associated switch are switched on. Find such compensators widely used in measurement technology, specifically for the direct measurement of an unknown EMF using the voltage compensation method.

For example, a known direct current compensator consists of two separate circuits and a galvanometer as a zero indicator. Each of these In principle, both circuits form an independent compensation circuit. To the The voltages of the two compensation circuits are used to measure the unknown voltage added and switched to the unknown EMF via the zero indicator.

A comparison takes place automatically on the zero indicator, so that you can read off the unknown emf from it. There are in the two compensation circles various resistors are provided, which can be selected by means of a crank switch can be switched on in order to achieve the correct compensation voltage.

When measuring an EMF with the voltage compensation method, the result is the ratio of the EMF size to be measured to the EMF size of the normal element basically as the ratio between two resistances, these resistances a constant current, common to both resistors, flows through it. The precision of the compensator is accordingly perfect due to the accuracy of the ratios determined between the resistances. The endeavor, the measuring accuracy of the compensators to increase has resulted in numerous circuit arrangements and improvements in the Compensators used resistors out. The ever increasing demands which are placed on the measuring accuracy of the compensators, do not leave any neglect the measurement error that cannot be completely eliminated even with careful production to. In addition, the measurement errors do not remain after the expansion joints have been manufactured constant because the resistances used inevitably change over time and change under the action of temperature fluctuations. From these facts it follows that a high level of accuracy of the compensators can only be achieved in practice leaves, if at some time intervals during use a possibility for the Accuracy control of the same is possible with sufficient precision.

There are several different methods of checking the accuracy of Known compensators.

Most of these known methods require use of normal measuring devices, which must have an even higher accuracy than the compensator to be controlled. Have the standard measuring devices used for control also own measurement inaccuracies, which affect the accuracy of the control of the compensators act. While there are some methods of reducing these effects, but practical application of these methods encounters difficulties as to the compilation and calibration of the special control circuit arrangements, and the results of the control are substantially different Experience of the compilation, Calibration and control dependent on the personnel carrying out the work.

If the expansion joints are more precise, their accuracy will be checked even more difficult during their use. This fact stands essentially the creation of new, even more precise expansion joints and their application of known expansion joints.

Another disadvantage of the known expansion joints is that that they have no special arrangements which can easily be reduced or elimination of those when checking the compensator in use allow determined inaccuracies. The need to get the tolerance values for the Calculating compensator measurement results leads to a significant one in a measurement process Loss of time.

The invention is therefore based on the object of a compensator measuring arrangement to create, which does not have the above disadvantages, but which is capable of a Check the accuracy while using the compensator.

The invention relates to a DC compensator measuring arrangement with at least two separate and independently fed Compensation circles, the variable resistors and decades of compensation resistors have, as well as a self-balancing zero indicator and a crank switch for setting the resistances and connecting the two compensation circuits in series when measuring the unknown emf.

According to the invention are for automatic accuracy control Measurement arrangement the two compensation circuits via the self-adjusting zero indicator by means of the crank switch and some additional contacts and current taps switchable against each other, whereby the differential voltage measured at the zero indicator serves as a measure for the recalibration of the compensation circuits.

To control the measuring arrangement are in this way one after the other the differences between the tensions at each stage of the smaller decade and the voltage at its first stage, the difference between the counter voltage, which lies on the ten levels of the smaller decade, and that on one level of the next greater decade of voltage, etc., measured for each decade. Also measures one the difference between the voltages applied to the in the manner described divided variable resistor and on the corresponding (according to their nominal value) parts of the decades of the compensation resistances.

With this new circuit arrangement, a control of the Carry out a compensator with any precision directly at the measuring station, without doing anything having to use any standard measuring devices. Another advantage of the invention consists in the fact that the measurement inaccuracies involved in the control of the compensator can be determined directly at the measuring station.

The new circuit can improve in various types of expansion joints with fundamentally different electrical circuits are used will.

The invention is illustrated below with reference to the figure, for example explained in more detail.

The DC compensator consists of the self-aligning Zero indicator 1 and from two separate and independently powered circuits. Each of the two circuits serves as a separate compensator. In the first circuit are the source 2, the variable resistor 4, a rheostat, the normal element 5, the connection 6 for connecting a separate zero indicator and the self-adjusting Zero indicator 1; furthermore two resistance decades 7 and 8, which are used as compensation resistors to serve.

The source 3, a variable resistor (not shown), a variable resistor and the two resistance decades 9 and 10.

The resistance decades 7 ... 10 are by means of their taps with the Sliding contacts 21 ... 24 of the crank switch 12 connected. About these sliding contacts move the measuring brushes 25 ... 28, which establish an electrical connection between the Establish sliding contacts 21 ... 24 and the contact rings 29 ... 32. Using the Measuring brushes are defined, decadically graded on the resistance decades 7 ... 10 Voltage units can be tapped, e.g. B. the tens of millivolts from decade 7, the ones of millivolts from the decade 8, the tenths of millivolts from the decade 9 and hundredths of millivolts from the decade 10.

The crank switches have the additional control brushes 33 ... 36, which are mechanically connected to the measuring brushes 25 ... 28 and offset by one step are. The control brushes 33 ... 36 make electrical connections with the contact rings 37 ... 40 of the crank switch.

In the contact rows 21 and 23 of the decades 7 and 9 are additional Contacts 41 and 42 are provided, which with the end contacts of the contact rows 22 and 24 of the next smaller decades 8 and 10 are connected. Contacts 41 and 42 are offset by one step compared to the zero contacts of decades 7 and 9.

This multiple switching device is designed as a crank switch 12, the brushes 13 ... 15 owns. The self-adjusting zero indicator 1 is by means of the brushes 13 and 14 of the crank switch 12 between the two arbitrarily with the corresponding contacts the contact rows 16 and 17 connected points can be connected.

The brush 15 is mechanically coupled to the brushes 13 and 14 and connects to each other two corresponding contacts in the contact rows 18 and 19. The crank switch ensures all the necessary connections between the zero indicator 1 and the two compensation circuits.

When the crank switch 12 is in a position, the measurement of the the terminals 11 to be connected unknown voltage Ex made in a known manner. The other positions of the crank switch are used to measure the differences between the Tensions that are applied to the resistors of the compensator when one is independent Want to make control.

If you check the compensator yourself, the differences of several connected to the different resistances of the two circuits Tensions measured. Therefore, the crank switch 12 has a corresponding number of contacts in contact rows 16 ... 19 that start with the corresponding points of the both circuits are connected.

For the sake of simplicity, not all details are shown, since the invention is also so understandable.

The variable resistor consists of several resistors to which over several taps 20 decadic voltages can be tapped, which according to their Setpoint equal to the values of the voltages applied to the resistance decades 7 and 8 are.

The steps of the resistance decades 7 ... 10 and the parts of the variable resistor 4 are with the constant, significantly larger shunt resistors 43 and with the to adjustable calibration resistors44 lying in series with the shunt resistors 43 Mistake.

When measuring the unknown voltage Ex (not shown), which is connected to the terminals 11, one sets the crank switchl2 in the first position from the left. The brushes 13 ... 15 take the position shown one, and the two voltages of the two circuits are known in a known manner added.

The resistance decades 7 ... 10, which are used as compensation resistors serve, are set so that the voltages Ui and U2 are applied to them, their Sum is equal to the presumed value of the unknown voltage Ex. These compensation voltages are switched against the voltage to be measured via the zero indicator 1. Of the self-balancing zero indicator 1 therefore equals the part of the unknown voltage Ex, which does not depend on the sum of the voltages on the compensation resistors is compensated.

Independent control of the expansion joint is carried out as follows made: You first set the current in the with the help of the normal element 5 both circuits. Then the measurement of the difference between the voltage on one stage of decade 8 and the voltage on the other stages same decade. The crank switch 12 is set to for the measurement position determined by the voltage differences. In this position of the crank switch 12, the brushes 13 ... 15 have been moved one position to the right, i.e. they are standing in the second position from the left.

In this position of the crank switch 12, its brushes 14 are located and 15 on the contacts of rows 17 and 19, which are not through those in the figure shown lines with the contact rings 40 and 32 of the switch of the decade 10 are coupled.

In the same position of the crank switch 12, its brushes are 13 and 15 on the contacts of rows 16 and 18, those by not shown Lines are supplied with the voltage of a section of the circuit to the source 2 this voltage with respect to that taken from the steps of decade 10 Voltage has opposite polarity. The voltage difference is given by the self-adjusting zero indicator 1, which is constantly between the brushes 13 and 14 is measured automatically.

Then by means of the rule arrangement of the source 3 is a current set in the second compensation circuit so that the display of the zero indicator 1 goes to zero. The voltage at the resistors of decade 9 then agrees corresponds to the voltage at the first stage of decade 8.

Then, by means of the switch for the decade 10, each stage of this Decade without changing the current in the two compensation circuits one after the other switched on and the voltage difference between each stage of the decade 10 and that stage for which the current control is carried out, measured.

Similarly, if the crank switch is in the appropriate position 12 and by means of decade 9 the differences between the voltages at one of the Decade 9 steps and the voltages measured at each of the remaining steps.

When the switch is set to zero for decade 9, the Differences between the full voltage on the ten steps of decade 10 and the Voltage measured at a stage of the next higher decade 9. In the same The sequence is the voltage differences of all decades as well as the differences between the voltages of the setting resistor 4 and their nominal value corresponding voltages of the measuring decade resistors measured.

A calibration can be carried out according to the results of the automatic control of the DC compensator to ensure the accuracy of its measurement results to increase. The differential voltages measured during the control are used for this purpose with the help of the variable calibration resistors 44, which the levels of Resistance decades 7 ... 10 and the variable resistor 4 are connected in parallel.

The self-adjusting zero indicator 1 is obtained by comparing it with the voltages at the compensation resistors of the compensator controlled and calibrated if calibration is necessary. After that, the tension at all Decades of resistance and variable resistances checked and calibrated again.

The results of the control can not only be used for reducing the measurement tolerances through the calibration, but also for the determination of the exact The value of these tolerances are used to determine the correction values of the measurement results capture.

The invention makes it possible to use the DC compensator to be controlled to carry out a control and recalibration of the same at the measuring station, with any Measurement accuracy can be achieved.

Claims (1)

Claims: 1. DC compensator measuring arrangement with at least two separate and independently fed compensation circuits, which have variable resistances as well as decades of compensation resistances, as well as a self-adjusting zero indicator and a crank switch for adjustment the resistances and series connection of the two compensation circuits in the Measurement of the unknown EMF, characterized by the fact that for automatic Accuracy control of the measuring arrangement the two compensation circuits over the self-adjusting Zero indicator (1) using the crank switch (12) and some additional contacts (41, 42) against other switchable and the differential voltage measured at the zero indicator (1) serves as a measure for the recalibration of the compensation circles, 2. Arrangement according to claim 1, characterized in that the variable resistor (4) is provided with taps (2 (e) which subdivide the same, with the voltages applied to the partial resistances the voltages at the steps of the decades (7, 8) of the compensation resistances of the same Circuit are the same. 3. Arrangement according to claim 1, characterized in that in the Contact rows (21, 23) of the crank switch (12) at a distance of one switching step of the zero point of the additional contacts (41, 42) that are larger according to their value are arranged with the contacts of the contact rows (22, 24) of the next smaller Electrically connected decade of compensation resistances of the same circuit and their arrangement makes it possible to connect to the mentioned two contacts, i. H. to the Zero and additional contact to tap the full voltage that occurs on the smaller decade lies. 4. Arrangement according to claim 1 and 3, characterized in that the Crank switch (12) besides the brushes (25 ... 28) additional brushes (33 ... 36) which are offset by one switching step from the brushes (25 ... 28) and with the help of which in carrying out the automatic control of the direct current compensator both the tension at the individual stages of the larger decade in terms of their value as well as the full voltage on the next smaller decade of the same circuit can be tapped. 5. Arrangement according to one or more of the preceding claims, characterized in that the control and compensation resistors (4, 7 ... 10) are provided with parallel electrical circuits consisting of a variable Calibration resistor (44) and an unchangeable one connected in series with it Resistance (43) exist, which is greater than the bridged resistance. 6. Procedure for automatic control and subsequent calibration the DC compensator measuring arrangement according to claims 1 to 5 by determining the Corrections based on the voltage differences displayed on the zero indicator, characterized in that the differences between the voltage at a stage the decade of the compensation resistors and between the voltage on each of the others Stages of this decade one after the other, that also the differences between the full Tension on the ten levels of the decade and the tension on one level of the next higher decade and the differences between the voltage on the sections of the set resistance and the voltages corresponding to the size be measured at the compensation resistors that then these voltage differences by calibrating the adjustable resistors, the setting and compensation resistors are connected in parallel, brought to a minimum and then the self-balancing Zero indicator by comparison with the tensions on the decades of the Compensation resistors checked, if necessary the subsequent calibration of the zero indicator carried out and the exact verification and calibration of the voltages at the compensation and setting resistors is performed.