DE1616390B1 - Combined electrical Wheatstone-Thomson measuring bridge - Google Patents

Description

The invention relates to a combined electrical Wheatstone-Thomson measuring bridge with two relationship branches lying in a parallel path to the measuring diagonal and with one or two balancing resistors for the measured value reading containing comparison branches.

The known combined Wheatstone-Thomson measuring bridges have the The disadvantage is that their measurement accuracy is only available in a narrow temperature range or even only maintained at a certain temperature. This fixed temperature is referred to as the nominal operating temperature of the measuring bridge (e.g. + 20 ° C).

The temperature range in which the measurement accuracy is within the permissible Limits remains, is referred to as normal operating temperature (e.g.

+2 ~ 1 ° C).

The temperature range for which the measuring bridge is intended is Specified operating temperature range (e.g. + 15 - + 30 ° C).

Does the temperature deviate from the nominal temperature or from a normal one Temperature in the operating temperature range, an additional display error appears, due to the different temperature response of the resistors in the bridge branches is conditional.

A well-known method for extending the operating temperature range of measuring bridges is that in the bridge branches resistors with special selected temperature range can be used.

However, the mentioned method requires a lot of effort and is only effective in a relatively small temperature range, this one The higher the accuracy demands on the measuring bridge, the smaller the temperature range are.

In addition, the measurement accuracy depends on the calibration accuracy of the individual resistances of the bridge branches and their temporal constancy.

The accuracy of the display of the bridge can be influenced by fluctuations over time the bridge resistance values are significantly reduced.

The invention is based on the object of a combined Wheatstone-Thomson measuring bridge indicate, in which an increase in the measurement accuracy both at nominal and normal temperature as well as at any temperature lying in the operating temperature range up to the measuring accuracy which approximates the mentioned nominal and normal temperature is guaranteed and the influence of a temporal instability of the resistance values is suppressed in the ratio branches of the measuring bridges on the measurement accuracy.

This task is performed with a combined electrical Wheatstone-Thomson measuring bridge of the type mentioned at the outset, according to the invention, in that a ratio standard A set of resistors is provided, which is divided into several, partly as fixed resistors, partly designed as variable resistors partial resistors is divided in such a way can be connected to one another by switches that after adjusting the set of resistors in such a way that the partial resistances are equal to one another in one position of the switch are, the resistance value of the first partial resistance from the one serving as the basic level Fixed resistance in relation to the resistance values of the other partial resistances from 1: iOn, where n is an integer or can be zero, and that the bridge Switching means has, with the help of which the set of resistors for zeroing the measuring bridge before the actual resistance measurement in each case with the formation of a Wheatstone auxiliary bridge first in parallel with the series connection from the one used in the Wheatstone Bridge Comparison branch and the adjoining relation branch and then in parallel can be switched to the two proportional branches, the partial resistances being the two Form the remaining bridge branches.

The invention is now based on an exemplary embodiment with reference explained in more detail on the drawings. It shows F i g. 1 the circuit of a Wheatstone bridge, F i g. 2 the circuit of a Thomson bridge, FIG. 3 a resistor circuit, which ensures a resistance ratio of 1: 9, FIG. 4 the circuit diagram of a ratio standard, 5 shows the basic circuit diagram of a Wheatstone-Thomson bridge according to the invention the ratio normal and a switching device, F i g. 6 shows a circuit example for a ratio branch of the bridge with balancing resistors.

First there are the known circuits of the Wheatstone and Thomson measuring bridges affronted.

The Wheatstone measuring bridge (FIG. 1) contains the resistance to be measured Rx, resistors R1, R2 and R3 of the comparison and ratio branches, a battery B and a zero indicator G.

The equilibrium condition for the measuring bridge is: R3 Rx = R1 -. (1) R2 The display error #Rx results from: ÇRS = bR1 + BR3-DR2- (2) Here # R1, # R2 and # R3 are the relative deviations of the resistance values from the nominal values of the respective resistors R1, R2 and R3.

Are the absolute amounts of the deviations bR2 and BR3 the same, i. H.

IR3I, (3) so #Rx = # R1. (4) The display error of the bridge becomes then only determined by the deviation of the resistor R1 from its nominal value.

Thus the possibility is to have an exact ratio R3: R2 1: ion too where n is an integer or zero, is a means of increasing accuracy the Wheatstone bridge both at any temperature in the operating temperature range as well as when the resistance values of R2 and R3 change over time.

In Fig. 2 shows a Thomson measuring bridge.

The bridge contains the resistance Rx to be measured, a normal resistance RX, resistors R, and R4 of the infinitely variable comparison branches, resistors R2 and R3 of the ratio branches, a resistance r of the connecting conductor, one Zero indicator G and a battery B.

The value of the resistance to be measured results from: R1 Rx = RN - + d (5) R2 with Most Thomson measuring bridges are designed so that the condition R1 = R4 R2 R3 (7) is always met.

If d = 0, R1 Rx = RN -, (8) R2 where the relative display error #Rx of the bridge is calculated using the formula #Rx = #RN + # R1 - # R2 (9).

Here RN, DR1, R2 are the relative deviations of the resistance values of the respective resistors RN, R, and R2 of their nominal values.

As with the Wheatstone measuring bridge, the display error of the Thomson bridge is mainly determined by the error in the normal resistance RN when the errors can be made negligibly small.

The following then applies to the display error: #Rx = #RN. (10) With the decrease of the absolute value d also decreases, which increases the measurement accuracy for low-resistance resistances.

To get exact resistance ratios R, and R, R2 are a set of resistances as a ratio standard and a switching device in the Wheatstone-Thomson measuring bridge introduced, whereby the ratio normal consists of several stages, the fixed and Have variable resistors with associated switches and connected to one another in this way are that after a comparison of the ratio normal the resistance value of one of his Levels that contain a fixed resistor and are considered the basic level, in a ratio for example 1: 1 or 1:10 to the resistance values of the other levels, while the switching device consists of one or more switches, with their The resistances of the ratio standard help the comparison branch first when adjusting the bridge and the subsequent relation branch and then the two relation branches in parallel be switched.

To get an exact ratio of two resistances, the property known per se of a group of resistors of the same nominal value used; the percentage error remains with both series and parallel connections of resistors of the same nominal value unchanged. There- through it is possible with high Accuracy to produce a ratio of two resistances of 1: a2, where a = Is 2, 3, 4, 5, 6, etc.

For a = 3 this ratio is 1: 9.

F i g. 3 shows a circuit that enables an accurate relationship from 1: 9. This circuit has series-connected resistors rl, r2, r3 and r4 and associated switches K, and Ka, which are connected in parallel of resistors r2, r3 and r4.

Are the resistances r2, r8 and r4 equal to each other and each equal 3 r, and if their actual values deviate only slightly from the nominal value, then when closing the switches Kl and K2, whereby the resistors r2, r, and r4 are connected in parallel the nominal value of the equivalent resistance of stage BC RBC (Aeq) = r1. (11) There the actual values of the resistors r2, rg and r4 deviate from their nominal values (because of inaccurate adjustment, change in resistance over time, influence of outside temperature and other factors). it is necessary to satisfy equation (11) and sufficient, one of the resistors in the Schar device according to FIG. 3 as an adjustment resistor to execute.

After equation (11) is satisfied and switches K1 and K2 are reopened, the RAB: RBC ratio is obtained with high accuracy = 1: 9.

F i g. 4 shows a ratio standard for obtaining an accurate resistance ratio 1: 1 and 1: 10, in which the values of the individual resistors are chosen as follows are: r6 + 0.5 r7 = r2 = rs = r4 + 0.5 r5 = 3 r1.

The stage CD is provided with switches K, and K2, with which from series connection of resistors r2, r3 and r4 plus r5 to parallel connection can switch.

The adjustment resistors r5 and r5 included in stages CD and BC r7 enable the resistances RCD (Aeg) and RBC to be compared with the one used as a reference resistance assumed resistance RAB.

F i g. 5 shows a basic circuit diagram of a Wheatstcne-Thomson measuring bridge.

The circuit contains the two mechanically coupled, continuously variable adjustable resistors R and R4 in the comparison branches and the two resistors R2 and R3 with balancing resistors R5 and R6 in the ratio branches.

The relationship branches can e.g. B. be carried out according to FIG. Here each resistance Ra, i (i = 1.2 ... m) corresponds to a certain balancing resistance R6,1, ....... l? 6.m.

The branch required in each case is set using switches K2,1, K2,2 ... K2.m switched on.

The circuit of the Wheatstone-Thomson measuring bridge contains a ratio standard, that from fixed resistors r1, r2, r3, r4 and r6 (Fig. 5) and variable resistors r5 and r7 consists, and a switching device, the mechanically coupled changeover switch 1, 2, 3, 4 and 5 and a switch 6 that is mechanically connected to switches K, and K2 is, have.

In switch position I of switches 1, 2, 3, 4 and 5, an adjustment is carried out of the ratio standard, in switching position II an adjustment of Ra to R1 and in switching position III the adjustment of R2 to R2 was carried out.

In switch position IV a Wheatstone Measuring bridge (the resistance Rx to be measured is applied to terminals P1 and P2).

In switch position V a Thomson measuring bridge is formed (the Resistance to be measured Rx is applied to terminals P1 and P2 and a normal resistance RN connected to terminals Ra and P4).

The measuring circuit also contains a zero instrument 7 and a battery 8th.

The method of operation with the measuring circuit is as follows: First, the comparison of the ratio standard is carried out. The partial resistance BC (Fig. 5) is added to the partial resistance by substitution with the aid of the variable resistor r7 AB aligned; here the switches 1, 2, 3, 4 and 5 are in position 1, the Switch 6 first put in position 1 and then in position II.

Then switch 6 is switched to position III. Here will be the switches K1 and K2 closed and the equivalent resistance RcD (Aeq.) with the help of the variable resistor r5 also matched by substitution to the partial resistor AB.

After the adjustment has been carried out, switch 6 is set to position IV (ratio AB: BC = 1: 1) or switched to position V (ratio AB: BD = 1: 10).

Switches K1 are in positions IV and V of switch 6 and K2 open.

Then a comparison of the ratio branches is carried out, resulting in minimal deviations should lead.

For this purpose, the ratio normal is assigned to the comparison branch R1 and the ratio branch R2 + R6 connected in parallel, forming a Wheatstone bridge (Fig. 5). Switches 1, 2, 3, 4 and 5 are set to position II. Then the ratio becomes normal set the ratio 1: 1 or 1:10, d. H. switch 6 in position IV or V brought. Resistance values of this type are found in the resistance branches R1 and R2 + R6 which result in the ratio 1: 1 or 1:10. By changing the resistance Ra the bridge is balanced so that the equation # R1 # = # R2 + R6 # or lOIRiI = I)? 2 + R61 is fulfilled.

Now the ratio is normal to the Branches R3 + R6 and R3 + R5 placed that a Wheatstone bridge results (Fig. 5). To this end switches 1, 2, 3, 4 and 5 are brought to position III.

The adjustment of the remaining resistance branches is now carried out according to the previously adjusted resistor R2 + R6 was made as the base resistor, by moving the switch 6 to the positions IV and V alternately on the Normally the resistance ratios 1: 1 and 1:10 can be set.

If the device only works in a Wheatstone bridge circuit, it is not necessary the adaptation of R2 + R6 to R1.

Claims (1)

Claim: Combined electrical Wheatstone-Thomson measuring bridge with two relationship branches lying in a parallel path to the measuring diagonal and with one or two balancing resistors for the measured value reading containing comparison branches, characterized in that a set of resistance (r1 to r7) is provided, which is divided into several partly fixed resistors (r1 to r4, r6), Partial resistors (AB, BC, CD), some of which are designed as variable resistors (r5, r7) is, which can be connected to one another by switches (K1, K) that after adjustment of the resistance set (r, to r7) in such a way that the partial resistances (AB, BC, CD) in one position of the switch (K ,, K are equal to each other, the resistance value of the first partial resistance (AB) from the fixed resistance serving as the basic level (r,) in relation to the resistance values of the other partial resistances (BC, CD) of 1: 10n, where n is an integer or can be zero, and that the bridge Has switching means (1 to 6), with the help of which the set of resistance (r1 to r7) to zero the measuring bridge prior to the actual resistance measurement under Form a Wheatstone auxiliary bridge first in parallel with the series connection the comparison branch (R,) used in the Wheatstone bridge and the one attached to it subsequent ratio branch (R2 + R6) and then parallel to the two ratio branches (R2 + R6, R3 + R5) is switchable, with the partial resistances (AB, BC + CD) the two Form the remaining bridge branches.