DE1058146B - Device for measuring the quotient of two resistances - Google Patents

Description

GERMAN

The invention relates to a measuring device in which a quantity to be measured is in the form of a resistor change occurs and the quotient of this resistance and another resistance is measured in such a way that that the first resistor in series with an auxiliary voltage source between the input terminals of a Amplifier with negative feedback, the output voltage of which, if necessary after further amplification, is measured.

The invention aims at such a device in which the scale of the measuring instrument is linear with respect to is the conductivity of the resistance element in the input circuit.

The invention further aims to make the device suitable for a large number of measuring ranges, wherein the linearity is maintained in all measuring ranges.

The invention is characterized in that the second resistor is in series with an impedance above which the output voltage or a proportional voltage results in the feedback circuit connected between the input terminals of the amplifier.

In order to eliminate the effects of stray capacitances and leakage resistances, the first mentioned Resistances or conductivities attached in a special way, namely preferably the output circuit from a self-induction coil to which the measuring alternating voltage is inductively transmitted, and the first resistor and the feedback circuit of a second inductively coupled to the input circuit Self-induction and the second resistor, the resistances at those of the self-inductions mentioned remote ends are connected to a point of constant potential (earth).

Preferably find for supplying the measuring alternating voltage and for discharging the current to be measured Use double-shielded transformers, with one of the shields of each transformer immediately connected to ground and the other connected to the input electrode of the amplifier.

To switch the measuring range, the second resistor is designed to be exchangeable.

In addition, the invention provides a device which is used for measuring the specific conductivity of Electrolytes are suitable. If here the second resistor consists of a so-called reference line, i. H. one Measuring cell which is filled with a liquid whose properties correspond to those of the liquid to be measured and which is exposed to the same conditions with regard to temperature, results in an automatic one Temperature compensation.

The invention is explained in more detail below with reference to the drawing.

Device for measuring the quotient of two resistances

Applicant:

NV Philips' Gloeilampenfabrieken,
Eindhoven (Netherlands)

Representative: Dr. rer. nat P. Roßbach, patent attorney,
Hamburg 1, Mönckebergstr. 7th

Claimed priority:
Netherlands of May 22, 1957 and February 19, 1958

Pieter Geert Kuipers, Eindhoven (Netherlands),
has been named as the inventor

Fig. 1 shows the circuit arrangement of an embodiment,

2 shows an equivalent circuit diagram,

Fig. 3 shows the arrangement of two cells, while
Figures 4, 5 and 6 illustrate further embodiments. "An oscillator which supplies a measuring voltage, the frequency of which can be, for example, 80 to 1000 Hz" is connected to terminals 1. With the help of the transformer Tl with the windings 2 and 3 and the panels 4 and 5, the measuring voltage is transmitted to the input circuit of a Verstärkefs Vl. The Έΐη-gang of the amplifier also contains an element with a resistance 1 / Z ₁ in series with the winding 3! The amplifier can, for example, contain a push-pull stage as the output stage, which is connected to the primary winding 6 of the transformer Γ2. This transformer has two secondary windings, of which one winding 7 is double-screened against the primary winding with the aid of the screens 8 and 9. This winding? serves for negative feedback and is connected in series with an element with a resistor-l / Z ^ between the input terminals of the amplifier Vl . The second secondary winding 10 is connected to a second amplifier V2 , the output current of which is rectified using a Graetz circuit. The direct current obtained is measured with the direct current instrument 11.

The drawing shows that the resistors 1 / JT ₁ and 1 / if ₂ are connected in such a way that their common point can be grounded. In this way, capacitive influences are eliminated as far as possible. The shields 4, 5 and 8, 9, of

909 528/122

one of which is connected to earth and the other to the input electrode of the amplifier in every transformer is.

The mode of operation of the circuit can be explained using the simplified circuit arrangement according to FIG. The input voltage can be

being represented. Next is

- με

: ■. Sometimes it is desirable to measure the difference between two conductivities 4, in which the secondary winding of the input transformer has a center tap and voltage is supplied to the two measuring cells in opposite phase. the The input voltage of the amplifier is proportional to the difference between the two currents flowing through the cells. The following applies to the output voltage:

K ₁
_. It follows from this that

if

Then it will be

or.

E =

"K ₁ '

i_ J_V.

K ₁ * K _x ~ ~ K ~ x ^{(1 +}

K ₁

and ί = E · K ₁ . Now is

K ₁
-

where 6 _{0 is} the output voltage. So:
iiii

'κ ~ ₁ ~ ^β ° ^ Ύ ₁ ⁺ Ύ ₂ "*" ^e ° ⁼ ~ Ύ ₂ ⁼ " K ₂

The output voltage therefore depends linearly on the conductivity K ₁ ,

-In this way the conductivity K ₁ can be determined if K _{2 is} a known conductivity. By taking a number of exchangeable elements for K _% , a number of measuring ranges can be achieved, the display being linear with the conductivity K ₁ in all ranges.

The device described is particularly suitable for measuring the conductivity of electrolytes with temperature compensation. In this case, that of a reference cell is used for the conductivity K _% , ie a conductivity cell with the same properties as the cell used for K ₁ , which is located in the liquid, the specific conductivity of which is e.g. B. should be registered during a certain period of time. The cell arranged at the point of K ₂ is filled with liquid of the same type as the liquid to be measured and is located in the same temperature conditions, for example immediately next to cell K ₁ , in the liquid to be measured, but of course separated from this liquid . This arrangement of the cells in a liquid line is shown in FIG. The reference cell is located in front of the measuring cell with respect to the direction of flow, so that the time delay for the former is as short as possible.

It can be assumed that the temperatures of the two cells and also the resistance coefficients of the conductivities are always almost the same. The factor 1 -j- at (α = the temperature coefficient of conductivity and t = Celsius temperature), which indicates the change in conductivity with temperature, is eliminated in this way.

Oie Fig. 5 and 6 show modified apparatus in which the shield can be formed easily.

. In Fig. 5, the secondary winding of the transformer T ₁ consists of two equal parts 3 and 3 '. The center tap is connected to earth. The secondary transformer winding forms a closed circuit together with the winding 12 and the resistors 1 / Z ₁ and 1 / Jf _2. The winding 12 is coupled to the winding 13, which lies between the ungrounded output terminal of the amplifier F ₁ and earth. The common point of the resistances is not connected with the. grounded input terminal of the amplifier.

The output voltage is taken from terminals 14 and. for example measured after rectification.

A simple calculation teaches that the output voltage is given by the relationship

is given when at least the product of the first resistance and the gain factor is large against the sum of the two resistances.

Here, too, there is a linear relationship between the conductivity of the measuring cell and the output voltage if the input voltage is kept constant. Because the secondary winding of the first transformer T ₁ and the primary winding of the second transformer T _{2 are} both connected to ground, no shields need to be used between the windings.

In general, the cells are connected to the bridge circuit shown by cables. The cable capacities have little effect on the measurement because of the internal resistance of the secondary transformer windings are very low.

6 shows an embodiment in which an even better linearity can be achieved. The secondary winding of the feedback transformer consists of two parts 12 and 12 ', the number of turns of the first part being approximately four times that of the second part. The series connection of the resistors is connected to the common point. The gain is less than in the previous case.
The circuits described are very suitable for conductometric titration, in which case the two resistors have approximately the same values. The voltage on the primary winding 13 of the transformer T ₂ is given by:

[η = transmission ratio).

The sensitivity of the tube voltmeter, by means of which this voltage is measured, is proportionally

Claims (8)

moderately high, so that small changes in KJK1 can be made visible. Patent claims: 1. Measuring device in which a variable to be measured occurs in the form of a change in resistance and the quotient of this resistance and another resistance is measured such that the first resistor in series with an alternating voltage source between the input terminals of a Amplifier with negative feedback, whose output voltage, if necessary after further amplification, is measured, characterized in that the second resistor is in series with an impedance, over which the output voltage results, in the between the input terminals of the amplifier switched feedback loop. 2. Apparatus according to claim 1, characterized in that the input circuit of the amplifier a self-induction coil to which the measuring alternating voltage is inductively fed, and the first Resistance consists, while the feedback circuit consists of an inductive with the output circuit of the amplifier coupled second self-induction and the second resistor, and that the resistors at the ends facing away from the mentioned self-inductions with a point of constant potential are connected. 3. Apparatus according to claim 2, characterized in that the transformers have a double shield such that one of the screens of each transformer is constant with a point Potential and the other is connected to an input terminal of the amplifier. 4. Device according to one or more of the preceding claims, characterized in that the second resistor is replaceable. 5. Device according to one of claims 1 to 3 for measuring the conductivities of electrolytes, characterized in that the second resistor consists of a conductivity cell with a Liquid filled with the same properties as the liquid to be measured and the same temperature conditions is exposed. 6. Apparatus according to claim 5, characterized in that the conductivity cell is directly is arranged next to the conductivity cell immersed in the liquid to be measured. 7. Apparatus according to claim 5 or 6, characterized in that in the input circuit of the amplifier a number of measuring cells are connected through which the same current flows, in such a way that that the voltages that arise across them are in the opposite sense in the input circuit of the amplifier are effective. 8. Apparatus according to claim 1, characterized in that the measuring AC voltage is a transformer is fed, the secondary winding has a center tap that is marked with a point constant potential, and that the two resistors are in series with the secondary winding are connected, with the interposition of an impedance at which the output voltage results, and that the common point of the resistors is connected to the input electrode of the amplifier. 1 sheet of drawings © 909 528/182 5.59