SU420954A1 - ELECTRICAL CONDUCTIVITY MEASURE - Google Patents

Description

one

The invention is intended for use in electrical measuring equipment as a measure of electrical conductivity from 1 to Yu.

There are known measures of electrical conductivity with multi-digit quantization of the latter, which have limits of indications of 0.1–102 sim. However, they are characterized by a large number of resistor components, which usually require at least four per quantization bit. When implementing accurate multi-discharge measures of electrical conductivity over 1 sym in the form of simulators of electrical resistance and conductivity, much less resistor components are required for one bit of representation and quantization of conductivity. However, such measures are not recommended for a conduction range of less than 10 sim.

In order to obtain highly effective in terms of range and accuracy, and at the same time economical in terms of the required number of components, to implement a multi-discharge electrical conductivity simulator, you need to find a circuit solution that would require a minimum resistor component with a conductivity of more than 10 or less Sim. The first resistor components are difficult to accurately

commute, and the latter are too expensive if they are microwire or not very accurate if they are non-wired.

The purpose of the invention is to simplify the device.

For this, a measure of positive conductivity is connected in parallel with the negative conductivity feeder, and the conductivity of the first measure is made equal to the product of the conductivity of the first arm by the resistance of the second and the maximum conductivity of the latter.

The drawing is a schematic diagram of the proposed measure.

The diagram has the following notation: 1 and 2 are the input poles of the measure; GO is the conductivity of a step-adjustable main arm of the internal circuit of the measure; d is the conductivity of the second arm, stepwise regulated jointly with the adjacent arm; R2 is the resistance of the shoulder opposite the shoulder; (1-.i) GS is the conductivity of the shoulder adjacent the shoulder, but lying in a different current branch (, and is the required reading of the resulting conductivity); CU is the equilibrium

an amplifier with a threshold of sensitivity to voltage n balanced by voltage f.

The principle of action is based on the use of the properties of a parallel connection.

electrical elements when total conductivity

(one)

5l2 GO +,

where GO is the conductivity of a traditional resistor element, and gi2 is -GiR2G3 (l-m-) is the conductivity of a negative quasi-resistor, formed by a controlled bridge circuit GI, Kg, (1-M-) G3 amplifier UU.

Between the parameters of the component of the measure is always the ratio

g., - (1- V-) G,. (2)

Therefore, according to expressions (1) and (2), the conductivity is simulated by the device

G ,, GO - (1 -) Go. (3)

in the shoulder (1- | l) Ga it is possible to have five decades with the indication p, - 0.00001- 0.99999, and the shoulder GO can be made in the form of a store of conductivities 10-, 10-2, 10-sim. Thus, the range of conductivity measures will be from HMHHGoMHH 10-5 I0-i 10-is sim to 0.99999 10- 0.1 sim. An important property of a measure is that it can be aggregated from unified traditional resistance and conductivity measures.

Subject matter

A measure of electrical conductivity, containing a stepwise changeable measure of conductivity and a simulator of electrical conductivity of negative value, consisting of an amplifier controlled by a three-arm resistor circuit, in which a shoulder adjacent and lying in one current branch with a stepwise measure, is made the same stepwise change eem; next shoulder is in

the form of a constant resistor; the third arm is in the form of a multi-digit conductivity store, characterized in that, in order to simplify the device, a measure of positive conductivity is included

parallel to the simulator of negative conductivity, and the conductivity of the first measure is made equal to the product of the conductivity of the first shoulder by the resistance of the second and the maximum conductivity of the last.

Gi