SU454468A1 - Conductometric concentration meter - Google Patents

Description

one

This invention relates to devices that control the concentration of solutions by their electrical conductivity.

Known conductometric apparatus for measuring a concentration of solution, consisting of two-transformer bridge sensor conductivity liquid-loop communication and adapted for differential measurement circuit using the electrolytic thermometer soprotivleNIN shoulder nonequilibrium bridge system autobalancing consisting of the servo amplifier, the reversing motor and the compensating reohoda.

However, adjustment of the thermal compensation system is performed by selecting the electrolyte of the electrolytic thermal compensator so that the temperature coefficient of the thermal compensation system is equal to the temperature coefficient of the liquid loop, which is caused by the presence of significant values of active resistance in the thermal heating circuit that are connected in series with the cell and reduce the temperature coefficient of the thermal myopic parameters.

The inclusion of a reactive compensating element and a resonant capacitance in the compensating coil circuit ensures minimal distortion of the temperature coefficient of the thermal compensator due to the very small

active co-current winding reactive compensator. At the same time, medium conceptual medium can be used as the electrolyte of the thermocompensator.

The drawing shows a block diagram of the concentrator.

The conductivity metering device contains a transformer Tr I, a transformer Tr 2, a communication coil ESh, a thermocompensator cell Rm, a magnetic compensator Mk with a resonant capacitor Cp, an amplifying device V and a measuring device U2.

The device works as follows.

In the middle of the measurement range, the concentration of the electrolyte in the coil of communication and in the cell of the thermal compensator is the same. In this case, the magnetic flux in the core of the transformer Tr 2, caused by the flow of the communication loop, is equal to the flow formed by the compensation loop. In this case, the magnetic compensator does not give a signal, and its reactive component of the resistance is compensated. When the temperature of the controlled solution is changed, and consequently, the temperature of the compensator solution, the circuit is in equilibrium due to the equality of the temperature coefficients of the communication loop and the compensation loop.

When the concentration of the controlled electrolyte changes, the difference in the magnetic fluxes of the coil of communication and the compensation coil with an amplifier and magnetic compensator brings the system into equilibrium.

Since the total inductance of the magnetic compensator varies little over the measuring range, the condition of the series resonance of the compensator with the capacitor Cp will be preserved over almost the entire measurement range.

Thus, the use of a reactive compensator and a resonant capacitor and their sequential inclusion in the circuits of the compensation coil make it possible to simplify the scheme of automatic balancing and thermal compensation by combining them in one element — the compensating coil. This makes it possible to obtain accurate thermal compensation over a wide range of temperatures, simplifying instrument calibration.

Subject invention

Conductometric atomic center,

including two transformers, a liquid coil, a thermocompensation coil with two transformer windings, an electrolytic resistance thermometer and a compensation element, characterized in that, in order to improve the temperature compensation accuracy, the compensating element is designed as a series-connected magnetic compensator and a resonant capacitor.