SU1474532A2 - Non-contact conductometric transducer - Google Patents

Abstract

The invention relates to the measurement of the electrophysical parameters of liquids and can be used in marine conductometry to determine the salinity of the water, in the chemical industry and the electroplating industry to determine the concentration of electrolyte solutions. The aim of the invention is to improve the measurement accuracy by stabilizing the conductive constant of the sensor. The contactless conductivity sensor contains two transformer converters 5 and 6, each of which consists of two toroidal magnetic circuits, one of which has an excitation winding, the other has a measuring winding, and the first transformer converter 5 is located in the channel of the second converter 6, the measuring winding 11 of the second converter 6 is connected to the input of the variable voltage amplifier 4, and excitation winding 12 of the second converter 6 is connected to the output of variable voltage amplifier 4 p marry The excitation winding 14 of the first converter 5 is connected to the alternating voltage generator 1, and the measuring winding 13 is connected via the current-to-voltage converter 2 to the measuring device 3. 1 sludge.

Description

one

The invention relates to the measurement of the electrophysical parameters of liquids, can be used in marine conductometry to determine the salinity of the water, in the chemical industry and electroplating to determine the concentration of electrolyte solutions and is an improvement of the sensor according to the author. St. No. 595668.

The purpose of the invention is to improve the measurement accuracy by stabilizing the conductive constant of the sensor.

The drawing shows a diagram of the proposed sensor.

The non-contact conductometric sensor consists of an alternating voltage generator 1, a current-voltage converter 2, a measuring device 3, a high-gain amplifier 4, a first 5 and a second 6 conductivity converter with a liquid turn connection. In this case, the first converter 5 is located in the channel of the second converter 6. Each of the converters 5 and 6 contains two toroidal magnetic cores 7-10, each of which is wound around the winding 11-14. The excitation winding 14 of the first converter 5 is connected to the generator 1, and the measuring winding 13 is connected to the input of the converter 2 of the current to the voltage. Measuring winding

11 of the second Converter 6 is connected to the input of the amplifier 4, and the winding

12 of the excitation is connected to the output of the amplifier 4. The measuring device 3 registers the output voltage

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converter 2 current to voltage.

The sensor works as follows.

The alternating voltage from the generator 1 is fed to the winding 14 and ensures the appearance of EMF in the fluid. Accordingly, a current proportional to its specific electrical conductivity begins to flow in the fluid. If a part of the current lines is closed in the surrounding space of converter 6, an electromotive voltage appears in winding 11 proportional to the total current flowing through the channel of converter 6. This signal is amplified by amplifier 4 and fed to a circuit of a winding 12, the current of which causes the appearance of an additional EMF in a fluid, which prevents the flow of current in the space surrounding the converter 6. With a sufficiently large Wux tim amplifier 4 (103 - 10) nearly all of the current lines I are closed within the channel of the transducer 6, as shown by arrows in the drawing. The current flowing in the electrolyte circuit encompassing the converter 5 causes current to appear in the winding 13. Then the measuring signal converted to the voltage by the converter 2 flows to the measuring device 3.

It is obvious that in the proposed sensor the conductive constant does not depend on the volume of the electrolyte under study and the position of the sensor in the surrounding space, but is determined only by the configuration and geometric

314745324

Claims (1)

the dimensions of the converter 5 and the channel of the variable voltage amplifier of the converter 6. and the second transformer conductivity of the conductivity, moreover, the formula of the invention transformer of transformer located in the channel of the second noncontacting conductometric mater converter, measure- - sensor auth.St. No. 595668, about tl and - the winding of the second one is transformable by the fact that, for the purpose of bodies, it is connected to the input of the amplifier to increase the measurement accuracy due to JQ AC voltage, and the stabilization winding of the conductive constant excitation to it additionally enter alternating voltage.