SU748216A1 - Apparatus for analysis of organic liquid frequency - Google Patents

Description

K1 The arm and base are tightly mounted on the body and stitched between them with pins 4.

Inside the housing there is a cylindrical electrode 5, made of stainless steel and pressed into the annular groove of the base. Along the axis of the cylindrical electrode, a central electrode 6, made of wire (e.g., Molybdenum Copper, Nichrome, etc.) and passing through, is pulled. openings of the cover and base. On the outer side of the base, the central electrode is connected to the spring contact 7 and the current lead 8. Its second end on the outer side of the cover is connected to one of the current leads of the semiconductor thermoreeter 9. The thermistor 9 is placed inside the microthermostat 10, which is fixed on the cover. To fill the interelectronic gap with the test liquid, a hole was drilled in the lid, covered with a teflon stopper 11.

Electrical contact with the cylindrical electrode is made by means of a conductor 12 passing through a hole in the base. By means of current leads, the electrodes are connected to an adjustable high voltage source 13. Through the same current lead, as well, the current lead 14 of the thermistor is included in the measuring circuit 15. The device assembly is displaced on the collecting vessel 16.

The device works as follows.

Before starting the measurement, the entire system is thoroughly cleaned. After assembly, the vessel is twice weeded: it is drained with a small amount of controlled liquid. The device is then fixed on the collection vessel 16 and placed on a strictly horizontal surface, and the test liquid is poured into the interelectrode space through the hole in the lid 2 so that its level reaches the upper edge of the cylindrical electrode 5. The lid in the lid 2 is fixed with a stopper 11 and Microthermostat 10 is fixed on the lid 2. After that, thermostat 10 is put into operation, and electrodes 5 and 6 are connected to high-voltage source 13 using current leads 8, 12 and 14, and thermistor 9 is connected to measuring circuit IS.

 turning on the power of the measuring circuit 15 through the semiconductor thermistor 9 current flows / which heats it. The output signal of the measuring circuit 15 will be determined by the resistance value of the thermistor 9, which, in turn, depends on the heat exchange conditions of the thermistor with the environment. Since in the proposed setting 740216

If the thermistor 9 and one of its conductors 14 are in calm air with a constant temperature maintained by microthermostat 10, the heat exchange of the thermistor and its resistance will significantly depend on the height of the second current lead in the liquid under investigation, which is in electrical and thermal contact with the central electrode 6. Measuring circuit 15 is constructed in such a way that in the absence of a high voltage on the electrodes 5 and b, its output signal is 0.

After these preparatory operations have been performed, electrodes 5 and 6 are supplied from a high-voltage source 13, a certain voltage at which the polar liquid rises along the central electrode b or the non-polar liquid is ejected from the interelectrode gap. In either case, due to the change in the height of the second current lead of the thermistor 9 in the liquid, its resistance changes, which leads to imbalance of the measuring circuit 15 and the appearance of a signal at its output.

The height of the rise of the polar and the amount of displaced non-polar liquids at a given voltage on the electrodes is the greater, the less impurities are contained in them. Thus, the purity of the monitored fluid is determined by the value of the output signal of the measuring circuit 15.

The device allows for appropriate calibration to determine the purity of both polar and non-polar liquids. The electrical output of the device significantly improves the quality of the analysis, since the semiconductor thermistor is highly sensitive to changes in heat exchange conditions and allows you to capture even minor changes in the level of the monitored fluid, ensuring a high resolution of the device as a whole.

 The device can act as an indicator of a given degree of purity of the liquid or serve to determine its purity at certain stages of purification.

Claims (2)

1.Turichin A.M. Electrical measurements of non-electrical quantities. Energy, M.-L., 1966, p.643. 2. USSR author's certificate number 176454, cl. G 01 N 27/00, 1953. W / V: ii // II i jj it.-b