SU970288A1 - Device for checking ferromagnetic liquids - Google Patents

Description

The invention relates to magnetometry and can be used to control the electromagnetic characteristics, and their integral development, of ferromagnetic fluids, such as special technical fluids, and, in particular, in assessing the degree of content of ferromagnetic impurities in liquid aviation fuels and lubricants.

A device for controlling ferromagnetic fluids, comprising two cells of a dielectric material in the form of hollow toroids with inlet and outlet channels, a high-frequency generator and an indicator 1 is known.

A disadvantage of the known device is the low sensitivity of operation, which does not ensure the quality control of the studied characteristics, especially liquids with weakly expressed electromagnetic properties, the discharge of which includes appropriate aviation liquids, as well as the relative complexity of the design implementation due to the use of the principle of high-frequency impedance controlled liquid environment.

A device for controlling ferromagnetic fluids is known, comprising a measuring winding made in the form of identical sections that are connected to a measuring master - indicator, a dielectric pipeline with the possibility of a test liquid flowing through it and a permanent magnet with a pipe section located between the poles They are located ossically and symmetrically on opposite sides of the permanent magnet along the axis of the pipeline 2.

A disadvantage of the known device is the low sensitivity of operation (functioning) due to the fact that it is based on

20, the principle of recording amplitude changes determined by monitored electromagnetic characteristics, while phase changes, which are highly informative, are not taken into account (are actually ignored). This reduces the effectiveness of the control of certain liquid media, distorts the reliability of the results obtained and

30 does not satisfy modern technological issues in the mass production of special ferromagnetic fluids.

The purpose of the invention is to increase the sensitivity.

The goal is achieved by the fact that a measuring winding in the form of two identical sections, one of which is located on the pipeline, an alternating current source and an indicator, is inserted into the device for controlling ferromagnetic liquids containing one pipeline of dielectric material, On which is located the second section of the measuring winding, a resistor and a capacitor, while the output of the AC source is connected to the nepBoiviy input of the indicator through the first section of the measuring windings, and to the second input of the indicator through the second section of the measuring winding, moreover, between the inputs of the indicator and o6a (a resistor and a capacitor are connected to the bus, respectively).

PA figure 1 presents a principal view of the device; figure 2 - the image of the control unit of the oscillographic indicator.

The device for controlling ferromagnetic fluids contains the first pipeline 1 of dielectric material with the possibility of the test fluid flowing through it, the second similar pipeline 2 with the possibility of flow of reference fluid through it, with which the indicators of the test fluid are compared, the measuring winding made in the form of two sections 3 and 4, one of which is located on the first pipe 1 along its axis, and the other is similar to the second pipe 2, resistor 5 is an exemplary measure vnogo resistance, a condenser b exemplary measure capacitance, the AC source 7 and the indicator 8. Piping ostsillografachesky i. and 2 have the same hydrodynamic data. Sections 3 and 4 have identical electrical parameters (number of turns, impedance, etc.) and are connected in series, respectively, with one resistor 5, and the other with a capacitor 6 so that they form together with them two separate successive chains connected parcel to the output of the alternator 7. The resistor 5 and the capacitor 6 are connected in parallel to different inputs of the oscillographic indicator 8, for example, to the channels of the horizontal and vertical

electron beam oscilloscopic deflection. The resistance values of the resistor 5 and the capacitance resistance of the capacitor 6 are equal in absolute value.

The operation of the device is as follows.

The flows of the test and reference fluids with ferromagnetic particles are pumped synchronously through the corresponding pipelines 1 and 2 (directions indicated by arrows) and intersect the contours of the coils of sections 3. And 4 of the measuring winding during their movement, introducing in accordance with the law

electromagnet induction corresponding amplitude and phase changes in the currents flowing in successive chains with elements 3-5 and 4-6. With the similarity of the electromagnetic characteristics of the test and reference liquids, the magnitudes of the electrical voltages supplied to the inputs of the oscillographic indicator 8 are equal in absolute value

amplitudes, and the phase shifted by an angle of 90 °, i.e. are in quadrature, which corresponds to the image on the screen of the control unit of the indicator 8 in the form of a circle (curve 9 of figure 2).

In the case of the smallest differences between the correlated electromagnetic characteristics, the equality of amplitudes and quadrature phase shift of the voltages at the inputs of the indicator 8 will be violated, as a result of which the circle on the screen of its control unit will be transformed into a corresponding ellipse (curve 10, figure 2) the screen

a certain radial and ring calibration, as well as a preliminary calibration of the device, gives a full-scale idea of the electromagnetic quality of the liquid under study on the integral manifestation of amplitude and phase changes.

Thus, the proposed device is distinguished by high sensitivity in controlling the electromagnetic characteristics of ferromagnetic fluids due to the realization in the measuring process of the reaction perception of the entire complex of electromagnetic manifestation, namely both in amplitude and phase expressions of the studied parameters.

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Claims (2)

1. USSR author's certificate according to the application No. 2780968 / 18-21, cl. G 01 R 33/12, 1979. 2. USSR author's certificate for application 2947991 / 18-21, cl. G 01 R 33/12, 1980.