UA146323U - METHOD OF INFORMATIVE TWO-PARAMETER CONTROL OF SAMPLE OF ACID WASTEWATER OF FOOD PRODUCTS - Google Patents

Abstract

The method of informative two-parameter control of the sample of acid wastewater is that along the sample is passed an alternating electric current, which creates a vortex EMF, under the action of which eddy currents excite a magnetic flux, which is geometrically with the excitation magnetic flux, creating a total magnetic field. while the total magnetic flux decreases in magnitude and shifts the phase angle relative to the exciting magnetic flux, and all this, in turn, leads to a change in the informative components of the signals of thermal TVKP, ie inductance and resistance, which are associated with electrical conductivity , the temperature t of the sample and the geometric parameters of the glass tube, which contains a sample of acid effluents, which is heated to simulate production conditions, according to the measured characteristics of TVKP and based on the established dependences of normalized internal inductance on the generalized parameter, ie specific normalized of inductance from resistance on alternating current,, informative two-parameter control of electric and temperature parameters of a sample of acid drains is carried out

Description

The useful model belongs to non-destructive testing and can be used in industrial ecology and thermometry during informative measurement control of the parameters of wastewater samples of the brewing and winemaking industries of food production. Known methods and means of measuring the specific electrical conductivity of food waste water samples are based on the dependence of the change in the concentration of the conductive substance in the space between the electrodes of the analytical device or on the dependence of the potential of the indicator electrode on the concentration of liquid ions. These are conductometric methods (direct conductometric methods, conductometric titration methods) and potentiometric methods (ionometry, potentiometric titration) |1). They have significant disadvantages in relation to the measurement of wastewater samples, namely: due to the lack of selectivity, the direct conductometry method is used only for the analysis of single-component solutions, to obtain sharp breaks on the conductometric titration curves, it is necessary to take into account the dilution effect of the solution, in the practice of conductometric measurements, it is customary to reduce the value of the specific electric conductivity Ж to temperature

I1-25"C, which, in turn, leads to the inaccuracy of informative control of the physical and chemical characteristics of liquid environments. The disadvantages also include: a long process of preparing liquid samples, the need for standards, standard samples, standard solutions and passport calibration dependencies, lack of theoretical and experimental methods, the implementation of which determines the obtaining of absolute values of the electrode potential, requirements for the state of the reference electrodes.

There is also a known method (2|) of non-destructive control of the specific electrical conductivity Ж of a sample of machine lubricant during the implementation of the variable-frequency eddy current method using a miniature transformer eddy current converter (TVP) with a copper core, which is immersed in a vessel with the liquid under investigation. Which consists in the fact that by changing the frequency of the magnetic field y is maintained by a constant value of the generalized magnetic parameter x, which includes information about the electrical and temperature parameters of the fluid under control, while the TVP is located at the bottom of the container with machine oil. The constant values \u200b\u200bof the parameter x are fixed based on the readings of the phase meter, since the shift angle Ф between the reference EMF Eo and EMF Eg, the value of which is given in the core, is connected by a universal dependence on the parameter x. The essence of this implementation is that the core

The cylindrical shape takes the temperature of the environment in which the eddy current converter is located, that is, the core of the converter is heated, and as a result, the temperature T of the liquid is determined by the temperature of the thin copper core. The method was further developed by the IZ| when controlling the electrical conductivity U and magnetic permeability n of ferromagnetic metal products by a parametric electromagnetic converter (EMC), which includes only one winding for the simultaneous performance of measuring and magnetizing functions. The disadvantages of the method (|2, 3| are the complexity of the hardware solutions associated with the difficulties of varying the frequency of the alternating current, the requirements for the geometric parameters of the miniature converter and the core, the need to use special methods to compensate for the effects of the air gap between the core and the measuring winding of the converter.

A known method is method I4| control of magnetic, electrical and temperature parameters of weakly ferromagnetic liquid samples, which consists in the fact that during the passage of an alternating current in a test tube with a liquid, a magnetic field is created, while the dispersed ferromagnetic particles have the properties of attraction between themselves and create a monolithic structure of a cylindrical rod. It should be determined that the use of a thermal eddy current contact converter (TVCP) for monitoring the physicochemical parameters of magnetic fluids is due not only to a relatively simplified schematic implementation, but also to the absence of the influence of the demagnetization factor on the results of measurement control, which makes it possible to increase the probability of monitoring the relative magnetic permeability and , specific electrical conductivity Ж and temperature І of the magnetic fluid. The disadvantages of this method are the lack of data on the optimal operating modes of the converter with liquid samples under control, undefined limits for changing the length of the samples, the lack of data on the peculiarities of controlling the physicochemical characteristics of samples of emulsions and suspensions, which are formed as a result of food industry waste discharges.

The task of a useful model is to expand the functional and technical capabilities of thermal

TVKP regarding the compatible two-parameter informative control of the specific electrical conductivity Ж and temperature of a wastewater sample in a transverse magnetic field for the purpose of solving issues related to the further selection of the method of wastewater treatment of the brewing and winemaking industries of food production.

The problem is solved by ensuring the interaction of the external magnetic field with the magnetic field of eddy currents, which are induced in a sample of wastewater, which is subjected to preliminary heating to simulate the industrial conditions of production of products of the brewing and wine industry, related to the problem of cleaning acidic wastewater.

The essence of the method consists in the analysis of the interaction of an external uniform magnetic field with a single-frequency magnetic field of eddy currents, which is induced in a sample of acidic effluents. At the same time, the magnetic flux in the liquid "2, the inductance I and the electrical resistance О are related to the specific o. . . a . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . converter ", as well as with the temperature of the sample. As the frequency of the magnetic field increases, the internal inductance of the sample decreases, the resistance and the specific electrical conductivity of the sample increase (the index indicates that the value is temperature-dependent ).

Since, the main criteria when choosing a technology for wastewater treatment of industrial enterprises is the composition of the water, namely the presence of certain pollutants in it according to the numerical data of the specific electrical conductivity X, and the temperature of its sample, in accordance with the established regulatory methods, determine the concentration of C, indicators of mineralization

TDS, total OH hardness, hydrogen pH index and other physico-chemical characteristics of wastewater samples, which are specified in the relevant normative documents on wastewater, all this allows for further selection of mechanical, physico-chemical, biological and other methods of wastewater treatment.

The technique of informative two-parameter measuring control of specific electrical conductivity Ж and temperature І consists in the fact that the specific . . . . 1, normalized characteristics of thermal TVKP: o normalized internal inductance, other, normalized electrical resistance ("" and generalized parameter A, which contain information about the specific electrical conductivity Ж;» the temperature of the liquid sample and the geometric parameters of the glass tube with the sample of acidic effluents. Further, according to with the help of the TVKP switching scheme, changes in the internal inductance 7 and resistance 2 are found, which are caused by a change in the total magnetic flux .

Zo occupies the depth of penetration of the magnetic field b into the liquid sample corresponding to its value.

Dos. ijuvandamathedzatic model "TVKP - a sample of acidic wastewater", expressed by a system of equations: о, - ED, хи) where and - designation of functional dependencies, - diameter of the wastewater sample; - specific electrical conductivity of the sample at the initial temperature; I is the temperature coefficient of resistance, which is found experimentally; and. initial temperature of the sample, P-18 26.

The generalized parameter A, at different values of the temperature of the sample, is found by the formula? -- p

A, pd uko; (2) a. . . and - and -a4l107 where " is the diameter of the test tube with the sample, " : po. magnetic constant, No Gn/m; 9 - cyclic frequency. at

At the specified resistance of the sample at direct current 9, taking into account the compensation of part of the total inductance I caused by the passage of the parasitic magnetic flux Ф,

outside the sample, measure the voltage on the current leads of the glass tube, which are located from its . . . the field is -0, according to the formula - 0

I - vl loz) where d is the length of the test tube with a liquid sample under control. The normalized internal inductance is determined by the formula: yno

And, (4) / . . . . . . where " is the internal inductance of the liquid on an alternating current.

Next, when the heater H is turned off, set the operating point A, (at (-1872) on the dependence of the normalized internal inductance "" on the generalized parameter A, i.e. tsa -E and (4). Fig. 1. At the same time, if the value of A: is in the range 1"xAi-x2.5, where the sensitivity of the TVCP is the greatest, leave unchanged the value of the set frequency ii of the magnetic field of the TVCP. In the event that the working point of AI does not fall into the specified range, set the frequency y2 and carry out repeated measurements of the components of the TVCP signals, while changing the values of the frequencies и, и2...... them, until the value of the working point A: falls into the range 1-Аих2.5. Next, with the help of a heater, the Temperature Й of the liquid sample is changed in the temperature range from 18 to 30 C and at the frequency " М 71, measure the components . in I, o . her her her about M

Knowing the shield, they find the temperature-dependent normalized resistance

Or", - at 0. (6)

To determine the parameter Ж, it is necessary to apply the functional dependence of the specific normalized internal inductance it on the generalized parameter A, i.e.

Ha - (Ou. . that sh i in n217, fig. 2. Moreover, the introduction of specific normalized inductance 71 is explained by . , given in Fig. 1 and Fig. 2, temperature points corresponding to temperatures 1-18; 21; 24; 27; b. I

Inductance, it is determined by the formula: -- Her

Ha t

Koo) Sh - (7)

After this, the specific electrical conductivity Ж of the liquid sample is determined

Chr 5

Grastis 8) leaks? Cropping of dry paddy according to the formula:

ЖБВБЗВЗ -- -)!' - 25-52 5ШШШ 22553533: -- 2 1 (24 dra t et, (9)

In fig. From is a diagram of a thermal TVCP with a sample of wastewater. The scheme includes: TKVP in the form of a series-connected inductance 7, resistance C and capacity C0 (marked by a dashed line). TVKP simultaneously performs the following functions of thermal eddy current

. F,, . not converter: creating a magnetic flux,; Compensation of part of the total inductance

In the measurement of the internal inductance 7" and the variation of the temperature of its acid waste sample. The scheme also includes: O - oscilloscope, DSP - source of sinusoidal voltage,

HF - frequency meter, B: and B2 - voltmeters, Nzo - sample resistance, C - two-channel recorder for monitoring the form of current I and voltage I of the liquid sample, VF - phase angle shift meter,

NP - heating device (indicated by a thick dashed line). It has been experimentally proven that the implementation of the method of informative two-parameter eddy current control of the specific electrical conductivity Ж and the temperature of a sample of acidic wastewater increases the accuracy of measurements by 15-20 95 in comparison with known methods.

Sources of information: 1. Porev V.A., Dashkovskyi O.A., Mindyuk Y.L., Prymiskyi V.P. Analytical environmental devices and systems: monograph. Vinnytsia: Vinnytsia National Technical University, 2009. 336 p. 2. Sebko V.V. Eddy current methods and devices for non-contact temperature measurement of products and environments: autoref. thesis for the acquisition of sciences, the degree of technical Sciences: 05.11.15. Kharkiv State Scientific and Industrial Association "Metrology". Kharkiv: Kharkiv State Polytechnic University "HDPU", 1998. 16 p. 3. Verezyuk B.M., Marikutsa U.B., Sviridova T.V. Solving the problem of multi-parameter control of metal products by the alternating-current method of eddy currents. Herald

Lviv Polytechnic National University. 2006. Mo. 564. P. 67-71. 4. Sebko V.P., Sebko V.V. Control of three parameters of ferromagnetic liquids by a thermal contact eddy current converter. Ukrainian Metrological Journal. Kharkiv NSC "Institute of Metrology". 2010. Me1. P. 14-18.

Claims (1)

USEFUL MODEL FORMULA A method of informative two-parameter control of a sample of acidic wastewater, which consists in the fact that an alternating electric current is passed along the sample, which creates an EMF eddy, under the action of which the eddy currents excite a magnetic flux, which will add up geometrically with the exciting magnetic flux, creating a total magnetic flux 2 in the sample under study, while the total magnetic flux decreases in magnitude and shifts by the phase angle in relation to the exciting magnetic flux, and all this, in turn, leads to a change in the informative components of the thermal TVCP signals, i.e. inductance 7 and IF resistance ). . at. . m, which are related to the specific electrical conductivity Ж, the temperature ii of the sample and the geometric parameters of the glass tube, which contains the sample of acidic waste water, which is subjected to heating to simulate production conditions, according to the measured characteristics of the TVCP ii based on the established dependencies of the normalized internal inductance "" from the generalized A, I - K(A,) t ti 1, I vi o M parameter , that is, the specific normalized inductance 1 of the resistance and on ! by means of Uh (or ! - - alternating current, nm, informative two-parameter control of the dielectric and temperature parameters of the acid waste sample is carried out, according to the formulas: I. 0th 2 Ha and (0) r. Hm ate I 2 Boaeslisno Iva A G-- юНЧНЧ- б 2 2 - 6 ( E 6 - 2 2 52 -1й1-- (2 noses tt, /th . . And, . . . . where " is the normalized internal inductance; " is the internal inductance of the liquid on an alternating current below l-0.0; - inductance at the frequency of the magnetic field; - resistance on the alternating current I; in . . . " - voltage on the current leads of the glass tube; Ф. phase angle of shift between current 1 in . . Ф) of the liquid sample under control and the same voltage Ш; 07 - temperature-dependent normalized resistance that! ! not 1, . ! resistance; 79 - resistance of the sample on direct current; 77! - specific normalized inductance; A. . o. . a . generalized parameter; Zhi - specific electrical conductivity of the liquid sample; " - diameter of the test tube with the sample; 7 - frequency of the magnetic field on an alternating current; But. magnetic became, - at -4l:10 g/m: Her - . and. - the city of N/m; temperature of the acidic wastewater sample; temperature coefficient of resistance; I - the initial temperature of the acidic wastewater sample; Ж is the specific electrical conductivity of the wastewater sample at the initial temperature. ZO s DAKKH prteneeteetkyukchnkh o pk nn nnya min zon nn PK nyn Zh t z : ii Z : : ii : U N write shi NN V Soya -f VE NAEYA EK nya Ne Z y Fig. 1 VN Tu i nn ny p p, nn p NK V MI N Zo 1x : : і ща 3. smokes мк мысти ие «-Ezh shchi l shinki I, ptn tyu ne 1 : In ak. : t BU NI o p pi ЖЯ FC is Ne Ba xx Fig. 2