SU1653813A1 - Method for automatic control of mixing solutions - Google Patents

Abstract

The invention relates to methods for automatic control of blending processes in the liquid phase and can be used in the mineral fertilizer industry to obtain multi-component fertilizers with a predetermined ratio of components. The aim of the invention is to improve the quality of the final product by increasing the accuracy of adjustment of the pearl in -evoi jp. .oelahs current density and temperature of the initial solutions and the temperature of the mixed solution and the calculation of these values of steps of the mixed density of the mixed solution. The feed of the initial solutions is regulated depending on the magnitude of the mismatch between the current and reference values of the densities of the mixed solution of 1 sludge SL

Description

The invention relates to methods for automatically controlling the mixing processes in the liquid phase and can be used in the mineral fertilizer industry to obtain multi-component fertilizers with a predetermined ratio of components.

The purpose of the invention is to improve the quality of the final product by improving the control accuracy.

The drawing shows a schematic diagram of the implementation of the proposed method

Pipelines 1 and 2 are designed for supplying, respectively, solution A and the solution of substance B to mixer 3. Pipeline 4 serves to drain from mixer 3

a mixed solution of substances A and B for further processing. A temperature sensor 5 and a density sensor 6 for a solution of substance A are installed on line 1. A temperature sensor 7 and a density sensor 8 are mounted on line 2. Pipeline 4 is equipped with a temperature sensor 9 and a density sensor 10 for a mixed solution of substances A and B. Computing device 11. which receives signals from sensors 5-10 controls the actuator 12, which finely adjusts the flow rate of solution B in the bypass line 13. a Consequently, the ratio of the costs of solutions of substances A and B at the entrance to the mixer 3. Provided more

SL

with

00 00

rough pre-adjustment of the ratio of costs of the solutions; at a fixed flow rate of the substance A solution in the pipeline 1, a proportional flow rate of the substance B solution in the pipe 2 is established on its segment covered by the bypass line 13.

The method is carried out as follows.

The concentration and temperature and, consequently, the density of solutions A and B in pipelines 1 and 2 continuously and randomly fluctuate in certain intervals. Therefore, the sensor 5, temperature 1d and sensor 6, the density rl of the solution of substance A, sensor 7, temperature te and sensor 8, the density of the solution of substance B, and sensor 9, temperature t and sensor 10, the density p of the mixed solution A and B in pipeline 4, are measured. Information on the measured values is fed to a computing device 11, in which, using sensor readings 5–9, a reference density value of the mixed solution p is calculated. The value of r o is essentially variable. In addition, the difference between the current (sensor 10) and the reference density values of the mixed solution is calculated. The manipulation of the actuator 12 is aimed at maintaining equality p-ro 0.

Let us assume that the density of the resistor of substance B exceeds the density of the solution of substance A, i.e. pd rv- Then at times when ro-0, actuator 12 provides an increase in the supply of a solution of a substance in the bypass line 13, and consequently, at the entrance to the mixer 3, and the flow increment is proportional to the absolute value of the p-pc difference. Conversely, with p-ro O, the flow rate of solution B in the bypass line 13 is reduced, with the reduction in flow rate being proportional to the value of | p-pol.

To calculate the reference value of the density of the ro mixed solution, provided that the temperatures and concentrations of the initial solutions vary in rather narrow intervals, a linear polynomial of the form can be used

RO Co + CipA + Cgpc + C3 TA + d IB + Cs t,

ABOUT)

in which the magnitude of the constant coefficients Co. CL. C5 is determined by the nature of substances A and B and the solvent by a given mass ratio of substances A and B in a mixed solution, as well as by the average values (in the range of changes) of temperatures and concentrations of the initial solutions of substances A and B.

For example, carbamide (substance A) and ammonium nitrate (substance B) are mixed in the form of their solutions, with water being the solvent. The concentration and temperature of the urea aqueous solution vary smoothly, but randomly in the ranges of 68-72 wt.% And 90-100 ° C, respectively, and the aqueous solution of ammonium nitrate, respectively, in the ranges 79-87% and 115-135 ° C. The temperature of the mixed aqueous solution varies in the range of 105-115 ° C. It is necessary to maintain in the mixed solution the mass ratio of carbamide to the mass of ammonium nitrate, equal to 0.77. In this case, the empirical constant coefficients C in the polynomial (1) (provided that the density is measured in kg / m and the temperature is about ° C)

C0 140 Ci-0.78. C.2-036; Sz 0.49; 0.242. Sat - -0.64 Selection of C0 coefficients. Ci ... Cs in the formula (1) in each particular case is carried out experimentally, Let us assume that the concentration and temperature of the solution of a substance vary in the intervals. Xd min - Xd max And

IA mi. tA mdks a solution of substance B - respectively, in the intervals of Xv mim - Hv.max and to min tn max. The temperature of the mixed solution varies in the range of 1 Min-Tmax-For any combination of five values

Hd XB, tA, IB. t. selected from these inervals for a given mass ratio q0 of substance A and B in a mixed solution, it is possible to experimentally determine the corresponding value of the reference

density of ro mixed solution

First, experimentally determine the densities of RA Irv of solutions of the substance A and B by the concentration Xd and Xb at temperatures of TA and GB, respectively. Further mixes

between themselves solutions of substances A and B in a certain mass ratio GA: GB. with GA / GB ChoHv / Xd. The resulting mixed solution is heated or cooled to temperature t, then it is measured

density at this temperature. This defines the reference density of the mixed solution pb. Thus, a set of five values of the values of rd.rv. tA, ib. t matches the experimentally found reference density value of the mixed solution pb

In order to find the values of the constant coefficients of Co. Ci ... Cs in equation (1), you need to spend at least 6 (and

better, more) experimental determinations of the value of r0 in accordance with the rule indicated above. And each time, new values of Xd, Xv should be chosen. tA. te, t of the given intervals of their change. After accumulating the necessary experimental data using the least squares method, the values of the constant coefficients Ci in equation (1) are selected, in which the correspondence between the experimental and values calculated by equation (1) is best achieved.

If the concentrations and temperatures of the initial solutions of substances A and B vary in too wide intervals, the linear polynomial (1) is not accurate enough for the calculation of /% Therefore, it may be advisable to add to the polynomial (1) / additional terms that take into account non-linear arlcter dependencies or cross effect of density and temperature on the value of / TO

In cases where there are experimental data on the densities of rds.rv of solutions of substances A and B at various concentrations Xd and Xv and temperatures (most often such data are collected from literature sources), but it is not possible to conduct additional experiments to determine the values of With. Ct Cs in equation (1) to calculate p0. The formula for calculating the reference density of a mixed solution of substances A and B can be obtained as follows.

On the basis of available experimental data using the least squares method, computer calculates the coefficients ai in the formula for calculating the density / 5d of the substance A solution, depending on its concentration Xd and temperature tA

RA “ai + 32 tA + (az + 34 TA) Hd. (2)

Similarly, the coefficients bi are found in a similar formula for calculating the density pb of a solution of substance B

PB DI + D2te + (L3 + L41b) Hv. (3)

Let the stock solutions be mixed in a GA / GB weight ratio. where GA, GB are the masses or the mass flows of the initial solutions of substances A and B. A mixed solution is formed in which the concentrations of substances A and B are YA and, respectively

Yb.

The mass ratio of substances A and B in a mixed solution is

q - YA / YB.

In this case, the values of k and q are related by

q - kHd / Xv or k - qXR / Xd (5) Concentrations Od. Y substances A and B in a mixed solution

GA

Yt - G-XA G ". A GA 4 G GA.

Hd AA x Hk X;

“G +

q XB + X

(&

Yp G. - BXB

GA 4 Go GA k M

GB

XR

X in,. qXA

q XB + XA

(7)

To calculate the density p at the temperature t of the mixed solution, the principle of additivity can be accepted (5). expressed with the accepted notation as follows.

/ i (ai + e2 t + (az + 34 1) (Od +

 YB) rrYA

Ya + yfi

+ b41) (YA + YB) + bi 021 + (B3 YR

YA + YB

(eight)

As a result of the transformations of expression (8), it is possible to obtain a formula for calculating p as a function of variables / ed, / EVLA, IB. t, based on the known mass ratio q of substances A and B in a mixed solution of Fe:

Oud

45

/ e (ai 32 t) ud vu + (az + 34 t) YA + YB + Yi

+ (bi + b2 t)

Yb yb

YA YB YB YB

4- (b3 + b4 t) YB - (9)

- (+ (in + m,). 9 .. + (,, vg17 + (| in + 1m “) §.

55

 faiq + bi

I q + 1

+ sVrra

In the

(four)

+ K 3q + b3) + (a4q + b4) t T5U The variables Xd and Xv appear in formula (9). which can be expressed as a function of the densities and temperatures of the initial solutions by simply transforming the dependencies (2) and (3)

HA

/ ZD- (31 4-32 tA), EZ + 34 TA

(ten)

 YR PB 7 (Ь1 + Ь2 tB) m p

XB L3 + NPV (To calculate the reference PO density of the mixed solution, i.e. the density of the mixed solution, obtained by combining only the initial solutions taken in the correct mass ratio (taking into account fluctuations in concentrations and temperatures of the initial solutions), which ensures the specified mass ratio qo substances A and B in a mixed solution, formula (9) is used after substituting q q0 into it

 / 31 q0 4-bi 32 q0 02, P {qo + 1qo + 1)

+ (az Qo + bz) + (at q0 + b4) t

(12)

Formula (12) as opposed to (large is versal, since it gives satisfactory results in a wider range of concentrations and variations, the initial solutions and the experimental determination of the density of the mixed solution depending on its temperature and composition.

For example, consider the previous case: urea (substance A) and ammonium nitrate (substance B) are mixed in the form of their aqueous solutions, and it is necessary to obtain in a mixed solution a mass ratio of substances A and B equal to q0 0.77. Formula (12) with the following dimensions, r0 (kg / m-3) is used for calculating the PO; tA, c. t (° C); HA. XB (May%). In this case, the following values are taken for ki; atsi, bi;

ai 9,79319 32 -2,82692 az 3.31451; 34 -4.74935

10Z; bi 9.21939 1 (G: b2 -5.99584 -10 1

L 6.06715; -5,61792- 10

1-4

The coefficients ai, bi in equations (2) and (3) were obtained by processing on a computer experimental data on the density of aqueous solutions of urea and aqueous solutions of ammonium nitrate at various concentrations of CA. XB and temperatures TA tv

0

five

0

five

O

In this case, formula (12) gives satisfactory results with fluctuations of variable values in the intervals Hd 60-85 May.% TA, XB 70- 90 wt.%, TV 70-140 ° C. t 70-95 ° С

The application of the proposed method in comparison with the known one allows to reduce the relative error while maintaining the specified mass ratio of substances in the mixed restoreor from ± 7.5% to ± 3.8%. those. the adjustment accuracy is almost doubled. As a result, the consumer properties of the fertilizer are improved.

Claims (1)

Invention Formula A method for automatically controlling the process of mixing solutions of substances consisting in measuring the density of a mixed solution, determining its predetermined value and controlling the ratio of the flow rates of the initial solutions of substances by the deviation of the measured density from its predetermined value, characterized in that, in order to improve the quality of the final product by improving the accuracy of regulation, in addition, the current densities of the initial solutions and Ti: K are measured, the initial and mixed temperatures of 4nj are dissolved, and the published values of the densities The ty / l of the mixed solution is determined by;, - measured values according to the following expression.  / ai q0 + bi 32 Ро + Р ° Гф-М q7 + 1 j - (aj Po + bz) + (al q0 + b) t - Hvhd 40 45 50 55 qoXB + HD where q0 is the specified mass ratio of substance A to mass of substance B in a mixed solution; t is the current temperature of the mixed solution; a1, a2.az.a4.b1, b2. bz.b4 are empirical constants; XA is the current concentration of the solution of substance A, determined from the formula RA 31 + 32 TA - (az + eo TA) HA, where TA and p are respectively the current temperature and the current density of the solution of substance A; Xs is the current concentration of the solution of substance B, determined from the formula PB bi 02 TV + (Lz 4 b4 TV) Hv. where IB and pb are, respectively, the current temperature and the current density of the substance B solution Mixed solution of Substances A and B Solution of matter / air defense / Solution substance in / / J Y-y & -2 / Chya A p