SU1328346A1 - Method of automatic control of maleic anhydride synthesis process - Google Patents

Abstract

And there is no way to be blinded on a baseline with a change in benmt-8az8uino ewe air

The invention relates to the automatic control of the process for producing maleic / anhydride, it allows to reduce the consumption of benzene and can be used in the chemical industry. At each step of control of the identification blocks 3, 4, and 5, based on information obtained from the (I) 11 meter, the temperature of the benz: ash – air mixture at the inlet end (L

Description

the cycle apparatus, and 12 the temperature of the salt bath of the contact apparatus,. and 13 the consumption of benzene in the evaporator 14, 15 and 16 of the temperature profile, the coefficients of the equations describing

. , one

I The invention relates to the automatic control of technological processes and can be used in the chemical industry in the automation of processes leading in fixed-bed apparatus, in particular, the process of producing maleic anhydride. . one

The aim of the invention is to reduce the consumption of benzene.

A block diagram of the system for automatically controlling the synthesis of maleic anhydride is presented on the chart, which implements the proposed method.

Control system: contains benzene evaporator 1, contact apparatus 2, identification blocks 3-5, controllers 6-8, blocks 9 and 10 of the implementation of process models, meter 11 temperature of the benzene-air mixture at the inlet of the contact apparatus, salt bath temperature meter 12 KNT tactical apparatus, meter 13 consumption of benzene in the evaporator and gauges 14-16 temperature profile in the contact apparatus.

The method is carried out as follows.

The air enters the benzene evaporator 1 to form a benzene-air mixture with a ratio of air and benzene not lower than 35/1, which is sent to contact apparatus 2, where maleic anhydride is formed by catalytic oxidation of benzene with atmospheric oxygen. The oxidation reaction is exothermic and takes place at the temperature of the molten salt in the reactor, which removes heat, at 370-420 ° C.

The contact apparatus is a vertical tubular reactor, in which tubes catalysis-i 45 is poured

the temperature value at the control points of the reactor, blocks 9 and 10 determine the calculated value of the flow rate of benzene, at which the predicted temperature value at the control point of the apparatus is equal to the set one. 1 il ..

0

15

20

25

thirty

 35

40

45

torus KH-256. The heat removal in the apparatus is carried out by melting the nitrite-nitrate salts, with which the mesque tube space is filled. Heat is removed from the molten salt by a steam generator mounted in the central part of the apparatus, and the resulting vapor is directed to the condensate compartment. To align the themes. At the catalyst bed, the contact apparatus is designed as a large number of very narrow tubes, cooled from the outside by coolant.

In order to reduce the consumption of raw materials, such a temperature regime is necessary at each point at which the speed of the direct reaction would be maximum with the speed of side reactions limited. This means that the temperature at various points along the height of the apparatus must be close to a certain optimal value with a minimum dispersion. It is undesirable to exceed a certain limit value by temperature, because the rate of irreversible decomposition reactions of benzene and maleic anhydride increases, and too many control channels are needed, therefore it is necessary to maintain temperatures in the most active zones in some limits around the optimal value, not allowing exceeding its limit value.

To eliminate the negative effect of random input variables, it is necessary to control the perturbation, i.e. forward. In order to make a prediction, mathematical models of the object are needed that link input and output variable objects. Since the synthesis reactor is a nonstationary object, primarily due to aging and periodical

replacement of the catalyst, then the object model should be non-stationary, taking into account the activity of the catalyst. The construction of such models is achieved by using adaptive identification principles. Adaptive adjustment of mathematical models allows you to monitor changes in the parameters of the object, in particular, the aging of the catalyst.

According to research data, the most significant parameters affecting the temperature mode of the process are the temperatures of the incoming benzene.

Y, (n) К „Х, (П-2) + К, Х, (П-2) + К„ Х (П-2) -нК „У,. (П-2); ) K ,,, X, (P-2) + K, X (P-2) + K, X, (P-2) -1- (P-2);

Y (n) K „X, (P-2) + K, X (P-2) + K„ X, (P-2) + K, Y (P-2),

t

where X is the temperature of the benzene distribution of the coefficients K-, of the corresponding mixture; the equations of the system described above.

X is the temperature of the salt bath apparatus;

X, is the consumption of benzene;

25 According to the optimal one-step identification algorithm using P — discrete time; data obtained from meters

Y; - temperature in the i-th point; 11-16. Regulator 6 carries K; - - - coefficient. calculating the value of the control action. The equations take into account the dynamic JQ st values so that the predicted value of the characteristics of the channels involved. the temperature in the seventh point is four; At each step, in blocks 3, 4 and 5, the two strokes are equal to the specified time; identification is carried out by the formula:

X, (P)

Yi.qA.2.i..x, inL: .iSi.x inhK2sY.lnL to „

where Y is the temperature setpoint.

The control channel is the flow rate of benzene, as the least inertial parameter.

Based on the obtained control value, the temperature is predicted at the sixth point of the model 9 temperature control using the equation for the test point. When the prediction i exceeds the limit value, the control action is corrected so that the temperature does not exceed the limit value:

Yrp - Yfe (P + 2)

X j

X,

to.

gb

where is y

7

- corresponding to the temperature limit value;

Yg (P + 2) - temperature forecast.

Otherwise, the control action does not change.

air mixture, molten salts in the apparatus, as well as the consumption of benzene.

Three zones of the apparatus can be distinguished where the reaction is most intense, i.e. temperatures reach maximum values and change dramatically as input variables change. This is the fifth, sixth, and seventh points of the existing numbering of the points of catalyst temperature control along the vertical of the apparatus. For them, there are equations that fairly accurately describe the temperature behavior at these points:

0

50

five

Similarly, the acceptance of the resulting control is verified by the model for the fifth temperature control point.

The functions of blocks 3-10 can be: implemented using a computing device.

The advantage of this system is greater accuracy of regulation; ny temperature process.

According to preliminary estimates based on modeling using experimental data, the use of a control system will reduce the value of the standard deviation (MSE) to 0.35 O, where b is the Existing value of MSE.

The use of this method for automatic control of the batch synthesis process

improve the quality of control, thereby reducing the consumption of benzene by 1.5%.

Claims (1)

Invention Formula A method for automatically controlling the synthesis of maleic anhydride, by measuring and regulating the supply of air and benzene to the evaporator of the contact apparatus, the temperature of the salt bath of the contact apparatus by changing the flow of condensate into it And measuring the temperature profile in the apparatus, about m l and Editor N. Gunko Compiled by T.Golenshina Tehred M. Khodanych Proofreader L. Brskid Order 3450/27 Circulation 371Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab. D. 4/5 ..Production and printing company, Uzhgorod, st. Design, 4. 28346-6 In addition, in order to reduce the consumption of benzene, the temperature of the benzene-air mixture at the inlet of the contact apparatus is additionally measured using measured values of benzene and benzol temperature of the air mixture at the inlet of the contact apparatus, salt bath of the apparatus and temperature in control The 10 point of the apparatus determines the calculated value of the flow rate of the benzl at which the predicted temperature value at the control point of the apparatus is equal to the preset value, and stabilizes f5 is the calculated value of benzene consumption.