SU850586A1 - Method and device for automatic control of soda monohydrate production process in drum crystallizer - Google Patents

Description

It sets the operation mode of the device. In addition, the known technical solution E does not take into account changes in the temperature of the incoming material flows, which also adversely affects the moisture stabilization of the finished product.

The purpose of the invention is to stabilize the moisture content of the finished product.

The goal is achieved by the fact that the condensate consumption is additionally regulated depending on the electrical resistance of the monohydrate soda) in the drum crystallizer, measured at a distance equal to {20-30% of the length of the drum from the side of its loading and, moreover, is corrected by the temperatures of the light soda and condensate, and the device is equipped with a soda monohydrate electrical resistance control circuit including a soda monohydrate electrical resistance sensor, current and electropneumatic transducers, a regulator electrical resistance of soda, while the output of the sensor of electrical resistance of soda is through the current and electropneumatic converters connected to the input of the regulator of electrical resistance of soda, and the output of the latter is connected to the input of the regulator of consumption flow capacitor.

In addition, the device is equipped with light soda and condensate temperature control circuits containing temperature sensors of light soda and condensate, current and electropneumatic transducers, temperature controllers of light soda and condensate, while the output of the temperature sensor of light soda through current and electric

pneumatic converters are connected to the input of a light soda temperature controller, the output of which is connected to the input of a soda monohydrate electrical resistance regulator, and the output of a condensate temperature sensor is connected via current and electropneumatic converters to an input of a condensate temperature regulator whose Vrsod temperature is connected to the input of a light soda temperature regulator at This sensor of electrical resistance of soda is made in the form of an isolating flexible cable, at the end of which a current-carrying load is fixed, while the cable is mounted on a cantilever rod located in the side wall of the crystallizer on the side of its loading. The electrical resistance of soda monohydrate is inversely proportional to its moisture content. The supply of a device with a soda electric resistance control circuit allows you to almost instantly transmit a regulation signal to change the condensate flow rate at any change in the soda monohydrate moisture in the drum mold, which significantly stabilizes the moisture content of the finished product.

Introduction to the device for automatic control of the process of obtaining soda monohydrate of soda temperature control circuits for light soda and condensate temperature allows for adjusting the condensate flow when the temperatures of the incoming material flows change, which also has a positive effect on stabilizing the moisture content of the finished product.

The proposed design of the soda monohydrate electrical resistance sensor makes it possible to measure the electrical resistance directly at the site of soda monohydrate formation, which virtually eliminates the effect of transport retardation in the control object, which also stabilizes the humidity in the finished product.

In the drawing, an image is shown a device, a general view.

A device for producing soda monohydrate from light soda includes a transporting device 1 for light soda, a hopper 2, a loading auger 3 and a drum mold 4, a condensate collector 5.

A device for automatic control of the process of obtaining soda monohydrate from light soda in a drum mold contains a flow control loop for light soda, including a weight meter 6, a flow controller 7 for flow of light soda, a regulating member 8, a flow control loop for condensate including a restriction device 9, a flow regulator 10 the condensate and the regulator 11, the adder 12. The device also contains a circuit for regulating the electrical resistance of soda monohydrate, including an electrical sensor 13 soda, current and electropneumatic converters 14 and 15, regulator 16 for electrical resistance of soda monohydrate, light soda temperature control circuit, including light soda temperature sensor 17, current and electropneumatic converters 18 and 19, light soda temperature regulator 20, condensate temperature control loop, including a condensate temperature sensor 21, a current and electropneumatic converters 22 and 123, a condensate flow controller 24, an air sensor 25.

The sensor 13 for electrical contacting of soda monohydrate is in the form of an insulated flexible cable 26, at the end of which a conductive load 27 is fixed. The cable 26 is attached to a cantilever arm 45 g-e 28 located in the side drum crystallizer 4 on the side of the loading edge. The method is carried out in a speduk way. The light soda from the conveyance device 1 is fed by gravity into the hopper 2, from where it is dispensed through the charging auger shutter 3 into the drum crystallizer 4. From the collector 5, the condensate is dispensed into the drum chute 4, which is supplied depending on the light soda. With a constant consumption of light soda and condensate in the mold,. as well as at constant values of the electrical resistance of soda monohydrate and the temperature of light soda and condensate, the automatic process control device operates in steady state. At the same time, the ratio of the flow rate of the light weight to the flow rate of the condensate remains constant. When changing, for example, an increase in the flow rate of light soda, the modified signal from the output of the weight meter 6 is fed to one of the inputs to the control valve 12 and, accordingly, to the input of the regulator 10 of the condensate flow, causing the condensate flow to change to the desired value. When, for example, the soda monohydrate moisture changes in a drum crystallizer 4, the electrical resistance of soda monohydrate decreases, which causes a change in the signal at the output of the soda monohydrate electrical resistance sensor 13 and the output signal at the output of the current 14 and electropneumatic converter 15, and consequently, at the output of the regulator 16 The modified signal from the output of the regulator 16 of the electrical resistance of soda monohydrate is fed to another input of the bitchiator 12, and its output to the regulator 10 of the condensate flow ta. This will entail a reduction in the condensate consumption by an amount at which the previous value of humidity is restored. Similarly, the flow rate of condensate incl changes in the temperature of the condensate and the temperature {H1 of light soda. The control algorithm, which is implemented by the proposed device tnteet -sold view “- t“). “9 -signal at the output of the flow controller kszh-. sata; K,, Kj are the coefficients of the proportional and structural adjustment; - signaling the output of the sumliruk tse device. gd 5 to d to the module on the scoop of the dispatch from the center of the billet (reg. com measurement, P is the weight measurement output signal; Pgjj is the output signal of the soda monohydrate electrical resistance regulator . СССРАЭС-Ртс Р „, с тпоС дтг с-Ртк) Ч nuiCj rrtK ass) е Рдэс signal proportional to the electrical resistance of soda monohydrate; signal at the output of the temperature controller light sod; signal proportional to the temperature of light soda; Pj is the signal at the output of the condensate temperature controller; a signg proportional to the temperature of the condensate; signal at the set point; constants; The coefficients of proportionality are corresponding to the regulators of electrical resistance of soda monohydrate, light soda temperature, and condensate temperature. The proposed method of automatically controlling the process of obtaining soda ohydrate from light soda in the abane crystallizer allows the dehydration of monohydrate 1 in the range 18.1–20.5 wt.% According to recognition from 15.9–25.3 wt.% According to the known method, t . when used, their range of maintaining moisture of soda monohydrate is reduced by a factor of 3.9. The exohic effect of the introduction of the breasts is achieved due to the energy consumption for drying the finished product. Formulas of the invention 1. A method of automatically controlling the production of monohydraoids in a drum cylinder and controlling the flow rate of a condensate crystallizer depending on the flow rate of light soda, in order to stabilize the humidity of the finished condensate product, it is additionally removed depending on the electrical resistance of monohydrate i in the drum crystallizer, kept at a distance of 20-30%

Claims (5)

Claim 1. A method for automatically controlling the process of producing soda monohydrate in a drum crystallizer by controlling the flow of condensate into the mold depending on the flow of light soda, characterized in that, in order to stabilize the humidity of the finished product, the flow of condensate is additionally adjusted depending on the electrical resistance of the soda monohydrate in a drum mold, measured at a distance of 20-30% of the drum length from the loading side of the mold. 2. The method according to p. 1, with the fact that the condensate flow rate is adjusted according to the temperatures of light soda and condensate. 3. A device for automatically controlling the process of producing soda monohydrate in a drum crystallizer, comprising a light soda flow control loop, including a weight meter, a light soda flow controller and a regulator, a condensate flow control loop, including a constricting device, a condensate flow regulator and a regulator, an adder, one of the inputs of which is connected to the output of the weight meter, and the output is connected to a condensate flow controller, characterized in that, p. In order to stabilize the humidity of the finished product, it is equipped with a circuit for regulating the electrical resistance of soda monohydrate, including an electric resistance sensor of soda monohydrate, current and electro-pneumatic converters, an electric resistance regulator of soda monohydrate, and the output of an electric resistance sensor of soda monohydrate through a current and electric pneumatic converters is connected to the input of an electrical resistance regulator soda, and the output of the latter is connected to the input of the flow regulator to ndensata. 4. The device according to claim 3, characterized in that it is equipped with temperature control circuits for light soda and condensate containing temperature sensors for light soda and condensate, current and electro-pneumatic converters, temperature controllers for light soda and condensate, while the output of the light temperature sensor soda through current and electro-pneumatic converters is connected to the input of the temperature controller of light soda, the output of which is connected to the input of the controller of electrical resistance of soda monohydrate, and the output of the temperature sensor of sat coupled via the current to the input and elektropnevmopreobrazovateli condensation temperature regulator, whose output is connected to an input light soda temperature controller. 5. The device according to p. 3, with the fact that the soda electric resistance sensor is made in the form of an insulated flexible cable, • a conductive load is fixed to the end of the cable, while the cable is mounted on a console-mounted rod located in the side the crystallizer wall from the loading side.