SU1232648A1 - Control system for process of reducing roasted alunite ore in production of alumina - Google Patents

Description

the sulfur dioxide anhydride gas analyzer is connected to the output of the block for determining the change in the concentration of sulfur dioxide, the second input of which is connected to the output of the clock device; the output channel of the block for determining the change in the concentration of sulfur dioxide is connected to the regulator

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The invention relates to non-ferrous metallurgy and is intended for the automatic control of α-dngms from technological conversions in the production of alumina from alunite raw materials.

The aim of the invention is to increase the recovery of alumina from the ore and to save elemental sulfur,

The drawing shows a schematic diagram of the proposed system.

 The system contains a fluidized bed apparatus 1, an ore supply pipeline 2, a reducing agent supply pipeline (sulfur), an air supply pipeline 4, a pipeline 5 through which gaseous reaction products are sent to a sulfuric acid production plant, an air supply pipeline 6 to an area located under the fluidized bed, sensor 7 of the temperature in the fluidized bed of the apparatus, regulator 8 of the temperature in the fluidized bed, temperature setpoint 9, actuator 10 installed on the pipeline for supplying the ores to the apparatus.

The system also comprises a flow rate sensor 11 blowing, a flow rate controller 12 blowing, an actuator 13, an oxygen concentration sensor 14 in the blast, a signal multiplying unit 15.

In addition, the system includes a controller 16 for the flow of oxygen supplied with blast, a unit 17 for the indicated oxygen rate, a signal multiplication unit 18, a scale unit 19, a summation unit 20, a temperature sensor 21 in the settling zone of the apparatus, a temperature controller 22 in the settling tank zone, setpoint 23 temperature c. a settling zone, a signal multiplying unit 24, a scale setpoint 25, a flow controller 26, Vos-1232648

changes in the concentration of sulfur dioxide - anhydride, the second input channel of which is connected to the unit for changing the concentration of sulfur dioxide in the exhaust gases, and the output channel of the regulator for changing the concentration of sulfur dioxide is connected to the third input of the summation unit.

Installer setting device 27 of the consumption of the reducing agent at the executive device 28 installed on the supply line of the reducing agent to the apparatus. The system also contains a sensor 29 for the concentration of sulfur dioxide in the exhaust gases, a block 30 for determining the change in the concentration of sulfur dioxide, a regulator 31 of

changes in the concentration of sulfur dioxide

hydride, unit 32 changes in the concentration of sulfur dioxide and the clock device 33.. J5 of the system are interconnected as follows.

Temperature sensor 7 is connected to the first input of temperature controller 8, the second input of this controller is connected to temperature setpoint 9. The output of the regulator 8 is connected to the input of the actuator 10. The output of the flow rate sensor 11 is connected to the input of the flow regulator 12 and the first input of the multiplication unit 15. The output of the controller 12 is connected to the input of the actuator 13. The second input of the multiplication unit 15 is connected to the output of the oxygen concentration sensor 14, the output

The multiplication unit 15 is connected to the first input of the oxygen consumption regulator 16 in the blown, the second input of this controller is connected to the setting device 17, and Vmx: one is connected to the first input

channel block 18 multiplying signals. The second input of the multiplication unit 18 is connected, dinene: with the output of the scale setting unit 19, and the output of the multiplication unit 18 is connected to the first input of the adding unit 20. The summation unit by the second input is connected to the output of multiplication unit 24, and the output is connected to the input of the regulator 26 of the flow rate of the reducing agent.

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The regulator 26 of the consumption of the reducing valve. The second input is connected to the output of the sensor 27 of the consumption of the reducing agent, and the output - to the input of the actuator 28. The first input of the signal multiplying unit 24 is connected to the output of the scale setting unit 25, the second input of the block 24 is connected to the output of the regulator torus 22 temperature in the settling zone. The inputs of the controller 22 are connected to the outputs of the temperature sensor 21 and the setting device 23. The input of the sulfur dioxide anhydride concentration determination unit 30 is connected to the sulfur dioxide anhydride concentration sensor 29 and the clock device 33, the output blocks 30 are connected to the first input of the sulfur dioxide anhydride concentration controller. The second input of the controller 31 is connected to the output of the setting device 32, the output of the controller 31 is connected to the third input of the summing unit 20

The system works as follows.

With increasing (decreasing) temperature in the apparatus, measured by sensor 7, above (below) the value set by setpoint 9, the output signal of controller 8 increases (decreases), and actuator 10 decreases (increases) the flow cross section, reducing (increasing) flow ore into the apparatus. In this way, the temperature in the apparatus is stabilized.

In turn, a decrease (increase) in the supply of ore to the apparatus leads to a decrease (increase) in the supply of sulfur contained in the ore in a bound form, and the concentration of the reducing agent increases (decreases) in the ore layer. With increasing (decreasing) concentration of the reducing agent, a larger (smaller) amount of reducing agent is carried to a settling zone with an oxidizing atmosphere created by supplying oxygen-containing blowing there. In this case, a larger (smaller) amount of reducing agent is oxidized in the settling zone, which leads to an increase (decrease) in the temperature in the settling zone measured by sensor 21. The signal at the descent of the sensor 21 increases (decreases) when the value is greater (smaller), what is set by the setting device 23, the output signal of the regulator 22 decreases (increases), respectively, and is equal to 1 (a decrease of 2 G. 4 8L

b) the BbixoAHoff signal of the block 24 and the adder 20, Decrease (an increase in the signal of the adder 20 relative to the signal arriving at the second g input of this regulator 26 from the sensor 27 causes the regulator 26 to increase (decrease) the output signal p arriving on the actuator 28. Device 28

) Q reduces (increases) the flow area and thus reduces (increases) the flow of the reducing agent into the ore layer.

Decrease (increase) feed

5 the reducing agent in the ore layer, in turn, leads to a decrease (increase) in the change in the concentration of sulfur dioxide in the exhaust gases, defined by blocks 29 and 30, when 2Q than when changing the concentration by an amount greater (smaller) than that set by unit 32, the controller 31 reduces (increases) the output signal to the input of the third

5 inputs of the summation block 20. When this controller 26 additionally reduces (increases) the signal at the input of the actuator 13, which reduces (increases)

Q flow area, which leads to an additional decrease (increase) in the consumption of the reducing agent.

A decrease (increase) in the consumption of the reducing agent leads to a decrease (increase) in the output signal of the .29 and 30 blocks.

As the oxygen content in the blast increases (decreases), the signal at the output of the oxygen concentration sensor 14 and, accordingly, at the output of the product block 15, increases (decreases). The signal entering regulator 16 will become larger (less) than the signal coming from setpoint 17. Regulator 16 reduces (increases) the signal supplied as a reference to regulator 12, the output of which decreases the signal (increases). This will lead to a decrease (increase) in the flow area in

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the actuator 13 and, accordingly, decreases (increases) the flow rate of the blow supplied through the pipeline 4.

Due to the fact that the flow blow, 5 supplied to the fluidized bed, varies within a limited range, the actuator 13 has limit values for the maximum and

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minimum flow area. In case of reaching the minimum (maximum) cross section by the device 13, the mode control is carried out only over the channel: production block 15, multiplication block 18, scale setter 19, summation block 20. Increasing (decreasing) the signal at the output of the work unit 15 results in an increase (decrease) in the signal at the output of the proe unit 18 (maintained at the scale set by the setting unit 19. Increasing (decreasing) the signal from the unit 18 to the input of the adder 20 increases (decreases) setting the reducing agent consumption controller 26. Increasing (decreasing) the oxygen content in the blast and increasing (decreasing) the supply of the reducing agent leads to an increase (decrease) in the temperature in the apparatus through the channel: temperature sensor 7, temperature controller 8 with temperature setting device 9, actuator 10, apparatus loads for ore.

Thus, in each control cycle, a balance is maintained between the supply to the apparatus of heat, ore, oxygen with blast, and a reducing agent consumed for oxygen oxidation to blow and the reduction of sulfur contained in the ore as compounds to sulfurous anhydride; which leads to an increase in extraction of linozem from the ore and to the saving of elemental sulfur.

The implementation of the system is possible on the basis of standard automation tools. Thus, as the temperature sensors 7, 21, thermocouples HK can be used in combination with a converter ТЭДС to current ПТ-ТП-68 and an electropneumatic converter ЭППП-63. As setters 17, 19, 23, 25, and 32, you can use the remote control panel AJU-BITU controllers 8, 12, 16, 22, 26, and 31,

as well as actuators 10, 28), 13 can be selected according to the catalogs of the pipeline shut-off and regulating a) matra (depending on the flow rate of the controlled medium).

The multiplier-division device 11F1 can be used as a product unit. 18 of the START system and the summation block is a device of the simplest algebraic operations PF1. 1 too

systems START, gas analyzers for oxygen devices of the ANG-1 type and gas analyzers for sulfuric anhydride AGK-1.

The clock device 33 may be

assembled from USEPPA elements according to standard schemes.

The invention makes it possible to increase the recovery of alumina and sulfur dioxide from the ore. An increase in sulfuric anhydride from alunite is equivalent to obtaining an additional amount of elemental sulfur.

Claims (1)

SYSTEM OF MANAGEMENT OF THE PROCESS OF RESTORING BURNED ALUNI -. YOUR ORE IN THE PRODUCTION OF ALUMINUM, consisting of a node for stabilizing the temperature in the reaction zone, containing a sensor, a setter 'and a temperature controller and an actuator, nodes for controlling the flow rate of the reducing agent and blast supplied to the apparatus, containing the corresponding sensors, regulators, and devices for controlling expenses, that, in order to increase the extraction of alumina from the ore and save sulfur, it additionally contains an oxygen analyzer installed on the line, blowing air into the apparatus, gas analyzer sulfur dioxide installed on the line leaving the gas apparatus, three signal multiplication units and a signal summing unit, a sensor, a regulator and a setter for settling zone temperature, a regulator and a setter for changing the concentration of sulfur dioxide, a regulator and a set unit for oxygen consumption in the blast, a determination unit changes in the concentration of sulfur dioxide and a clock device, two scalers, the output of the oxygen analyzer connected to the first input of the first multiplication unit, the second input of the first unit multiplied I am connected to the output of the blast flow sensor, and the output of the first multiplication unit is connected to the input of the oxygen flow controller. In the blast and to the first input of the second multiplication block, the second input of the oxygen flow controller in the blast is connected to the oxygen flow controller in the blast, the output of the oxygen flow controller the blast is connected to the input of the blower flow controller, and to the second input. the output of the second multiplication unit is connected to the output of the first scaler, the output of the second multiplication unit is connected to the first input of the signal summing unit, the output of the signal summing unit is connected to the input of the reducer flow regulator, the output of the third multiplication unit is connected to the second input of the signal summing unit, the inputs of which are connected to the second setter the scale and output of the channel of the temperature controller in the settling zone of the apparatus, the input channels of which are connected to the set point and the temperature sensor hydrochloric zone, moreover, the yield of sulfur dioxide gas analyzer connected to the output determination unit changes in the concentration of sulfur dioxide, a second input coupled to a clock output unit, the output channel determination unit changes sulfur dioxide concentration, coupled with changes in the concentration of sulfur regulator. an anhydride, the second input channel of which is connected to the master for changing the concentration of sulfur dioxide in the exhaust gases, and the output channel of the regulator for changing the concentration of sulfur dioxide is connected to the third input of the signal summing unit. f