SU1573308A1 - Automatic control system for feeding air to subfurnace of power processing waste-heat boiler - Google Patents

Abstract

The aim of the invention is to improve the accuracy of regulating the air supply to the underflooding of an energy technological waste heat boiler using heat from the flue gases of the heating furnace. The goal is achieved by the fact that the system containing sensor 3 for total air flow, regulator 8 for total air flow rate, sensor 4 for fuel consumption entering the sub-heating boiler, sensor 5 is the percentage of oxygen in the flue gases at the exit of the heat recovery boiler, regulator 28 of the oxygen content in the flue gases, unit 9 of the fuel-air ratio, unit 14, the specific air flow required for burning the air entering the sub-flow under stoichiometric conditions, unit 13 of the magnitude of the excess-air coefficient correction the ear in the sub-heating boiler, the unit 15 is the specific volume of flue gases generated by burning the fuel supplied to the sub-fuel under stoichiometric conditions, the unit 17 is the excess air ratio reduced by one, the unit 19 is the percentage of oxygen in the air, three blocks 10, 11, 12 multiplication, block 16 summation, additionally introduced sensor 5 percentage of oxygen in the flue gases coming from the furnace into the waste heat boiler, sensor 6 of the fuel consumption entering the furnace, unit 24 values of the specific volume of smoke new gas generated during the combustion of fuel in the furnace under stoichiometric conditions, three blocks 18, 20 and 25 summation, three 22, 23, 26 multipliers and two blocks 21, 27 divisions. The total air flow is adjusted by regulator 28, to the inputs of which signals are received of the actual and calculated specified oxygen content in the flue gas at the outlet of the waste-heat boiler. 1 il.

Description

one

(2-1) 4474499 / 24-06

(22) 08.26.88

(46) 23.U6.90. Bul N 23

(71) Scientific and Production Association for Automation of Mining, Metallurgical Enterprises and Energy Objects of Ferrous Metallurgy Dnepchermetavtomatika

(72) G.N.Sidorin, V.V.Dobrop, A.D.Sergeev, L.V.Sochinsk, V.A.Dudkina, A.I. Osipov, V.N.Schadrin, P.V.Mnlova - new and A.F. Zimmerman

(53) 621.182.26 (088.8)

(56) USSR Copyright Certificate No. 1469249, cl. F 23 S 1/02, 1986.

(54) SYSTEM OF AUTOMATIC REGULATION OF THE AIR SUPPLY INTO THE ENERGY-TECHNOLOGICAL UTILIZER BOILER

(57) The purpose of the invention is to jump

the accuracy of adjusting the air supply to the underflooding of an energy technological waste heat boiler using heat from the flue gases of the heating furnace. The goal is achieved in that the system containing the sensor 3. total air flow rate, total air flow rate controller 8, fuel consumption sensor 4 supplied to the sub-heating boiler, sensor B is the oxygen content in the flue gases at the waste-heat boiler outlet, flue gas oxygen controller 28, fuel ratio control 9 - air, unit 14, specific air consumption, necessary for combustion of air entering the sub-floor under stoichiometric conditions, unit 13, the value of the excess coefficient correction

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air in the heating of the recovery boiler unit 15 specific volume of flue gases generated by burning the stoichiometric fuel supplied to the sub-fuel, unit 17 of the coefficient of air reduced per unit, unit 19 of the oxygen content of the air, three blocks 10, 11, 12 the sensor unit 16 is the summation, up to-1- a sensor of 5 percent oxygen content in the flue gases coming from the furnace into the

The invention relates to industrial heat and power engineering, in particular, 20 to regulating the supply of total air to the sub-power energy technology waste heat boiler (ETC), which uses heat from the flue gases of heating furnaces and Uses 25 at the ferrous metallurgy enterprises.

The aim of the invention is to improve the accuracy of regulating the air supply to the sub-heating of the recovery boiler.

The drawing shows the structural diagram of the system of automatic control of the air supply to the energy technological waste heat boiler.

The system contains a heating furnace 1. With energy technology cattle- 35 scrap utilizer 2, a sensor 3 for total air flow to the ETKU underfloor, a sensor 4 for fuel consumption entering the ETK's underflooding, a sensor for 5% oxygen content in the flue 40 gases entering the furnace - utilizer, sensor b of fuel consumption entering the furnace, sensor 7 percentage of oxygen in the flue gases at the exit of the utilization boiler 45.

The sensor 3 for the total air flow to the underfloor ETKU is connected to the inlet of the regulator 8 for the total air flow, to the other input of which is connected, Q unit 9 of the fuel-to-air ratio.

The sensor 4 for fuel consumption entering the flooding of the ETKU is connected to the input of the regulator 8 and to the first inputs of the multiplication blocks 10-12. To the second input of the first block 10 multiplication is connected unit 13 of the correction value of the coefficient of excess air in

waste heat boiler, sensor 6 for fuel consumption entering the furnace, unit 24 of the value of the specific volume of flue gases formed during fuel combustion in the furnace under stoichiometric conditions, three blocks 18, 20 and 25 summation, three 22, 23, 26 blocks of multiplication and two blocks 21, 27 divisions. The total air flow rate is adjusted by the regulator 28, to the inputs of which signals are received of the actual and calculated specified oxygen content in the flue gases at the outlet of the waste-heat boiler. 1 il.

subtotal ETKU. To the second inlet of the second multiplication unit 11, the setting device 14 is connected with the specific air flow rate required for burning the fuel supplied to the ETKU under the stoichiometric conditions. To the second input of the third multiplication unit 12, the unit 15 is connected to the specific volume of flue gases generated by burning the fuel supplied to the ETKU under stoichiometric conditions.

The output of the first multiplication unit 10 is connected to the first input of the first summation unit 16, to the second input of which the unit 17 is connected to the excess air ratio reduced by one, and the output of the summation unit 16 is connected to the third input of the second multiplication unit 11. The sensor 5 of the oxygen content in the flue gases coming from the furnace to the ETCU is connected to the subtractive input of the second summation unit 18, to the summing input of which is connected the unit 19 of the oxygen content of the air.

The output of the second multiplication unit 11 is connected to the input of the third summation unit 20, to the other inputs of which the output of the third multiplication unit 12 is connected, and the output of the first division unit 21. The input of the splitter of the division unit 21 is connected to the output of the second summation unit 18, and the input of the dividend is connected to the output of the fourth multiplication unit 22. The input of the latter is connected to the sensor 3, and its other input is connected to the output of the fifth multiplication unit 23.

The sensor 6 for fuel consumption entering the furnace is connected to the first input of the multiplication unit 23, the second input of which is connected to the setter. 24 are the values of the specific volume of flue gases generated by the combustion of fuel in the furnace under stoichiometric conditions, and the output of multiplication unit 23 is connected to the input of the third summation unit 20.

The output of the first division unit 21 is connected to the first input of the fourth summation unit 25, the second input of which is connected to the output of the second multiplication unit 11, and the output of the summation unit 25 is connected to the input of the sixth multiplication unit 26, the other input of which is connected to the setting unit 19.

The output of the sixth multiplication unit 26 is connected to the first input of the second division unit 27, the second input of which is connected to the output of the addition unit 20. The output of the dividing unit 27 is connected to the inlet of the regulator 28 for oxygen in the flue gases, and the sensor 7 is the percentage of oxygen in the flue gases at the outlet of the control unit connected to the second inlet of the regulator 28. The outlet of the latter is connected to the inlet of the regulator 8 for the total air flow, the output of which connected to the actuator 29 of the regulator 30 of the blower fan

The system works as follows.

The signal from the fuel consumption sensor 6 entering the furnace 1 enters the first input of the multiplier 23, and the second input receives the signal of the setpoint 24 of the specific volume of flue gases generated during the combustion of fuel entering the furnace under stoichiometric conditions. Block 23 generates a signal representing the theoretical amount of flue gases produced by burning the fuel entering the furnace per unit of time.

The signal from sensor 5 of the percentage of oxygen in the flue gases of the furnace 0, p (%) is fed to the subtractive input of the summation unit 18, to the summing input of which the signal from the generator 19 of the percentage of oxygen in the air arrives. The output signal of block 18, which is the difference between the oxygen content in the air and flue gases

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furnace, enters as a divider to the input of the block 21 division. At its other input, the output signal of multiplier 22 is supplied as a dividend. This unit multiplies the signals from the outputs of multiplication unit 23 and sensor 5. The output signal of unit 21 represents the amount of air in Q flue gases flowing from the furnace into the waste heat boiler per unit time.

The theoretical amount of flue gases generated during the combustion of fuel entering the sinking of the recovery boiler per unit of time is generated in multiplication unit 12, the first input of which receives a signal from the sensor 4 of fuel consumption entering the sinking of the recovery boiler and the second input the signal of the setting device 15 of the value of the specific volume of flue gases generated during the combustion of the fuel entering the sub-heating boiler.

The sensor 4 signal also enters the first input of the multiplication unit 10, the second input receives a signal from the setpoint 13 of the correction value of the air excess factor in the sub-heating of the waste-heat boiler. At the output of multiplication unit 10, a signal is generated which is fed to the subtracting input of summing unit 16. The summing input receives a signal from the setting unit 17 of the air excess factor reduced by one, and the output signal of the adding unit 16 is fed to the third input of the multiplication unit 11, the second input of which receives a signal from the setting unit 14 the specific air flow necessary to burn the boiler entering the heating -utilizer in stoichiometric conditions. The first input of the multiplication unit 11 receives a signal from the sensor 4, and the output signal is the amount of excess air supplied to the combustion of the fuel to the sub-heating of the waste-heat boiler per unit of time.

This signal arrives at the second input of summation unit 25 and at the third input of summation unit 20. The output of unit 25 is the amount of air contained in the flue gas at the outlet of the waste heat boiler per unit of time.

The oxygen content in this air is formed by a block of 26

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neither, to the second input of which the output signal of block 25 is fed, and to the first input — signal of setpoint 19. The output signal of block 26 is supplied as a dividend to the first input of block 27 of division. The second input as a divider receives the output signal of block 20, the inputs of which receive the output signals of blocks 23 and 12. The output signal of block 20 represents the flue gas flow rate at the outlet of the waste-heat boiler per unit of time.

The output of dividing unit 27 is the reference for the percentage of oxygen in the flue gas at the outlet of the waste-heat boiler

The output signal of dividing unit 27 and the sensor signal 7 of the percentage of oxygen in the flue gases at the outlet of the waste-heat boiler is fed to the inputs of the regulator .28 oxygen content in the flue gases. The output of this regulator is fed to the input of the regulator 8 of the total water flow. To the other input of the last one there will sleep a signal on the consumption of fuel entering the sub-heating of the waste-heat boiler.

Pa from sensor 4, to the third input, a feedback signal from sensor 3 of the total air flow to the sub-heating boiler, and to the fourth, the signal from setpoint 9 according to the fuel-air ratio.

The regulator 8, acting on the actuator 29, changes the position of the regulator of the blower fan 30, reducing or increasing the flow of total air into the sub-floor of the control unit.

Claims (1)

Invention Formula The system of automatic control of the air supply to the underflooding of an energy technological waste heat boiler using heat from the flue gases of the heating furnace, containing a unit for the percentage of oxygen in the air, a sensor for the fuel input to the underflow of the energy technological waste heat boiler, the output of which is connected to the inputs of the first, second and third units multiply and to the input of the total air flow controller, setpoint for the correction value of the air excess factor in the sinking of the boiler 08 eight The lysator, the output of which is connected to the second input of the first multiplication unit, the unit for the specific air flow required to burn the fuel coming into the subminutant of the waste heat boiler under stoichiometric conditions, the output for which is connected to the second input for the second multiplication unit, the unit for the specific volume of flue gases generated during the combustion of the fuel utilizing boiler that is fed into the underflooding under stoichiometric conditions, the output of which is connected to the second input of the third multiplication unit, sets the excess factor 0 five 0 five 0 45 50 five air reduced by the unit whose output is connected to the input of the summation unit, to the subtractive input of which the output of the first multiplication unit is connected, and the output of this summation unit is connected to the third input of the Second multiplication unit, the common air flow sensor, the output of which is connected to the controller the total air flow rate, the fuel-air ratio adjuster, the output of which is connected to the inlet of the said regulator, the oxygen percentage sensor in the flue gases at the outlet of the boiler, the output of which is Connected to the inlet of the oxygen content regulator, in the flue gases, the outlet of which is connected to the first inlet of the common air flow regulator, the outlet of which is connected to the executive mechanism of the blower fan, characterized in that in order to improve the accuracy of the regulation of the air supply to the heating of the boiler -utilizer, it additionally contains a sensor for fuel consumption entering the furnace, a sensor for the percentage of oxygen in the flue gases coming from the furnace into the waste-heat boiler, a unit for the value of the specific volume of smoke exhaust gases generated during combustion of stoves in stoves under stoichiometric conditions, three summation units, three multiplication units, two dividing units, with the flow sensor of the fuel entering the furnace connected to the input of the fourth multiplication unit, to the second input of which the unit is connected the values of the specific volume of flue gases formed during the combustion of fuel in a furnace under stoichiometric conditions, and the output of this multiplication unit connected to the inputs of the fifth multiplication unit and the third summation unit, the output of the oxygen percentage sensor in the flue gases coming from the furnace into the waste heat boiler, connected to the second input of the fifth multiplication unit and to the subtraction input of the second summation unit, To the summing input of which the sensor for the oxygen percentage in air is connected, which is also connected to the first input of the sixth multiplication unit, the output of the second summation unit is connected to the input of the divider of the first division block, to the input of the divisible the output of the first multiplication block is connected to, the output of the first division block is connected to the second the input of the third summation unit and the input of the fourth summation unit, to the second input of which the output of the second multiplication unit is connected, and the output of the fourth summation unit is connected to the second input of the sixth multiplication unit, to the third and fourth inputs of the third unit the summation is connected to the outputs of the second and third multiplication units, respectively, and the output of the third summation block is connected to the input of the divider of the second division block, to 5 to the input of the dividend which is connected to the output of the sixth multiplication unit, the output of the second dividing unit is connected to the first input of the regulator of oxygen content in the flue gases.