SU1276880A1 - Automatic control system for process of burning - Google Patents

Abstract

AUTOMATIC REGULATION OF THE COMBUSTION PROCESS containing temperature and vacuum sensors installed in the furnace chamber, the output of the latter through the air flow regulator and the actuator connected to the fan guide of the fan, the temperature controller which output is connected to the engine connected through the speed regulator with a scraper fuel pusher, temperature and vacuum regulators, connected respectively to the first input of the temperature controller and to the second input of the flow controller in Air, characterized in that, in order to improve the control accuracy, it is equipped with an amplifier, a correction amplifier, a first and second adders, an integrator, an engine speed sensor, a correction regulator and a differentiation unit, the temperature sensor being connected via a series-connected amplifier, the first adder , the integrator, the second adder and the correction amplifier to the second input of the temperature controller, the output of the engine speed sensor through the adjustment regulator is connected to the third the air flow regulator input, the output of which through the differentiation unit is connected to the second W input of the second adder, while the output from the amplifier is connected to the third input of the second adder, and the output of the correction amplifier is connected to the second input of the first adder. 1HE O5 00 00

Description

The invention relates to the automatic regulation of the combustion process in the furnaces of various power plants, for example, in the furnaces of drying plants.

The purpose of the invention is povyshnye accuracy.

The drawing shows a block diagram of the automatic control system.

The system contains a combustion chamber 1 with temperature sensors 2 installed in it and a vacuum pressure sensor 3. The feeding of the furnace into the combustion chamber is carried out by the scraper feeder 4, and the combustion air is supplied by the fan 5.

The output signal of the temperature sensor 2 is fed through a serially connected amplifier 6, the first adder 7, the integrator 8, the second adder 9 and the correction amplifier 10 to the input of the temperature controller 11. The other input of this regulator receives a signal from the output of the temperature setpoint 12. The output of amplifier 6 is connected to the second input of the second adder 9, and the output of the correction amplifier 10 is connected to the second input of the first adder 7. The output signal of the temperature regulator 11 is fed through the speed regulator 13 to the motor 14, which changes the speed of the scraper feeder 4, and accordingly and the amount of fuel supplied to the furnace.

The output of the dilution sensor 3 is fed to the first input of the air flow regulator 15, the second input of which receives a signal from the vacuum generator 16, and its third input receives a signal from the output of the adjusting regulator 17, whose input is connected to the output of the speed sensor 18, measuring the rotational speed of the engine 14. The output signal of the air flow regulator 15 is fed to the actuator 19 controlling the fan guide 5, as well as through the differentiation unit 20 to the third input of the second adder 9.

The system works as follows.

When the temperature in the combustion chamber 1 changes, the thermo-emf of temperature sensor 2 changes. This change is aperiodic in nature and has a constant time. To reduce the time constant of the temperature sensor between it and the temperature controller 11, a correction element is connected, consisting of amplifier 6, first adder 7, integrator 8, second adder 9, and corrective amplifier 10.

Compiled by I. Bulkin

Editor N. Kishtulintstehred I. Vereye Corrector T. Kolb

Order 6654/31 Circulation 5 4 Subscription

VNIIPI State Committee of the USSR

for inventions and discoveries

 13035, Moscow, Zh-35, Raushsk iab., 4/5

Branch PPP "Patent, Uzhgorod, st. Project, 4

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The output signal of the amplifier 6 is fed through the adder 9 and the correction amplifier 10 to the second input of the temperature controller 11. The output of the correction amplifier 10 is also fed to the input of the first adder 7, where it is compared with the output signal of the amplifier 6. If the signal at the input of the amplifier 6 does not change, then at the output of the amplifier 6 and at the output of the correction amplifier 10 the signals are constant, and therefore the output the signal of the first adder 7 is zero.

When the signal at the input of the amplifier 6 changes at the first moment, a steeply increasing signal arrives at the input of the regulator 11.

The output of the first adder 7 becomes non-zero and a chain consisting of integrator 8, second adder 9 and correction amplifier 10 is activated, which means that the signal at the output of correction amplifier 10 smoothly increases until the signals at the inputs the first adder 7 does not match.

At the input of the temperature controller 11, two signals are compared: the output signal of the correction amplifier 10 and the output signal of the temperature setpoint 12. The temperature controller 11 forms a predetermined control law and, in accordance with this law, controls the electric motor 14 via the speed controller 13, increasing or decreasing the speed of the scraper feeder 4 of the fuel.

Information about the speed of the scraper feeder 4 fuel, and accordingly about the amount of fuel fed to the furnace, is transmitted through the speed sensor 18 and the corrections of the regulator 17 to the third input of the air flow regulator 15, to the first input of which air is supplied , and on the second - a signal from the setting unit 16 of the vacuum. The air flow regulator forms a predetermined law of regulation and, in accordance with it, controls the actuator 19 of the fan guide 5.

With a sharp increase or decrease in the air supply, the temperature in the combustion chamber changes rapidly, which can lead to jumps in the fuel supply. To prevent this phenomenon, the output signal of the air flow regulator 15 through the differentiation unit 20 is supplied to the third input of the second adder 9 and smoothes the surges at the input of the regulator 11.

Claims (1)

SYSTEM OF AUTOMATIC CONTROL OF THE BURNING PROCESS, containing temperature and vacuum sensors installed in the combustion chamber, the output of the latter through an air flow regulator and an actuator connected to a fan guide, a temperature regulator, the output of which through a speed regulator is connected to the engine connected to the scraper fuel feeder, temperature and vacuum, respectively connected to the first input of the temperature controller and to the second input of the air flow controller characterized in that, in order to improve regulation accuracy, it is equipped with an amplifier, a correction amplifier, a first and second adder, an integrator, an engine speed sensor, a correction controller and a differentiation unit, the temperature sensor being connected via a series-connected amplifier, a first adder, an integrator, the second adder and the correction amplifier to the second input of the temperature controller, the output of the engine speed sensor through the correction controller is connected to the third input of the controller air flow torus, the output of which through the differentiation unit is connected to the second input of the second adder, while the output of the amplifier is connected to the third input of the second adder, and the output of the correction amplifier is connected to the second input of the first adder. 1276880 A1