SU1331566A1 - Apparatus for feeding electric precipitators for gas cleaning - Google Patents

Abstract

The invention relates to high voltage sources for powering gas cleaning electrostatic precipitators, can be used in the cement and chemical industries, and improves the efficiency of the gas cleaning process, stability and cost-effectiveness of operation, reduce energy losses and simplify the design of the device. The device contains a power step-up transformer with an additional low voltage winding; current-limiting reactor; main unit of controlled valves; An additional unit of controlled valves, connected in series with the additional winding of the step-up transformer. The device also includes a high-voltage rectifier, an electrostatic precipitator current sensor, a voltage sensor on the electrostatic precipitator, an automatic control unit, and a unit for automatically changing the slope of the control characteristic of the unit. An electrostatic precipitator is connected to the high voltage leads of the rectifier. 2 3.p. f-ly, 1 ill. with

Description

one

The invention relates to high voltage sources for powering electrostatic precipitators and can be used in the field of electrical purification of industrial gaseous emissions from suspended particles in cement, chemical, metallurgical, energy and other industrial emissions.

The purpose of the invention is to increase the gas cleaning efficiency, economical operation, increase reliability and simplify the device.

The drawing shows a schematic diagram of a device for supplying gas cleaning electrostatic precipitators.

The device contains a power step-up transformer 1 with an additional low-voltage winding 2, a current-limiting reactor 3, a main unit 4 controlled valves, an additional unit 5 controlled valves connected in series with the winding 2, a high-voltage rectifier 6, an electrostatic current sensor 7, a sensor 8 voltage on the electrostatic precipitator (high-voltage reactive divider), automatic control unit 9, unit 10, which automatically changes the slope of the control characteristics of the unit.

Electrostatic precipitator 1 1 is connected to the terminals of high voltage rectifier 6.

The automatic voltage and current control unit 9 of the electrostatic precipitator 11 comprises a voltage signal integrator I2 on the electrostatic precipitator 11, a selector 13 of spark and arc discharges, an operating current limiting unit 14, an overshoot limiting and limiting overvoltage module 15 when the device is idling, amplitude - phase converter 16, driver 17 for controlling pulses of the main unit of power controlled gates.

The unit 10, which automatically changes the slope of the regulating characteristic of the unit, contains a buffer amplifier 18, which is a voltage follower, the purpose of which is to match the high output impedance of the integrator with the low input impedance of the load, the module. 19 changes of the adjustment slope

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characteristics of the device, consisting of an amplitude comparator 20 with hysteresis, made using an operational amplifier covered by a positive feedback loop (resistors 21 and 22, variable reference source 23), an integrating circuit / resistor 2A, and

10 capacitor 25), a differentiating circuit (capacitor 26 and resistor 27) and a resistive adder (resistors 28 and 29). The input 30 of the integrating circuit 24 and 25 is the first input of module 19, the input 31 of the differentiating circuit 26 and 27 is the second input, and the output 32 of the comparator 20 is the output of module 19.

The electronic switch 33, providing (; a logical device, covered by voltage feedback on the power controlled valves and consisting of two four-input logic elements AND 34

5 and 35, an inverter 36 and two integrating circuits (elements 37-39 and (40-42), with the second 43 and 44, the third 45 and 46, and the fourth 47 and 48 inputs of logic elements 34 and 35 in pairs

30 are combined and are respectively the first 49, the third 50 and the fourth 51 inputs of the electronic switch 33. The inputs of the inverter 36 and the second integrating circuit 40-42 constitute the second input 52 of the electronic switch 33. The output of the inverter 36 is connected through the integrating circuit 37-39 to the first the input 53 of the logic element 35, the output of the second integrating

4 (j circuit 40-42 is connected to the first input

54 logic element 34. Outputs

55 and 56 logic elements 35 and 34 are outputs of electronic switch 33.

45 In addition, the device contains a driver for generating 57 control pulses of an additional block 5 controlled valves, a circuit 58 and 59 of the module for modulating the slope of the slope and the amplitude of the phase-to-phase converter 16.

The device works as follows.

In the pre-start state, the power supply units are supplied to all nodes and blocks.

At the output of the amplitude-phase converter 16, control pulses are set whose front corresponds to the starting angle of 35

After powering the Start-up operation, the modulation change slope modulating variable 19 generates a control signal providing the signal from the output of the amplitude-phase converter 16 through the electronic switch 33 to the input of the control pulse shaping unit 57. The pulses generated by shaper 57 are applied to the control electrodes of the unit 5 of power controlled gates. The valves open and a voltage appears on the electrostatic precipitator II, the value of which is determined by the initial angle of control and the transformation ratio of the power transformer I, determined by the ratio of the number of turns of the high voltage and the series-connected main and auxiliary low voltage windings. A signal from the sensor 8, proportional to the voltage on the electrostatic precipitator 11, is fed to the input of the integrator 12 through a buffer amplifier 18 to the inputs of the amplitude-phase converter 16 and the slope change module 19. This leads to an increase in the control angle and, as a result, to an increase in voltage on the electrostatic precipitator 11. Thus, the process of self-excitation (acceleration) takes place. As a result of the damping action of the integrator 12, the voltage on the electrostatic precipitator 11 gradually increases, and the rate of increase is determined this time of the integrator 12. The voltage build-up continues until one of the following situations occurs: in the precipitating space of the electrostatic precipitator 1 1 there will be spark or arc breakdowns; the current value of the electrostatic precipitator 11 will exceed the specified setpoint; the front of the pulse of the amplitude-phase converter 16 will begin ahead of the front of the current pulse of the electrostatic precipitator 11 (overshoot process).

In these cases, the voltage build-up on the electrostatic precipitator 11 will be suspended by the negative feedback signal of the respective blocks (selector 13 of the spark bits, operating current limit module 14, and overshoot limit module 15).

In the process of overclocking, one of the situations listed does not occur; when the conduction angles are strong

the output of control valves of the unit 5, which are close to critical, i.e. when the voltage on the electrostatic precipitator 11, and consequently, at the input 30 of the module 19, the change in the steepness is close to the limiting dp of the transformation ratio of the power transformer 1, at the time of the end of the control pulse at the output of the amplitude-phase converter -16 (input 31 of the module 19) At output 32 of module 19, a control signal appears.

The effect of this signal on the input 52 of the electronic switch 33 and through the circuit 58 and 59 on the input of the amplitude-phase converter 16 leads to a shift in the side lag of the output control pulse of the amplitude-phase converter 16 and to switch it (in the dead time,

when the voltage at the inputs 50 and 51 of the block 33 is present) by the electronic switch 33 from the input of the generator 57 of the control pulses of the additional block 5 of power controlled gates to the input of the generator 17 of the control pulses of the main block 4 of the power controlled gates. TaKiiM, during the half-period of the mains voltage, abruptly changes (increases) the transformation ratio of the power transformer 1 and the steepness of the control characteristics of the device.

The voltage regulation on the electrostatic precipitator 11 is carried out by changing the control angle of the gates of the unit 4. The lagging angle of the control angle is chosen such that the current of the electrostatic precipitator does not change at the first moment after switching blocks 5 and 4.

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55

A further gradual increase in voltage on the electrostatic precipitator continues, either until the control valves of block 4 are fully opened, or until a negative feedback signal appears at the output of one of the modules 13, 14, or 15. The voltage decrease at the electrodes of the filter 11 under the action of automatic or manual adjustment leads to reverse switching of the transformation ratio of the power transformer 1

51

and reducing the steepness of the adjustment characteristic.

At the same time, due to the fact that hysteresis was introduced in module 19 for changing the steepness, the value of which is determined by the ratio of the resistances of the resistors 21-23, the reverse change of the steepness occurs at control angles 2-3% below critical, which significantly increases the reliability of the device operation frequent spark and arc discharges, in the switching zone.

The technical and economic efficiency of the proposed device as compared with the known is determined by an improvement in gas cleaning by an average of 10-12% due to a 4-6% increase in the average voltage on the electrostatic precipitator, associated with a decrease in the amount of pulsation and an increase in the stability of the automatic control system at low levels. levels of breakdown voltages as a result of automatic change of the slope of the adjusting characteristic of the unit, as well as an increase in the efficiency of the device and the entire electric system supply of the electrostatic precipitator due to an increase in the power factor of the unit – electrostatic precipitator system, a decrease in the current form factor due to an increase in w of the working conductivity angle of the control valves at low levels of breakdown voltage, which leads to a decrease in energy losses in the units and networks, as well as a decrease in the installed power transformers of the power supply system. In addition, the reliability of the device is improved, in connection with which the operating costs of the object of use of the invention are reduced, and the cost of the device is reduced due to its simplification.

Claims (3)

1. Device dp power supply for electric 1 gas cleaning gasifier, containing power booster transformer, main unit of power semiconductor controllable gates, current limiting reactor, high voltage rectifier, current sensors and voltage on the electrostatic precipitator and automatic regulator, which includes 6 voltage torus on electrostatic precipitator, selector of spark and arc discharges, operating current limiting module, overshoot limiting module, amplitude-phase converter and main control pulse driver, characterized in that, in order to improve gas cleaning efficiency, efficiency of operation, increase reliability and simplify devices, the power step-up transformer is supplied with an additional winding with an additional block of power controlled valves connected in series with the main winding the automatic regulator is equipped with a buffer amplifier, a slope change module, an electronic switch and an additional driver for control pulses of an additional power controllable gates unit, the buffer amplifier being connected to the output of the voltage integrator and the output to the first input of the change module the slope and through a resistor to the input of the amplitude-phase converter, the output of which is connected to the second input of the module changing the slope and the first input of the electronic comm the output of the module, and the change in the slope of the module is connected to the second input of the electronic switch and the input of the amplitude-phase converter, the third and fourth inputs of the electronic switch are connected respectively to the information outputs of the main and auxiliary blocks of power control valves, and the first and second outputs of the electronic switch through the main and auxiliary control pulse drivers, respectively, with the inputs of the main and auxiliary blocks of power control gates. 2. The device according to claim 1, characterized in that the electronic switch is made in the form of two four-input logic elements And, the second, third and fourth inputs of which are combined in pairs and connected respectively with the first, third and fourth inputs of the electronic switch, inverter and two integrating Diode circuits and resistors connected in parallel. and a capacitor, with the inputs of the inverter and the second integrating circuit combined and connected to the second input of the unit, the output of the inverter through the first integrating circuit is connected to the first input of one logical element And, the output of the second integrating circuit to the first input of another logical eight And, and the outputs of the logic elements are the outputs of the block. 3. The device according to claim 1, characterized in that the block changing the slope is connected to the input of the amplitude-phase converter through a series-connected diode and a resistor. Editor L. Langazo Compiled by B. Kaklyugin Tehred A. Kravchuk Proofreader A. Ilyin Order 3754/7 Circulation 511 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4