RU2166999C1 - Method for automatic control of electric filter voltage according to breakdown (variants) - Google Patents

Abstract

FIELD: automatic control of high voltage rectifying units for energizing electric filter for gas scrubbing by rectified high-voltage electric current. SUBSTANCE: at operation of system " rectifying unit - electric filter" in modes with sharp change of technological parameters of scrubbed gas (dust content, humidity, temperature, specific electric resistance, fraction size of trapped dust and so on) breakdown level of voltage of sedimentation space of electric filter changes in wide range from 15 to 80 kV. In order to hold voltage of electric filter as maximum as possibly, automatic control system provides measuring of mean electric current value and amplitude of breakdown voltage and in depending upon said values it sets voltage drop degree and voltage increase rate after breakdown. High electric current of electric filter corresponds to high voltage drop after breakdown; low electric current value corresponds to low voltage drop. Small voltage amplitude before breakdown corresponds to high rate of voltage increase; high voltage amplitude - to low rate of voltage increase. EFFECT: enhanced degree of gas scrubbing by means of electric filter. 2 cl, 2 dwg

Description

 The invention relates to the field of electric cleaning of gases from dust and mists in various industries and agriculture and can be used in automatic control systems for high-voltage converting power units of electrostatic precipitators.

 A known method of automatically controlling the maximum average value of the operating voltage on the electrostatic precipitator, at which the angle of regulation of the thyristor switch increases to achieve a natural maximum average value of the operating voltage, limited either by the nominal parameters of the converter unit or the current-voltage characteristic of the electrostatic precipitator (the presence of a “reverse corona”, spark and arc breakdowns of the precipitation space, etc.) (see ed. certificate of the USSR N 355606, publ. 30.09.72).

 Closest to the technical nature of the present invention is a method of automatically controlling the voltage of the electrostatic precipitator by changing the angle of regulation of the thyristor switch depending on the magnitude of the operating voltage on the electrostatic precipitator, in which to prevent prolonged breakdowns (which leads to a decrease in the average value of the operating voltage and can lead to burnout by the electric arc of the corona electrodes and, as a consequence, to short circuit in the electrostatic precipitator) the method involves reducing voltage of 1.5 -2.0% after each breakdown and smooth its restoration to the breakdown level (see. auth. svid. USSR N 12821000, publ. 01.07.87. Bull. N 1).

 A significant disadvantage of this method is that the magnitude of the voltage reduction and the recovery rate after breakdown is set manually and with the breakdown level of the precipitation space of the electrostatic precipitator existing at the time of adjustment.

 It is known that the breakdown level of the precipitation space of the electrostatic precipitator varies over a wide range from 15 to 80 kV and depends on a number of parameters of the gas to be cleaned (dustiness, humidity, temperature, electrical resistivity of the captured dust, etc.).

 The change in gas parameters is associated with the instability of the operation of technological equipment (furnace, mill, boiler, etc.).

 Thus, the accuracy of adjusting the degree of decrease and the rate of voltage rise after breakdown depends on the experience of the installer and can be satisfactorily observed only in some narrow region of the current-voltage characteristic of the electrostatic precipitator existing at the time of commissioning. This leads to an unjustified decrease in the average voltage value at the filter electrodes and, as a result, to a deterioration in the degree of gas purification.

 The aim of the present invention is to improve the degree of gas purification by electrostatic precipitator by increasing the average voltage at the electrodes in modes with a sharp change in breakdown levels associated with the instability of technological processes.

 It has been analytically and experimentally established that in order to maintain the optimal level of the average voltage value on the electrostatic precipitator at low breakdown voltages, it is necessary to allow a significant number of breakdowns (100 or more breakdowns per minute), i.e. to allow a slight decrease in voltage after the breakdown and its rather rapid increase. This is due to the fact that at low breakdown levels, i.e., small control angles and, consequently, small load currents, breakdowns are of a spark nature and their transition to an arc discharge is unlikely.

 On the contrary, at high breakdown voltages, i.e. large control angles and large load currents, breakdowns, as a rule, are of an arc character. Therefore, the depth of voltage reduction after breakdown should be greater, and the rate of increase should be less. This ensures a minimum breakdown frequency and more stable operation of the conversion unit - electrostatic precipitator system, and therefore, the maximum voltage on the electrostatic precipitator and its most efficient operation.

 The technical result is achieved by the fact that in the method of automatically controlling the voltage of the electrostatic precipitator according to breakdowns, which consists in changing the angle of regulation of the thyristor or triac switch in the power circuit of the high-voltage converter power unit of the electrostatic precipitator by changing the depth of voltage reduction and its smooth recovery after each breakdown of the precipitation space, according to the invention, the value of the average value of the current of the electrostatic precipitator before the breakdown, and the depth of voltage reduction at depending on this value, a larger current value corresponds to a greater depth of voltage reduction on the electrostatic precipitator, a smaller current value corresponds to a lower depth of voltage reduction.

 Another difference of the proposed method of regulation is that they measure the value of the angle of regulation before the breakdown, and the rate of increase in voltage on the electrostatic precipitator after breakdown to the breakdown level is set depending on this value, a lower value of the angle of regulation corresponds to a higher rate of increase in voltage on the electrostatic precipitator, a larger value of the angle of regulation - less speed.

 The third difference of the proposed method of regulation is that they measure the magnitude of the amplitude value of the voltage on the electrostatic precipitator before the breakdown, and the rate of increase in voltage after the breakdown is set depending on this value, a lower voltage amplitude on the electrostatic precipitator corresponds to a higher voltage increase rate, a larger voltage amplitude value - a smaller voltage increase rate.

 A comparative analysis shows that the differences of the proposed method compared with the prototype are significant. This allows us to conclude that it meets the criterion of "inventive step".

 In FIG. 1 and FIG. 2 presents possible variants of block diagrams of a device for implementing the inventive method.

 The block diagram (Fig. 1) contains a thyristor switch 1, a current-limiting inductor 2, a high-voltage converter 3, an electrostatic precipitator 4, an electrostatic precipitator voltage sensor 5, an electrostatic precipitator current sensor 6, an electrostatic precipitator current integrator 7, an electrostatic precipitator breakdown selector 8, a charge current integrator 9 , phase shifting device 10, driver of 11 pulses of control of the thyristor key 1, controlled converter 12, the voltage of the electrostatic precipitator - charging current of the integrator 9, converter 13 angle of inclusion - voltage, converter 14 t ok electrostatic precipitator - pulse duration, generator 15 of the discharge current of the integrator 9, master 16 of the maximum depth of voltage reduction after breakdown, master 17 of the maximum rate of increase of voltage on the electrostatic precipitator after breakdown.

 The scheme works as follows. When applying voltage to the converter unit and the voltage regulator of the mains and performing the “Start” operation, control pulses from the driver 11 appear on thyristor key 1, the phase position of which is set by the phase shifting device 10. The initial control angle Φ has a minimum value. Thyristor key opens. A voltage appears on the electrostatic precipitator 4, the magnitude of which is slightly lower than the voltage at the onset of corona. The current of the electrostatic precipitator is absent.

 At the same time, the voltage of the electrostatic precipitator from the sensor 5 is supplied to the input of the selector 8 breakdowns in the electrostatic precipitator and the input 18 of the controlled transducer 12. At the input 19 of the controlled transducer 12 from the output of the transducer 13 a voltage is proportional to the switching angle set by the phase shifting device 10. At the time of starting, the voltage the output of the converter 12 is maximum, because the value of the angle of inclusion α = π-Φ (Φ is the angle of regulation) has the greatest value. The magnitude of the charging current at the output of the converter 12 (at the input 20 of the integrator 9) is also maximum and, therefore, the rate of increase in voltage on the electrostatic precipitator has the greatest value. The magnitude of the maximum speed can be adjusted by the dial 17.

 As the voltage at the integrator 9 increases, the control angle - Φ increases, and the switching angle - α decreases, therefore, the voltage at the input 19 of the converter 12 decreases, the value of the charging current at the input 20 of the integrator 9 also decreases. As a result, the rate of increase in voltage on the electrostatic precipitator decreases .

The process of accelerating the aggregate - electrostatic precipitator system occurs at a variable speed, i.e., a lower speed corresponds to a lower control angle, a lower speed corresponds to a larger angle, and continues until one of the following situations occurs:
1. The angle of regulation - Φ will reach its maximum value. The value of the inclusion angle α is equal to zero. The rate of increase in voltage is also zero, because the voltage on the electrostatic precipitator reaches its maximum value and the acceleration process stops.

 2. The value of the current of the electrostatic precipitator will reach the nominal current value of the converter unit.

 3. In the electrostatic precipitator, at a certain voltage level, breakdowns of the precipitation space will begin.

When the voltage on the electrostatic precipitator exceeds the voltage of the onset of coronation, a current will flow through the filter, the value of which will increase with increasing regulation angle Φ.
The instantaneous current value of the converter unit from the sensor 6 is fed to the input of the integrator 7, from the output of which a voltage proportional to the average current value is supplied to the input 21 of the converter 14, the current of the electrostatic precipitator is the pulse duration.

 When breakdowns occur in the sedimentation space of the filter, voltage pulses appear at the output of the selector 8, which are fed to the input 22 of the converter 14 and to the input 23 of the discharge current generator 15. At the same time, a voltage pulse is supplied to the input 24 of the generator 15 from the output of the converter 14, the duration of which is less than the pulse duration of the selector 8 and is determined by the average value of the current of the electrostatic precipitator. A larger current value corresponds to a longer duration, a smaller value corresponds to a shorter duration. The pulse from the output of the Converter 14 starts the generator 15 of the discharge current, the output signal of which is supplied to the input 25 of the integrator 9.

 As a result of this, the voltage value at the input of the phase shifter 10 decreases, the value of the control angle at the input of the driver 11 and at the control electrodes of the thyristor switch 1. This leads to a decrease in the voltage at the filter electrodes by a certain amount proportional to the average value of the current of the electrostatic precipitator. The maximum value of the depth of voltage reduction on the electrostatic precipitator is set by the setter 16.

 Thus, the depth of voltage reduction on the electrostatic precipitator depends on the average current value before breakdown, a larger voltage reduction depth corresponds to a larger current value, and a lower voltage reduction depth corresponds to a lower current value.

 The block diagram of FIG. 2 differs from the block diagram of FIG. 1 by the fact that the converter 13 is the angle of inclusion - the voltage is replaced by an amplitude detector 13 of the voltage on the electrostatic precipitator. Feedback was introduced not by the angle of inclusion - α, but by the magnitude of the amplitude value of the voltage on the electrostatic precipitator, i.e. the rate of increase in voltage on the electrostatic precipitator is set depending on the amplitude value of the voltage. A lower voltage value corresponds to a higher speed, a higher voltage value corresponds to a lower speed.

Such a substitution is legitimate because U _max = f (α).

 Laboratory and industrial tests of the proposed method were carried out and positive results were obtained.

Claims (2)

 1. A method for automatically controlling the voltage of an electrostatic precipitator by changing the angle of regulation of a thyristor or triac switch in the power circuit of a high-voltage converter for supplying an electrostatic precipitator by changing the depth of voltage reduction and its smooth recovery after each breakdown of the precipitation space, characterized in that the average value of the current of the electrostatic precipitator is measured before the breakdown and the depth of voltage reduction after breakdown is set depending on this value, more a larger current value corresponds to a greater depth of voltage reduction at the electrostatic precipitator, a smaller current value corresponds to a lower depth of voltage reduction, the magnitude of the angle of regulation before breakdown is measured and the rate of increase of voltage on the electrostatic precipitator after breakdown to a breakdown level is set depending on this value, a larger value of the angle of regulation corresponds to a larger the speed of increasing the voltage on the electrostatic precipitator, the greater the value of the angle of regulation is the lower speed.  2. A method of automatically adjusting the voltage of an electrostatic precipitator by changing the angle of regulation of a thyristor or triac switch in a power circuit of a high-voltage converter for supplying an electrostatic precipitator by changing the depth of voltage reduction and its smooth recovery after each breakdown of the precipitation space, characterized in that the average value of the current of the electrostatic precipitator is measured before the breakdown and the depth of voltage reduction after breakdown is set depending on this value, b A larger current value corresponds to a greater depth of voltage reduction on the electrostatic precipitator, a smaller current value - a smaller depth of voltage reduction, the magnitude of the amplitude value of the voltage on the electrostatic precipitator is measured before breakdown, and the rate of voltage increase after the breakdown is set depending on this value, a larger value of the voltage amplitude on the electrostatic precipitator corresponds to a large the rate of increase in voltage, a larger value of the amplitude of the voltage - a lower rate of increase in voltage.

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