RU2168368C1 - Method for automatic determination, selection and control of mode of electric power supply of filter - Google Patents

Abstract

FIELD: systems for automatic control of high-voltage aggregates for energizing electric filters for gas scrubbing. SUBSTANCE: method provides applying of rectified high-voltage electric current to electric filter when system " rectifying unit - electric filter" operates in conditions of sharp change of technological parameters of scrubbed gas. Filter electric operation mode determined by breakthrough voltage level of precipitation space and electric current value of filter changes in wide range. When reverse corona discharge occurs, electric current density of filter increases and voltages of its electrodes drop. In order to provide optimal gas scrubbing, at occurring reverse corona discharge when electric current density of electric filter becomes higher than critical value, electric filter is energized successively in equal time intervals T1 sufficient for achieving stable operation mode of filter by means of rectified electric current pulses with repetition frequency F= 2fc/2n+1. At each of said time intervals stable amplitude and mean voltage values of electric filter are measured for calculating their products, storing them and comparing product values corresponding to different repetition frequency of rectified electric current. Then energization mode with maximum product value of stable amplitude and mean voltage values is selected for operation of filter. Periodically in time intervals T2 processes for testing, determination and selection of new frequency mode of filter energization are automatically repeated. EFFECT: enhanced degree of gas scrubbing by means of filter operating in selected mode. 3 cl,1 dwg

Description

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

 Known methods for 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 by the current-voltage characteristic of the electrostatic precipitator — the presence of a reverse corona, spark and arc breakdowns of a precipitation space, etc. (see USSR author's certificate N 355606, publ. 09/30/1972).

 There is also a method of automatically controlling the voltage of an electrostatic precipitator by changing the angle of regulation of the thyristor switch, in which, in order to limit the current of the reverse corona, the regulation is carried out depending on the magnitude of the operating voltage on the electrostatic precipitator. An increase in voltage on the electrostatic precipitator corresponds to an increase in the angle of regulation, while a decrease in voltage corresponds to a decrease in the angle. Those. positive voltage feedback is provided. This makes it possible to stop the increase in current when the increase in voltage on the electrostatic precipitator stops (see USSR author's certificate N 12821000, publ. 01/07/1987. Bull. N 1).

 In order to reduce the reverse corona current and increase the degree of gas purification from dust, as well as reduce electric power consumption, power supply methods of rectified current electrostatic precipitators with a reduced pulse repetition rate are widely used in world practice. Such dietary regimes in the foreign literature are called "Semipuls" - half-pulse. And in the domestic - "periodically."

 The closest analogue of the invention is a method for automatically determining, selecting and adjusting the mode of electric power supply of a filter by measuring the current density of the electrostatic precipitator and changing the switching frequency and the angle of regulation of the key in the power circuit of the high-voltage converter power unit of the electrostatic precipitator (see RF patent N 2040975, publ. 11/18/1987 )

 A significant drawback of the above devices is that the pulse repetition rate of the rectified current, i.e. the change in the electric power supply mode of the filter is set manually with the existing technological mode of operation of the electrostatic precipitator existing at the time of the regulator settings.

 It is known that the presence and intensity of the reverse corona, the breakdown voltage level of the precipitation space of the electrostatic precipitator, depends on a number of parameters of the gas being cleaned (dustiness, humidity, temperature, electrical resistivity, dispersed composition of trapped dust, etc.).

 The change in gas parameters is associated with the heterogeneity of the fired or grinded raw materials, combusted fuel, with a deviation from the norm of the temperature regime of the technological equipment (furnace, mill, boiler, etc.).

 Thus, the setting of the pulse repetition rate of the rectified current pulses depends on the accuracy of the evaluation of the operation mode of the electrostatic precipitator (from the experience of the installer) and can be satisfactorily implemented only in a certain narrow region of the current-voltage characteristic of the electrostatic precipitator existing at the time of commissioning. This can lead 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 increase the efficiency of gas purification by an electrostatic precipitator by increasing the average voltage at the electrodes, reducing the energy consumption in the modes of spark and arc breakdowns, reverse corona and intermediate modes in conditions associated with the instability of technological processes.

It is known from the theory of electric gas purification that efficiency - the efficiency of an electrostatic precipitator is described by the following relationship:
η = 1-exp (-wf),
here W is the velocity of charged dust particles to the precipitation electrode,
f is the specific deposition surface.

W = kU _m U _cf
where k is the coefficient of proportionality,
U _m - the amplitude value of the voltage of the electrostatic precipitator,
U _cf - the average voltage of the electrostatic precipitator.

It follows that in order to maintain the efficiency of the electrostatic precipitator at an optimal level under various power supply conditions, the product U _m U _cf should always be the greatest.

When gases are cleaned from dust with high ρ - electrical resistivity, charges accumulate on the dust layer, which, due to low dust conductivity, slowly drain onto the metal surface of the precipitation electrode. A voltage drop is formed on the dust layer, the value of which depends on the thickness of the layer - b, specific electrical resistance of the dust - ρ, current density - j and is expressed by the dependence
U = bρj,
The electric field in the dust layer is determined by the expression
E = U / b = ρj.
At a sufficiently large dust resistance and at a current density exceeding a certain critical value, an electrical breakdown occurs in the air pores of the layer, accompanied by the release of positive charges into the precipitation space. This phenomenon is called the reverse corona of positive polarity. It is accompanied by a partial neutralization of the negative space charge, an increase in current, and a decrease in voltage.

 As a result, the unproductive energy consumption increases and the technological efficiency of the electrostatic precipitator deteriorates.

 Therefore, to achieve the optimum degree of gas purification from dust, in the event of the inverse corona, i.e. when the current density of the electrostatic precipitator increases above a certain critical value, it is necessary to change the mode of electric power supply of the filter — a change in the pulse repetition rate of the rectified current.

The technical result is achieved by the fact that in the method for automatically determining, selecting and regulating the mode of electric power supply of the filter, which consists in measuring the current density of the electrostatic precipitator and in changing the switching frequency and the angle of regulation of the key in the power circuit of the high-voltage converter unit for supplying the electrostatic precipitator, according to the invention, the current density of the electrostatic precipitator is measured in the modes of spark and arc breakdowns, reverse corona and intermediate modes, and when it reaches some critical of a quantity, sequentially, at equal time intervals T1, sufficient to achieve a steady state of operation of the electrostatic precipitator, the electrostatic precipitator is supplied with rectified current pulses with a repetition rate of F = 2f _s / 2n + 1, during each of these time periods the steady-state amplitude and average voltage values are measured on the electrostatic precipitator, their products are calculated and stored, then the values of these products are compared for different frequencies of the rectified current pulses and left to work the frequency power mode for which the product of the steady-state values of the amplitude and average voltages is the largest.

F is the pulse repetition rate of the rectified current,
f _with - the frequency of the supply network,
n is the natural series of numbers 0, 1, 2, 3, ...

 Another difference of the proposed control method is that if for some time periods the products of the amplitude and average voltage values at different pulse repetition rates of the rectified current are equal, then the power mode for which the pulse repetition rate of the rectified current is the lowest is left in operation.

 The third difference of the proposed method of regulation is that control measurements, calculation of the products of the amplitude and average values of voltages and their comparison are made periodically at equal intervals of time T2 significantly greater than T1 and only when the current density of the electrostatic precipitator exceeds a certain critical value.

 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".

 The drawing shows one of the possible variants of a block diagram of a device for implementing the inventive method.

The block diagram (drawing) contains a thyristor switch 1, a current-limiting reactor 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 voltage detector 8, an electrostatic precipitator voltage integrator 9, phase shifter 10, controlled frequency divider 11, thyristor switch 1 pulse control pulse generator 12, comparator 13, critical current density adjuster 14, analog multiplier 15, commutator OR 16, computer device 17, a memory 18, multiplying U results _m U _cf. for frequency mode 2f _s, the storage device 19 of the results of multiplying U _m U _cf. for frequency mode 2f _c / 3, the memory 20 results multiplying U _m U _cf. for frequency 2f _s / 5 mode, arithmetic device 21, programmable switch 22.

 The scheme works as follows.

When applying voltage to the converter unit and the voltage regulator of the mains and performing the “Start” operation, the control pulses from the driver 12 appear on the thyristor key 1, the phase position of which is set by the phase shifting device 10, and the repetition rate is 2f _{with a} controlled frequency divider 11. The initial control angle is 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 amplitude detector 8 and integrator 9. From the output 23 of the integrator 9, a voltage proportional to the voltage of the electrostatic precipitator is supplied to the input of the phase-shifting device 10. This initiates the process of acceleration of the conversion unit-electrostatic precipitator system. The voltage on the filter begins to gradually increase.

 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 angle of regulation 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 27 of the comparator 13. From the output of the setter 14, the signal 28 determines the critical current density of the electrostatic precipitator to the input 28 of the comparator 13. The inputs 25 and 26 of the analog multiplier 15 are fed signals proportional to the average and amplitude values of the voltage of the electrostatic precipitator, respectively. From the output of the analog multiplier 15 to the input 29 of the switch 16 a signal is proportional to the product U _m U _cf. When the current density of the electrostatic precipitator exceeds a predetermined critical value, a signal starts the program at the input 30 of the switch 16 and the input 31 of the software device 17.

The program works as follows. For equal time intervals - T1, in series, the converter unit is switched on for frequency modes - 2f _s , 2f _s / 3, 2f _s / 5. During these time periods, U _m and U _s are measured, their products are calculated and the measurement results are recorded in the corresponding memory devices - 18, 19, 20. Then, signals proportional to the products U _m U _cf are supplied to the arithmetic device 21, where the highest value is calculated from these works. By means of the switch 22 and the controlled frequency divider 11, such a frequency mode of operation of the converter unit is set that corresponds to the highest value of the product U _m U _cf and the current density of the electrostatic precipitator is less than the critical value set in accordance with the size of the electrostatic precipitator, setter 14.

 The duration of the work cycle - T2 is set by the program and can vary within wide limits.

After the working cycle, the process of measuring U _m and U _cf for various frequency modes of the converter unit, calculating their products, memorizing and searching for the highest value of the product U _m U _cf - is repeated.

In the case when the products U _m U _cf for different frequency modes are equal, the power supply mode of the electrostatic precipitator remains in operation for which the pulse repetition rate of the rectified current is the smallest.

Measurement operations U _m and U _cf for various frequency operating modes of the converter unit, calculation of their products, memorization, search for the highest value of the product U _m U _cf and selection of the operating mode are performed only when the operating current density of the electrostatic precipitator exceeds a predetermined critical value.

Claims (3)

1. The method of automatic determination, selection and regulation of the electric power supply mode of the filter by measuring the current density of the electrostatic precipitator and changing the switching frequency and the angle of regulation of the key in the power circuit of the high-voltage converting power unit of the electrostatic precipitator, characterized in that the current density of the electrostatic precipitator is measured in spark and arc breakdown modes , reverse corona and intermediate modes, and when it reaches a certain critical value, sequentially, at equal intervals of time audio T1 sufficient to achieve steady-state operation of the electrostatic precipitator is set power electrostatic pulses rectified current repetition frequency F = 2f _c / 2n + 1, for each of the time intervals measured steady-state amplitude and average values of voltages on electrostatic compute their product and memorize , then the values of these products are compared for different repetition rates of the rectified current pulses and in the work they leave that frequency power mode for which the product the values of the amplitude and average voltages that are set are the largest.  2. The method according to claim 1, characterized in that if for some time intervals the products of the amplitude and average voltage values at different pulse repetition rates of the rectified current are equal, then the power mode for which the repetition rate of the rectified current pulses is left in operation - the smallest.  3. The method according to claim 1, characterized in that the control measurements, the calculation of the products of the amplitude and average voltage values and their comparison are periodically made at equal intervals of time T2 significantly greater than T1 and only when the current density of the electrostatic precipitator exceeds a certain critical value.

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