KR101672583B1 - Micro Pulse System, Method for Controlling The Same, Electrostatic Precipitator Including The Same - Google Patents

Abstract

A micropulse system of independent control type according to one aspect of the present invention, which is independently provided with a DC voltage source for generating and outputting a DC high voltage and a pulse voltage source for generating and outputting a pulse voltage, includes a DC voltage source for generating and outputting a DC high voltage; A pulse voltage source for generating and outputting a pulse voltage; And when the first control mode is selected, the DC voltage source is operated, the operation of the pulse voltage source is stopped to output the DC high voltage, and when the second control mode is selected, the DC voltage source and the pulse voltage source are operated, And a control unit for outputting the pulse voltage.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a micropulse system of independent control type, a control method of a micropulse system, and an electrostatic precipitator including a micropulse system (Micropulse System, Method for Controlling the Same, Electrostatic Precipitator Including the Same)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric dust collector, and more particularly, to a control of an electric dust collector.

BACKGROUND ART A micro pulse system (MPS) is a device for generating a pulse having a short width in microseconds (μs), and is applied to an environmental facility such as an electric dust collector or a deodorization system.

When the micropulse system is applied to an electrostatic precipitator, the micropulse system applies a pulse voltage to the discharge electrode to generate a corona discharge through the discharge electrode, thereby discharging the negative ions into the air. As a result, Energize the dust by surrounding the dust.

In the micropulse system, the direct current voltage is applied to the dust collecting plate to move the ionized dust to the dust collecting plate, so that the negative ions return to the power source through the dust collecting plate. The dust which lost the negative ions can not stay in the dust collecting plate, Not shown).

Hereinafter, a configuration of a micro-pulse system according to the prior art will be schematically described with reference to FIG.

FIG. 1 is a block diagram schematically showing a configuration of a micro-pulse system according to the related art.

1, a conventional micropulse system 100 includes a voltage regulator 110, a voltage booster 120, a rectifier 130, a charge capacitor 140, and a switching unit 140, .

The voltage regulator 110 is composed of at least one thyristor and plays a role of varying an AC voltage input from an external commercial power supply 160. [

The boosting unit 120 boosts the three-phase AC voltage supplied from the voltage regulator 110. That is, the voltage step-up unit 120 boosts the voltage of several hundreds V supplied from the voltage regulator 110 to a voltage of several tens KV.

The rectifying unit 130 is composed of a diode and performs full-wave rectification of the alternating-current voltage boosted by the voltage-boosting unit 120 to convert it into a direct-current voltage. In one embodiment, the rectifying unit 130 performs full-wave rectification of the AC voltage boosted by the voltage-up unit 120 and converts it into a negative DC voltage.

The charging capacitor 140 performs charging using a negative DC voltage supplied through the rectifying unit 130.

The switching device 150 supplies the negative DC voltage supplied through the rectifying part 130 to the discharge electrode through the resistor R and is charged to the charging capacitor 160 through the ON / OFF operation of the switch SW The voltage is supplied to the dust collecting board in the form of a pulse voltage.

The conventional micro-pulse system 100 as shown in FIG. 1 charges the charging capacitor 140 using the DC voltage generated by the voltage regulator 110 and charges the charging capacitor 140 The pulse voltage is dependent on the DC voltage generated by the voltage regulator 110, so that the control variability against the pulse voltage is lowered.

That is, in the micropulse system 100 according to the prior art, the rising and falling of the pulse voltage can only be performed in the same manner as the rising and falling of the DC voltage generated by the voltage regulator 110, There is a problem that it is not possible to appropriately cope with the case where control of either the pulse voltage or the DC voltage is required.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a micropulse system of independent control type independently provided with a DC voltage source for generating and outputting a DC high voltage and a pulse voltage source for generating and outputting a pulse voltage, And an electrostatic precipitator including a micro-pulse system.

It is another object of the present invention to provide an independent control type micro-pulse system capable of independently controlling a DC high voltage and a pulse voltage, a control method of a micro-pulse system, and an electrostatic precipitator including a micro- do.

In addition, the present invention includes a micro-pulse system of independent control type capable of adaptively controlling a DC voltage and a pulse voltage in response to the occurrence of a flashover when a spark occurs, a control method of the micro-pulse system, Another object of the present invention is to provide an electric dust collecting apparatus.

According to an aspect of the present invention, there is provided an independent control type micro-pulse system including: a DC voltage source for generating and outputting a DC high voltage; A pulse voltage source for generating and outputting a pulse voltage; And when the first control mode is selected, the DC voltage source is operated, the operation of the pulse voltage source is stopped to output the DC high voltage, and when the second control mode is selected, the DC voltage source and the pulse voltage source are operated, And a control unit for outputting the pulse voltage.

According to another aspect of the present invention, there is provided an electrostatic precipitator including: a micro-pulse system for outputting at least one of a DC high voltage and a pulse voltage according to a selected control mode; And a dust collector operative in accordance with at least one of a DC high voltage and a pulse voltage output from the micropulse system to remove dust contained in the exhaust gas, wherein the micropulse system generates a DC high voltage A direct current voltage source for applying the direct current high voltage to the discharge electrode; A pulse voltage source for generating a pulse voltage and applying the pulse voltage to the discharge electrode; And a second control mode for normal operation of the dust collector, wherein when the first control mode for the initial operation or test operation of the dust collector is selected, the DC voltage source is operated and the operation of the pulse voltage source is stopped to output the DC high voltage, The controller controls the DC voltage source and the pulse voltage source to output the DC high voltage and the pulse voltage.

According to another aspect of the present invention, there is provided a method of operating a micro-pulse system of independent control type, the method including operating a DC voltage source generating and outputting a DC high voltage and a pulse voltage source generating and outputting a pulse voltage, A method of operating a pulse system, comprising: selecting a control mode; And when the first control mode is selected, the DC voltage source is operated and the operation of the pulse voltage source is stopped to output the DC high voltage, and when the second control mode is selected, the DC voltage source and the pulse voltage source are operated, And outputting the pulse voltage.

According to the present invention, since the DC voltage source for generating and outputting the DC high voltage and the pulse voltage source for generating and outputting the pulse voltage are independently provided, there is an effect that the DC high voltage and the pulse voltage can be independently controlled.

In addition, according to the present invention, since the DC high voltage and the pulse voltage can be independently controlled, the micropulse system can be adaptively operated according to the environment in which the micropulse system is applied. Accordingly, the micropulse system is applied to the electrostatic precipitator There is an effect that the dust collecting efficiency of the electric dust collector can be maximized.

In addition, according to the present invention, it is possible to actively cope with the occurrence of flashover by variably controlling the DC high voltage and the pulse voltage according to the cause of the flashover when the flashover occurs, and to minimize the deterioration of the dust collection efficiency of the electric dust collector .

1 is a block diagram showing the configuration of a micro-pulse system according to the prior art;
2 is a block diagram schematically illustrating a configuration of a micro-pulse system according to an embodiment of the present invention.
FIG. 3 is a schematic view showing a configuration of an electrostatic precipitator to which the micro-pulse system shown in FIG. 2 is applied.
4 is a flowchart illustrating a method of operating a micro-pulse system of independent control type according to an embodiment of the present invention.

The meaning of the terms described herein should be understood as follows.

The word " first, "" second," and the like, used to distinguish one element from another, are to be understood to include plural representations unless the context clearly dictates otherwise. The scope of the right should not be limited by these terms.

It should be understood that the terms "comprises" or "having" does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

It should be understood that the term "at least one" includes all possible combinations from one or more related items. For example, the meaning of "at least one of the first item, the second item and the third item" means not only the first item, the second item or the third item, but also the second item and the second item among the first item, Means any combination of items that can be presented from more than one.

Hereinafter, the same components will be denoted by the same reference numerals for convenience of description.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Independent control type micro-pulse system

2 is a block diagram schematically illustrating the configuration of a micro-pulse system of independent control type according to an embodiment of the present invention.

2, an independent control type micro pulse system (MPS) 200 (hereinafter referred to as a 'micro pulse system') according to an embodiment of the present invention is a micro pulse system A DC voltage source 210, a pulse voltage source 220 for outputting a pulse voltage, and a controller 230 for controlling the DC voltage source 210 and the pulse voltage source 220.

That is, as shown in FIG. 2, the micro-pulse system 200 of the independent control type according to the present invention separates a DC voltage source 210 for outputting a DC high voltage and a pulse voltage source 220 for outputting a pulse voltage By independently configuring, the DC high voltage and the pulse voltage can be independently controlled.

Hereinafter, the configurations of the DC voltage source 210, the pulse voltage source 220, and the controller 230 will be described more specifically.

2, the DC voltage source 210 includes a first voltage regulator 212a, a first voltage regulator 212b, and a first rectifier 212c. The DC voltage source 210 generates a direct current high voltage, And a first DC voltage generating unit 212.

First, the first voltage regulator 212a is composed of at least one thyristor and plays a role of varying an AC voltage inputted from an external commercial power supply 240. [

The first boosting unit 212b boosts the three-phase AC voltage supplied from the first voltage regulator 212a. That is, the first boosting unit 212b boosts the voltage of several hundreds of V supplied from the first voltage regulator 212a to a voltage of several tens of KV.

The first rectification part 212c is composed of a diode and performs full wave rectification of the alternating voltage stepped up by the first step-up part 212b to convert it into a direct current voltage. In one embodiment, the first rectification section 212c performs full-wave rectification of the alternating-current voltage boosted by the first boosting section 212b and converts it into a negative (-) direct-current voltage.

In the present invention, the first rectification section 212c converts the AC voltage into a negative DC voltage by applying a DC voltage to the load L (e.g., a discharge electrode in the case of an electric dust collector) to which the micropulse system 200 is applied And generates a discharge in the load L by supplying a negative DC voltage.

Next, the pulse voltage source 220 generates and outputs a pulse voltage, and includes a second DC voltage generating unit 222, a charging capacitor 224, and a switching unit 226 as shown in FIG. 2 .

First, the second direct-current voltage generator 222 generates a positive direct-current voltage for generation of the pulse voltage to be output to the load L and supplies it to the charge capacitor 224. The second DC voltage generating unit 222 includes a second voltage regulator 222a, a second voltage regulator 222b, and a second rectifier 222c as shown in FIG.

The second voltage regulator 222a is composed of at least one thyristor and serves to vary an AC voltage input from an external commercial power supply 240. [

The second boosting unit 222b boosts the three-phase AC voltage supplied from the second voltage regulator 222a. That is, the second boosting unit 222b boosts the voltage of several hundred V supplied from the second voltage regulator 222a to a voltage of several tens KV.

The second rectifying part 222c is a diode and performs full-wave rectification of the alternating voltage stepped up by the second step-up part 222b to convert it into a direct current voltage. In one embodiment, the second rectifying section 222c performs full-wave rectification of the alternating voltage boosted by the second boosting section 222b to convert it into a positive DC voltage.

In the present invention, the second rectification part 222c converts the AC voltage into a positive DC voltage by supplying a positive DC voltage to the charging capacitor 224, For example, a discharge electrode of the electric dust collector). That is, the second rectifying unit 222c generates and outputs a positive pulse voltage, but generates a negative pulse voltage when applying the discharge electrode of the electric dust collector to the reference potential, and applies the positive pulse voltage to the discharge electrode.

The charging capacitor 224 is connected to the first DC voltage generating unit 210 at one end and connected to the second DC voltage generating unit 222 at the other end thereof to be supplied from the first DC voltage generating unit 210 And the positive direct current voltage supplied from the second direct current voltage generator 222 is used for charging. Further, the charge capacitor 224 outputs the charged voltage to the load so that the pulse voltage is applied to the load L.

The switching element 226 is connected to the terminal of the charging capacitor 224 connected to the second direct current voltage generator 222 and the voltage charged in the charging capacitor 224 is in the form of a pulse voltage having a predetermined pulse frequency So that the load L is discharged. That is, the switching element 226 allows the voltage charged in the charging capacitor 224 to be applied to the load L in the form of a pulse voltage through on / off operation under the control of the controller 230.

Next, the controller 230 selects a control mode according to the state of the load L to which the micropulse system 200 is applied, and controls the operations of the DC voltage source 210 and the pulse voltage source 220 according to the selected control mode. do.

In one embodiment, when the micropulse system 200 is applied to an electrostatic precipitator, the controller 230 selects a first control mode when an initial operation or a test operation of the electrostatic precipitator is required, 200) according to the first control mode. In addition, the control unit 230 can operate the micro-pulse system 200 according to the second control mode by selecting the second control mode when the normal operation of the electric dust collector is required. The control unit 230 may operate the micropulse system 200 according to the third control mode by selecting the third control mode when an abnormality such as a spark occurs in the electric dust collector.

Hereinafter, the operation of the control unit 230 will be described for each control mode selected by the control unit 230. FIG.

When the control unit 230 selects the first control mode, the control unit 230 operates the DC voltage source 210 and stops the operation of the pulse voltage source 220 so that only the DC high voltage is outputted to the load L do.

The controller 230 controls the pulse voltage source 220 by setting the gating signal applied to the second voltage regulator 222a included in the pulse voltage source 220 to zero for operation of the pulse voltage source 220. [ Can be stopped.

The control unit 230 periodically monitors the DC high voltage being output to the load L by the DC voltage source 210 in controlling the operation of the DC voltage source 210 to output the DC high voltage, When it is determined that the DC high voltage output to the load L is not the same as the preset first target value, the DC high voltage output to the load L is controlled by adjusting the input voltage input to the DC voltage source 210 Let 1 target value follow.

The controller 230 controls the phase of the AC voltage input to the DC voltage source 210 when the DC high voltage output to the load L is not equal to a preset first target value, So that the direct current high voltage output to the load L becomes the first target value.

Next, when the control unit 230 selects the second control mode, the controller 230 operates both the DC voltage source 210 and the pulse voltage source 220 to simultaneously apply the DC high voltage and the pulse voltage to the load L .

In this case, the control unit 230 periodically monitors the charging voltage of the charging capacitor 224 included in the pulse voltage source 220 so that the desired DC high voltage and the pulse voltage are applied to the load L. The control unit 230 controls the charging voltage of the charging capacitor 224 by controlling the input voltage input to the pulse voltage source 220. When the charging voltage of the charging capacitor 224 is not equal to the predetermined second target value, To follow the second target value.

When the charging voltage of the charging capacitor 224 is not equal to the preset second target value, the control unit 230 adjusts the phase of the AC voltage input to the pulse voltage source 220 so that the charging voltage of the charging capacitor 224 So that the charging voltage becomes the second target value.

The control unit 230 periodically monitors the DC high voltage and the pulse voltage being applied to the load L when it is determined that the charging voltage of the charging capacitor 224 is equal to the second target value. If it is determined that the sum of the DC high voltage and the pulse voltage applied as the monitoring result load L is not the same as the preset third target value, the controller 230 controls the input voltage inputted to the DC voltage source 210 The sum of the DC high voltage applied to the load L and the pulse voltage is controlled to follow the third target value by controlling the input voltage inputted to the pulse voltage source 220. [

Meanwhile, the controller 230 monitors the occurrence of the flashover, and when it is determined that the flashover has occurred, the controller 230 selects the third control mode and operates the micropulse system 200 according to the third control mode, thereby eliminating the flashover.

At this time, the flashover may occur due to a physical problem in the load (L). For example, when the load L is an electric dust collector, it may be caused by an abnormality of the exhaust gas, the input of foreign matter into the electric dust collector, stagnation of dust, or the like.

This third control mode is a necessary control mode for protecting the micropulse system 200 until the flash lock is canceled when flashover occurs.

In one embodiment, the controller 230 monitors the current and voltage output to the load L, and when the voltage output to the load L accompanies the rise of the current output to the load L toward the reference potential It can be judged that a flashover occurred.

At this time, the micropulse system 200 according to the present invention simultaneously applies the DC high voltage and the pulse voltage to the load L, so that the controller 230 determines whether the flashlock is generated by the DC high voltage and the pulse voltage Should be judged.

To this end, when the third control mode is selected, the control unit 230 first determines the cause of flashover. In one embodiment, the control unit 230 can determine the cause of the flashover by comparing the time at which the flashlight is generated and the timing at which the switching unit 226 for generating the pulse voltage is turned on.

According to this embodiment, the control unit 230 determines that a flashover has occurred due to the DC high voltage applied to the load L when the timing at which the flashover occurred and the ON timing of the switching unit 226 are not the same do.

The control unit 230 determines that the flashover occurs due to the pulse voltage applied to the load L when the flashing time is equal to the on time of the switching unit 226. [

If it is determined that the flashing has occurred due to the DC high voltage because the timing at which the flashing occurred and the ON timing of the switching unit 226 are not the same, the controller 230 stops the operation of the pulse voltage source 220 And controls the operation of the DC voltage source 210 so that the DC high voltage output by the DC voltage source 210 is reduced by a predetermined value.

At this time, the operation stop of the pulse voltage source 220 can be performed by setting the gating signal applied to the second voltage regulator 222a included in the pulse voltage source 220 to zero, and the reduction of the DC high voltage can be performed by the above- Lt; RTI ID = 0.0 > 1 < / RTI > target mode in which the DC high voltage must follow in one control mode. Thereafter, when the flash lock is canceled, the controller 230 returns the first target value to the original value and re-operates the pulse voltage source 220 to operate the micro-pulse system 200 normally.

On the other hand, if it is determined that the flashing occurred due to the same timing of the occurrence of the flashing and the ON timing of the switching unit 226, the control unit 230 stops the operation of the pulse voltage source 220 So that the pulse voltage is not applied to the load (L). Therefore, only the DC high voltage output by the DC voltage source 210 is applied to the load L. Thereafter, when the flash memory is removed, the controller 230 operates the micropulse system 200 by operating the pulse voltage source 220 again.

2, the micro-pulse system 200 according to the present invention includes a first reactor 242, a second reactor 245, a third reactor 250, and a fourth reactor 260, . ≪ / RTI >

The first reactor 242 is connected between the first DC voltage generating unit 212 and one end of the charging capacitor 224 and the second reactor 245 is connected between the second DC voltage generating unit 222 and the charging capacitor 224 As shown in Fig. The first reactor 242 and the second reactor 245 are wound together to generate a negative DC voltage applied to one end of the charging capacitor 224 by the first DC voltage generating unit 212, And a positive DC voltage applied to the other end of the charging capacitor 224 by the capacitor 222.

The third reactor 250 is connected between an output terminal connected to the load L and one end of the charge capacitor 224 so that the spark is generated in the load L. When the spark is generated in the load L, And the second direct-current voltage generating unit 222, respectively.

The fourth reactor 260 is connected between the switching element 226 and the other end of the charging capacitor 224 to control the form of the pulse when the charging voltage stored in the charging capacitor 224 is output as a pulse voltage. That is, the fourth reactor 260 determines the pulse shape of the pulse voltage applied to the load L through adjustment of the reactance value.

As described above, the micropulse system 200 according to the present invention independently includes the DC voltage source 210 and the pulse voltage source 220 so that the pulse voltage is not dependent on the DC voltage source 210, The micropulse system 200 can be operated adaptively according to the environment to which the micropulse system 200 is applied.

Particularly, when the micropulse system 200 is applied to the electrostatic precipitator, the micropulse system 200 can be controlled in various ways according to the state of the electrostatic precipitator, thereby maximizing the dust collecting efficiency of the electrostatic precipitator.

In addition, the micro-pulse system 200 according to the present invention can actively cope with the occurrence of flashover by variably controlling the DC high voltage and the pulse voltage according to the cause of the flashover when the flash is generated, It is possible to minimize the deterioration of the dust collection efficiency of the electric dust collector due to flashover when applied to the electric dust collector.

Hereinafter, the configuration of the electrostatic precipitator to which the micro-pulse system 200 as described above with reference to FIG. 3 is applied will be briefly described.

FIG. 3 is a schematic view illustrating a configuration of an electrostatic precipitator to which a micropulse system according to an embodiment of the present invention is applied.

3, the electrostatic precipitator 400 includes a dust collector main body 410, a micropulse system 200, a chattering device 420, and a transfer device 440. As shown in FIG.

The dust collector main body 410 (hereinafter, referred to as a 'main body') is a space in which electric dust collection is performed to collect dust contained in the flue gas, and includes an inlet 412 through which the flue gas flows, a dust collecting space 414, and an outlet 416 through which exhaust gas is discharged.

Although not shown, the dust collecting space 414 in which the dust contained in the exhaust gas is collected may be constituted by a plurality of dust collecting chambers. According to this embodiment, each of the dust collecting chambers is provided with a plurality of discharge electrodes (not shown) for charging the dust to the cathode, and a dust collecting plate (not shown) charged to the anode and collecting the dust, The micropulse system 200 is installed to apply at least one of high voltage and pulse voltage.

When a DC high voltage and a pulse voltage are applied by the micropulse system 200, the discharge electrode generates negative ions through ionization by corona discharge, and may be formed in the form of a wire or a rigid body. The anions generated in the discharge electrode flow into the airflow to collide with the particles, thereby charging the dust with anions. The dust particles charged by the anion are moved to the dust collecting plate.

The dust collecting plate is charged with an anode to adsorb dust particles charged with anion. In one embodiment, the collection plate may be plate-shaped.

The micropulse system 200 allows electrical dust collection through a discharge in the main body 410 by applying at least one of a direct current high voltage and a pulse voltage to the main body 410. Since the structure of the micropulse system 200 has been described in detail with reference to FIG. 2, a detailed description thereof will be omitted.

Next, the chattering device 420 separates the dust attached to the dust collecting plate included in the main body 410 from the dust collecting plate through the chatter. That is, the chattering device 420 applies a mechanical force to the dust collecting plate to drop, lower, and discharge the dust attached to the dust collecting plate. The chattering unit 420 can improve the chatter efficiency by controlling the chatter strength or the chatter frequency.

The transfer device 430 serves to transfer the dust separated from the dust collecting plate to the storage (not shown) by the chattering device 420. In one embodiment, the transfer device 420 is moved according to a predetermined transfer rate to transfer the dust to the reservoir.

As described above, by applying the micropulse system 200 according to the present invention to the electrostatic precipitator 400, a basic electric field between the discharge electrode and the dust collecting plate is formed and maintained by using the DC high voltage applied to the main body 410 It is possible to form a moving electric field of the charged dust and to prevent re-scattering of dust collected on the dust collecting plate. In addition, the floating dust is charged through the pulse voltage applied to the main body 410 to have electrical polarity, so that the floating dust moves to the dust collecting plate through the moving electric field. As a result, dust collection can be stably maintained as a whole.

Operation method of independent control type micro pulse system

Hereinafter, an operation method of the independent control type micro-pulse system according to the present invention will be described with reference to FIG.

4 is a flowchart illustrating a method of operating a micro-pulse system of independent control type according to an embodiment of the present invention. The operation method shown in FIG. 4 may be performed by a control unit of a micropulse system having a configuration as shown in FIG.

First, the control unit selects one of the first and second control modes (S500). In one embodiment, the control mode may be selected according to the state of the load to which the micropulse system is applied.

For example, when the micropulse system is applied to the electrostatic precipitator, the controller operates the micropulse system according to the first control mode by selecting the first control mode when the initial operation or the test operation of the electrostatic precipitator is required. In addition, the control unit operates the micro-pulse system according to the second control mode by selecting the second control mode when the normal operation of the electrostatic precipitator is required.

Thereafter, when the first control mode is selected, the controller operates the DC voltage source included in the micropulse system and stops the operation of the pulse voltage source so that only the DC high voltage is output to the load (S510).

In one embodiment, the control unit monitors whether the DC high voltage output to the load by the DC voltage source is equal to the first target value, in order to control the DC voltage source and output the desired DC high voltage to the load. As a result of the monitoring, if the DC high voltage output to the load is different from the first target value, the controller controls the phase of the AC voltage input to the DC voltage source so that the DC high voltage follows the first target value.

Meanwhile, when the second control mode is selected, the controller operates both the DC voltage source and the pulse voltage source to simultaneously output the DC high voltage and the pulse voltage to the load (S520).

In one embodiment, in order to control the DC voltage source and the pulse voltage source to output the desired DC high voltage and the pulse voltage to the load, the controller first determines whether the charge voltage of the charge capacitor included in the pulse voltage source is equal to the second target value Monitoring. If the charging voltage of the charging capacitor is different from the second target value as a result of the monitoring, the controller controls the phase of the AC voltage input to the pulse voltage source so that the charging voltage follows the second target value.

Thereafter, when the charge voltage of the charge capacitor becomes equal to the second target value, the control unit monitors whether the sum of the DC high voltage and the pulse voltage being outputted to the load is equal to a predetermined third target value. If the sum of the DC high voltage and the pulse voltage is different from the third target value, the controller controls at least one of the phase of the AC voltage input to the DC voltage source and the phase of the AC voltage input to the pulse voltage source, So that the sum of the voltages follows the third target value.

Thereafter, the controller monitors whether a spark occurs during the normal operation according to the second control mode (S530). Here, the flashover can be caused by a physical problem in the load L. [ For example, when the load L is an electric dust collector, it may be caused by an abnormality of the exhaust gas, the input of foreign matter into the electric dust collector, stagnation of dust, or the like.

In one embodiment, the control unit monitors the current and voltage output to the load L, and when the voltage output to the load L decreases in association with the rise of the current output to the load L toward the reference potential It can be judged that an island lock has occurred.

If it is determined in step S530 that a flashover has occurred, the controller determines the cause of the flashover (S540). In the case of the micropulse system according to the present invention, the control unit determines the cause of the flashover because it simultaneously applies the DC high voltage and the pulse voltage to the load L and thus determines whether the flashover is caused by the DC high voltage or the pulse voltage To confirm.

In one embodiment, the controller may determine the cause of the flashover by comparing the time at which the flashlight is generated and the timing at which the switching unit for generating the pulse voltage is turned on.

According to this embodiment, if the flashover occurrence time point and the switching unit turn-on time for generating the pulse voltage are not the same, it is determined that the flashover occurred due to the DC high voltage, and the flashover occurrence time and the switching unit for generating the pulse voltage are turned on If the timings are the same, it is determined that a flashover has occurred due to the pulse voltage.

If it is determined in step S540 that the flashover has occurred due to the DC high voltage, the controller stops operation of the pulse voltage source and controls operation of the DC voltage source so that the DC high voltage is reduced by a predetermined value in operation S550.

Thereafter, when the flash lock is eliminated, the control unit recovers the DC high voltage to its original value and re-operates the pulse voltage source (S560), and returns to S520 to operate the micropulse system normally according to the second control mode.

If it is determined in step S540 that the flashing has occurred due to the pulse voltage, operation of the pulse voltage source is stopped to apply only the DC high voltage to the load (S570).

Thereafter, when the flash lock is eliminated, the control unit re-operates the pulse voltage source (S580). The micro-pulse system returns to S520 to operate normally according to the second control mode.

The control method of the electric dust collecting apparatus may be implemented in a form of a program that can be executed using various computer means. The program for performing the control method of the electric dust collecting apparatus may be a hard disk, a CD-ROM, a DVD, Readable recording medium such as ROM, RAM, or flash memory.

Those skilled in the art will appreciate that the invention described above may be embodied in other specific forms without departing from the spirit or essential characteristics thereof.

It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

200: Micro-pulse system 210: DC voltage source
220: Pulse voltage source 230:
400: electric dust collector 410: dust collector main body
420: chattering device 430: conveying device

Claims (15)

A DC voltage source for generating and outputting a DC high voltage;
A pulse voltage source for generating and outputting a pulse voltage; And
When the first control mode is selected, the DC voltage source is operated and the operation of the pulse voltage source is stopped to output the DC high voltage. When the second control mode is selected, the DC voltage source and the pulse voltage source are operated, And a control unit for causing the pulse voltage to be output,
Wherein the control unit selects a third control mode when a spark occurs and controls the operation of the DC voltage source and the pulse voltage source according to a cause of flashover. The method according to claim 1,
Wherein,
Wherein the control unit determines the cause of flashover by comparing the flashover point of time with the timing of turning on the switching unit for generating the pulse voltage according to the third control mode. 3. The method of claim 2,
Wherein,
When the flashover occurrence time point and the switching unit turn-on time for generating the pulse voltage are not the same, it is determined that the flashover has occurred due to the DC high voltage, and the operation of the pulse voltage source is stopped and the DC high voltage is reduced by a predetermined value And the operation of the voltage source is controlled. 3. The method of claim 2,
Wherein,
Wherein the control unit determines that a flashover has occurred due to the pulse voltage and stops the operation of the pulse voltage source when the flashover occurrence time point and the switching unit turn-on time for generating the pulse voltage are the same. The method according to claim 1,
The control unit, when selecting the first control mode,
Wherein the controller monitors whether the DC high voltage output by the DC voltage source is equal to the first target value and controls the phase of the AC voltage input to the DC voltage source when the DC high voltage is different from the first target value, So as to follow the first target value. A DC voltage source for generating and outputting a DC high voltage;
A pulse voltage source for generating and outputting a pulse voltage; And
When the first control mode is selected, the DC voltage source is operated and the operation of the pulse voltage source is stopped to output the DC high voltage. When the second control mode is selected, the DC voltage source and the pulse voltage source are operated, And a control unit for causing the pulse voltage to be output,
The control unit, when selecting the second control mode,
Monitoring whether a charging voltage of the charging capacitor included in the pulse voltage source is equal to a second target value and monitoring the phase of the AC voltage input to the pulse voltage source when the charging voltage of the charging capacitor is different from the second target value So that the charging voltage follows the second target value,
Monitors whether the sum of the DC high voltage and the pulse voltage is equal to a third target value if the charge voltage of the charge capacitor is equal to the second target value, and if the sum of the DC high voltage and the pulse voltage is greater than a third target value The sum of the DC high voltage and the pulse voltage controls the third target value by controlling at least one of the phase of the AC voltage input to the DC voltage source and the phase of the AC voltage input to the pulse voltage source Independent control type micro-pulse system. The method according to claim 1,
Wherein,
Wherein when the first control mode is selected, the operation of the pulse voltage source is stopped by setting the gating signal applied to the pulse voltage source to 0 for the operation of the pulse voltage source. The method according to claim 1,
Wherein the direct current voltage source includes a first direct current voltage generator for generating and outputting a negative direct current high voltage,
Wherein the pulse voltage source is a second DC voltage generating unit for generating and outputting a positive DC high voltage, one end connected to the first DC voltage generating unit and the other end connected to the second DC voltage generating unit, And a switching unit for outputting, as the pulse voltage, a voltage that is turned on and off according to the control of the control unit and charged in the charge capacitor, characterized by comprising: system. A micropulse system for outputting at least one of a direct current high voltage and a pulse voltage according to a selected control mode; And
And a dust collector which includes a discharge electrode and a dust collecting plate and operates according to at least one of a direct current high voltage and a pulse voltage output from the micropulse system to remove dust contained in the exhaust gas,
The micro-
A DC voltage source for generating a DC high voltage and applying the DC high voltage to the discharge electrode;
A pulse voltage source for generating a pulse voltage and applying the pulse voltage to the discharge electrode; And
Wherein when the first control mode for the initial operation or test operation of the dust collector is selected, the DC voltage source is operated and the operation of the pulse voltage source is stopped to output the DC high voltage, and a second control mode And a controller for operating the DC voltage source and the pulse voltage source to output the DC high voltage and the pulse voltage,
Wherein the control unit selects a third control mode when the flashover occurs and controls the operations of the direct current voltage source and the pulse voltage source according to the occurrence of the flashover. 10. The method of claim 9,
Wherein,
If the flashing time point and the switching unit for generating the pulse voltage are not equal to each other according to the third control mode, it is determined that a flashover has occurred due to the DC high voltage, the operation of the pulse voltage source is stopped, And when the flashing point of time is equal to the timing of turning on the switching unit for generating the pulse voltage, it is determined that a flashover has occurred due to the pulse voltage, and the operation of the pulse voltage source is stopped Electric dust collecting device. A method of operating a micropulse system including a direct current voltage source for generating and outputting a direct current high voltage and a pulse voltage source for generating and outputting a pulse voltage,
Selecting a control mode;
When the first control mode is selected, the DC voltage source is operated to stop the operation of the pulse voltage source to output the DC high voltage, and when the second control mode is selected, the DC voltage source and the pulse voltage source are operated, Outputting the pulse voltage;
Monitoring whether a spark occurs; And
And controlling the operations of the DC voltage source and the pulse voltage source according to the flash lamp generation cause. 12. The method of claim 11,
Wherein the step of controlling operations of the DC voltage source and the pulse voltage source comprises:
If it is determined that a flashover has occurred due to the DC high voltage, the operation of the DC voltage source is controlled so as to stop the operation of the pulse voltage source and to reduce the DC high voltage by a predetermined value. If it is determined that the flashover is generated by the pulse voltage And the operation of the pulse voltage source is stopped. 12. The method of claim 11,
In the monitoring step,
If the flashover occurrence time point and the switching unit turn-on time for generating the pulse voltage are not the same, it is determined that the flashover occurred due to the DC high voltage. If the flashover occurrence time point and the switching unit turn- And judging that a flashover has occurred due to the voltage. 12. The method of claim 11,
Monitoring whether the DC high voltage output by the DC voltage source is equal to the first target value and outputting the phase of the AC voltage input to the DC voltage source when the DC high voltage is different from the first target value; So that the direct current high voltage follows the first target value. A method of operating a micropulse system including a direct current voltage source for generating and outputting a direct current high voltage and a pulse voltage source for generating and outputting a pulse voltage,
Selecting a control mode; And
When the first control mode is selected, the DC voltage source is operated to stop the operation of the pulse voltage source to output the DC high voltage, and when the second control mode is selected, the DC voltage source and the pulse voltage source are operated, And outputting the pulse voltage,
In the outputting step,
Monitoring whether a charging voltage of the charging capacitor included in the pulse voltage source is equal to a second target value and monitoring the phase of the AC voltage input to the pulse voltage source when the charging voltage of the charging capacitor is different from the second target value So that the charging voltage follows the second target value,
Monitors whether the sum of the DC high voltage and the pulse voltage is equal to a third target value if the charge voltage of the charge capacitor is equal to the second target value, and if the sum of the DC high voltage and the pulse voltage is greater than a third target value The sum of the DC high voltage and the pulse voltage controls the third target value by controlling at least one of the phase of the AC voltage input to the DC voltage source and the phase of the AC voltage input to the pulse voltage source Of the independent control type micro-pulse system.

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