KR101547024B1 - Electrostatic Precipitator and Method for Controlling Electrostatic Precipitator - Google Patents

Abstract

The electric dust collector according to one aspect of the present invention, which can control the discharge of dust by organically controlling the operation state of the unit facilities constituting the electric dust collector, includes an electric dust collecting unit for collecting dust contained in the exhaust gas, ; A high voltage power supply for applying a high voltage to the body for electrostatic dust collection; A chattering device for separating dust collected on a dust collecting plate included in the main body from the dust collecting plate; A flow rate sensor for measuring an amount of exhaust gas supplied to the main body; A first sensor for measuring a first dust amount contained in an exhaust gas flowing into the main body; A second sensor for measuring a second amount of dust contained in the exhaust gas discharged from the main body; And a control routine to be executed in accordance with the amount of exhaust gas, the first dust amount, and the second dust amount, to adjust a voltage applied by the high voltage power supply in accordance with the selected control routine, And an upper controller for adjusting the chatter frequency.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrostatic precipitator and a control method for the electrostatic precipitator,

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.

In a large-scale dust extraction plant such as a thermal power plant or a sinter plant, a dust collector is essentially used. The electrostatic precipitator is an environmental facility that removes the dust contained in the exhaust gas by using the electrostatic force in order to reduce the dust emission amount of the stack from which the exhaust gas is discharged to less than the standard value prescribed by the Environmental Law. In recent years, regulations for dust emission concentration and fine dust have been strengthened, and thus it is necessary to improve the dust collection efficiency of the electric dust collector.

The electric power collecting device applies electric charge to the air through the high voltage power supply device so that the charged electric charge is moved to the dust collecting plate by the action of the electric field in the state of surrounding the dust and then the dust collecting plate is chased to drop the dust downward, Remove dust.

The principle of operation of a general electric dust collector will be briefly described with reference to Fig.

FIG. 1 is a view for explaining the operation principle of a general electric dust collector, and shows an example of an apparatus for performing electric dust collection using a DC power source.

As shown in FIG. 1, when a negative voltage is applied to the discharge electrode, a corona discharge is generated through the discharge electrode to discharge the negative ions into the air, and the negative ions applied to the air surround the dust in the air to discharge the negative ions.

The negative ion is applied to the dust collecting pole so that the negative ions can be attracted to the dust collecting pole. The ionized dust moving to the dust collecting pole moves to the dust collecting pole and returns to the power source through the dust collecting pole. The dust that has lost the negative ion is no longer able to stay in the dust collector and falls down to be collected in the collection room (not shown).

The electric dust collecting apparatus as described above is composed of a plurality of unit facilities such as a built-in device (a dust collecting plate, a discharge electrode, an insulating insulator, etc.), a high voltage power supply device, a chatter device, a dust measuring device, a transfer device, The control of each unit facility constituting the control unit was performed.

That is, conventionally, the operation mode and the operation order are inputted for each unit constituting the electric dust collecting apparatus, and the continuous operation is repeatedly performed. Therefore, although the convenience of control can be ensured from the viewpoint of each unit facility, it is impossible to control the electric dust collector from the overall viewpoint. Therefore, in a state where the input load fluctuates, the operation state of each unit facility is controlled organically There is a problem that the discharge concentration of the dust may be exceeded. In addition, there is also a problem that the operation stability of the production process can not be guaranteed because the emission concentration may cause a penalty such as the production regulation and environment charge of the industry.

Further, in order to control the electric dust collector, it is necessary to judge whether the control is required through the state determination of the electric dust collector. However, in the conventional case, it is necessary to judge whether or not the control of the electric dust collector is required, The control order and the control method between each unit are also subjectively determined by the judgment of the operator even if the control of the electric dust collector is determined by the operator. So that it takes a long time for the operation of the electric dust collector to be normalized or the operation may not be normalized.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an electric dust collector and a control method of an electric dust collector capable of controlling the discharge of dust by organically controlling the operation state of the unit facilities constituting the electric dust collector, We will do it.

Another object of the present invention is to provide an electric dust collector and a control method of an electric dust collector which can automatically determine the state of the electric dust collector and the control mechanism of the electric dust collector according to the determined state.

According to an aspect of the present invention, there is provided an electrostatic precipitator including: a main body in which electrostatic dust collection is performed to collect dust contained in an exhaust gas; A high voltage power supply for applying a high voltage to the body for electrostatic dust collection; A chattering device for separating dust collected on a dust collecting plate included in the main body from the dust collecting plate; A flow rate sensor for measuring an amount of exhaust gas supplied to the main body; A first sensor for measuring a first dust amount contained in an exhaust gas flowing into the main body; A second sensor for measuring a second amount of dust contained in the exhaust gas discharged from the main body; And a control routine to be executed in accordance with the amount of exhaust gas, the first dust amount, and the second dust amount, to adjust a voltage applied by the high voltage power supply in accordance with the selected control routine, And an upper controller for adjusting the chatter frequency.

According to another aspect of the present invention, there is provided a control method for an electric dust collector, including: an amount of exhaust gas flowing into a main body in which electric dust collection is performed; a first dust amount contained in the exhaust gas flowing into the main body; Measuring a second amount of dust contained in the exhaust gas discharged from the first chamber; Selecting a control routine to be executed in accordance with the amount of exhaust gas, the first dust amount, and the second dust amount; And a controller for executing the selected control routine to control the voltage applied to the main body, the chracteristics or the chatter frequency of the chattering device for separating the dust from the dust collecting plate included in the main body, and the conveyance for transferring the dust separated from the dust- And adjusting the transfer speed of the apparatus.

According to the present invention, the operation of the electric dust collector can be controlled as a whole while organically adjusting the operation state of the unit facilities constituting the electric dust collector according to the input load and the dust discharge state of the electric dust collector, There is an effect that the electric dust collector can be controlled more quickly and quickly than when operated individually.

In addition, according to the present invention, since the operation of the electric dust collector is entirely controlled while organically adjusting each unit constituting the electric dust collector, it is possible to efficiently control the dust discharge concentration, and as a result, Therefore, it is possible to prevent the occurrence of penalties such as the production regulation and the environment charge of the industrial sector, thereby ensuring the operational stability of the production process.

Further, according to the present invention, the state of the electric dust collector is automatically determined according to the input load and the dust discharge state of the electric dust collector, and the control order or the control method of the electric dust collector is automatically determined according to the determined state, There is an effect that the control routine of the dust collecting apparatus can be standardized.

In addition, according to the present invention, the control routine of the electric dust collector is standardized, thereby minimizing the time required for normalization of the electric dust collector when an abnormal condition occurs.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view for explaining the operation principle of a general electric dust collector. Fig.
2 is a block diagram schematically showing the configuration of an electric dust collector according to an embodiment of the present invention;
3 is a flowchart illustrating a method of controlling an electric dust collector according to an exemplary embodiment of the present invention.
4 is a flowchart showing a control method of an electric dust collector according to a first control routine;
5 is a flowchart showing a control method of an electric dust collector according to a second control routine.
6 is a flowchart showing a control method of an electric dust collector according to a third control routine.

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.

Electric dust collector

2 is a block diagram schematically illustrating the configuration of an electric dust collector according to an embodiment of the present invention.

2, an electric dust collector 200 according to an embodiment of the present invention includes a dust collector main body 210, a high voltage power supply 220, a chattering device 230, a transfer device 240, A sensor 250, a first sensor 260, a second sensor 270, and an upper controller 280. Although not shown in FIG. 2, the electrostatic precipitator 200 may further include a plurality of subsidiary devices constituting the electrostatic precipitator 200.

The dust collector main body 210 (hereinafter, referred to as 'main body') is a space in which electric dust collection is performed to collect dust contained in the flue gas, and includes an inlet 212 into which the flue gas flows, a dust collection space 214, and an outlet 216 through which exhaust gas is discharged.

In one embodiment, the dust collecting space 214 in which the dust contained in the exhaust gas is collected may be composed of 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.

When a high voltage is applied by the high voltage power supply unit 220, the discharge electrode generates negative ions through ionization by a 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 high voltage power supply 220 causes a battery dust collection in the dust collecting chamber included in the main body 210 by applying a high voltage to the main body 210.

In one embodiment, the high voltage power supply 220 includes a DC power supply unit (not shown) for supplying negative DC power to the discharge electrode, a pulse power supply unit for supplying a positive DC power for the pulse power source ), And a charging capacitor (not shown) that charges when the DC power is supplied from the DC power supply and the DC power supplied from the pulse power supply, and discharges when the pulse power is applied to the dust collecting plate. At this time, one end of the charge capacitor is connected to the DC power supply, and the other end of the charge capacitor is connected to the pulse power supply.

According to this embodiment, since a negative high voltage supplied from the DC power supply unit is applied to the discharge electrode and a positive high voltage charged to the charge capacitor is applied to the dust collecting plate, when the pulse power is applied to the dust collecting plate, A voltage corresponding to the difference between the high voltage and the high voltage applied to the dust collecting electrode is applied to the dust collecting chamber. For example, when the voltage applied to the discharge electrode is -30 kV and the pulse voltage applied to the dust collecting plate is +40 kV, the same effect as -70 kV is applied to the dust chamber. In this way, although a high voltage is applied in the dust collecting chamber, the voltage applied through the discharge electrode is lower than the voltage applied in the dust collecting chamber, so that the reverse phenomenon is less likely to occur.

The chattering device 230 separates dust attached to the dust collecting plate included in the main body 210 from the dust collecting plate through the chatter. That is, the chattering device 230 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 230 can improve the chatter efficiency by controlling the chatter strength or the chatter frequency.

The transfer device 240 serves to transfer the dust separated from the dust collecting plate to the storage (not shown) by the chattering device 230. In one embodiment, the transfer device 240 is moved in accordance with the transfer rate set by the host controller to transfer the dust to the reservoir.

The flow rate sensor 250 is disposed at the inlet 212 of the main body 210 and measures the amount of exhaust gas flowing into the main body 210 from the outside every predetermined period and transmits the measured amount of exhaust gas to the host controller 270 do.

The first sensor 260 is disposed at an inlet 212 of the main body 210 and measures a first amount of dust contained in the exhaust gas flowing into the main body 210. The first sensor 260 transmits the measured first dust amount to the host controller 280. The first sensor 260 may measure the first dust amount at predetermined intervals or may measure the first dust amount according to an instruction from the host controller 280 and may transmit the measured first dust amount to the host controller 280. In another embodiment, the first sensor 260 may measure the first dust amount each time the chattering by the chattering device 230 is completed, and may transmit the measured first dust amount to the host controller 280.

The second sensor 270 is disposed at the outlet 214 of the main body 210 and measures a second amount of dust contained in the exhaust gas discharged from the main body 210. The second sensor 270 transmits the measured second dust amount to the host controller 280. The second sensor 270 may measure the second dust amount at predetermined intervals or may measure the second dust amount according to an instruction from the host controller 280 and transmit the measured second dust amount to the host controller 280. In another embodiment, the second sensor 270 may measure the second dust amount each time the chattering by the chattering apparatus 230 is completed, and may transmit the measured second dust amount to the host controller 280.

The host controller 280 controls the amount of dust collected by the electric dust collecting unit 250 according to the amount of exhaust gas measured by the flow sensor 250, the first dust amount measured by the first sensor 260 and the second dust amount measured by the second sensor 270 Determines the internal state of the apparatus 200, and selects a control routine to be executed in accordance with the determination result.

When the control routine to be executed is selected, the host controller 280 controls the voltage applied to the main body 210 by the high-voltage power supply 220 according to the selected control routine, or adjusts the chatter intensity or the chatter frequency of the chattering device 230 So that the second dust amount is less than or equal to the predetermined emission threshold value or the second dust amount is decreased.

In one embodiment, the host controller 280 determines whether the amount of exhaust gas, the amount of first dust, and the amount of second dust are both in an increased state (first case), as shown in Table 1 below. In the case where one dust amount is in an increase state and a second dust amount is in a maintenance state (second case), when the exhaust gas amount and the first dust amount are in the reduced state and the second dust amount is in the maintained state (third case) It is determined that an abnormality has occurred in the apparatus 200 and the execution of the control routine is determined.

Case Flow sensor The first sensor The second sensor The amount of exhaust gas (Q) The first amount of dust (Din) The second dust amount Dout One increase increase increase 2 increase increase immutability 3 decrease decrease immutability

More specifically, in the case of the first case where the exhaust gas amount, the first dust amount, and the second dust amount are both increased, the host controller 280 calculates the dust removal efficiency of the electric dust collector 200 by increasing the load It is determined that the first control routine is to be executed.

In the case of the second case in which the amount of exhaust gas and the first dust amount are in the increased state but the second dust amount is in the maintained state, the upper controller 280 suspects the dust accumulation of the dust collecting plate included in the main body 210 due to the load increase, It is determined that the second control routine is executed because an increase in the second dust amount is expected at a time difference.

The host controller 280 determines that the exhaust gas amount and the first dust amount are in the reduced state but the second dust amount is in the maintained state in the case where the load is reduced but the internal dust emission is not smooth and the third control routine To be executed.

In this manner, the host controller 280 determines the internal state of the electric dust collector 200 according to the amount of exhaust gas, the first dust amount, and the second dust amount, and determines whether to execute the control routine or not according to the determination result .

On the other hand, in the case of the fourth case in which the amount of exhaust gas is in the increased state but the first dust amount and the second dust amount are maintained as shown in Table 2 below, the host controller 280 is in the factory stop sequence state, It is determined that a separate control routine is not executed.

Further, in the case of the fifth case in which the exhaust gas amount, the first dust amount, and the second dust amount are both in the reduced state, the host controller 280 determines that the normal operation is possible under the load relief state and executes the separate control routine .

In the case of the sixth case in which the amount of exhaust gas is in a reduced state but the first dust amount and the second dust amount are maintained, the host controller 280 is in a state where there is no change in the concentration of exhaust dust while the load is reduced. It is judged that it is the situation and it is judged that the separate control routine is not executed.

Case Flow sensor The first sensor The second sensor The amount of exhaust gas (Q) The first amount of dust (Din) The second dust amount Dout 4 increase immutability immutability 5 decrease decrease decrease 6 decrease immutability immutability

When the execution of the control routine is determined, the host controller 280 selects the control routine for each case, adjusts the voltage applied to the main body 210 by the high-voltage power supply 220 according to the selected control routine, Thereby controlling the chatter intensity or the chatter frequency of the chattering device 230.

That is, in executing each control routine, the host controller 280 executes the control routine by taking into consideration the operation of a plurality of unit facilities, rather than controlling only the operation of the specific unit facility. This is because each of the units constituting the electrostatic precipitator 200 has different operation characteristics as well as each unit facility comprehensively affects the final dust emission as described below.

First, in the case of the high voltage power supply 220, if the voltage applied to the main body 210 is reduced, the dust collection rate decreases. If the voltage is increased, the dust collection rate increases. However, this may vary depending on the situation of the dust collection panel. For example, when the dust collecting plate has a large number of dust collecting layers, increasing the voltage causes a side effect that makes it difficult to separate through the dust collecting dust, and if the voltage is reduced, the dust particles collected on the dust collecting plate may be scattered again.

Also, in the case of the chattering device 230, the chatter strength and the chatter frequency can be adjusted. However, if only the chatter strength is increased, the dust particles collected on the dust collecting plate may be re-scattered.

In the case of the transfer device 240, although the effect of the overall dust collecting process is low, when the normally collected dust can not be discharged to the outside of the electrostatic precipitator 200, dust is accumulated in the lower portion of the electrostatic precipitator 200, The side effects of dust redistribution due to flow can occur.

The host controller 280 sequentially selects the control routines for each case so that the high voltage power supply 220, the chattering device 230 and the transferring devices 240 are sequentially So that the operation of the plurality of unit facilities can be controlled in a comprehensive manner.

Hereinafter, the control routine selected for each case will be described in more detail.

The first control routine

First, the host controller 280 selects the first control routine with the control routine to be executed when it is determined that the first case is generated in the electric dust collector 200 based on the exhaust gas amount, the first dust amount, and the second dust amount.

As described above, the first case is a situation in which the second dust amount exceeds the exhaust threshold, and the output of all the unit facilities of the electric dust collector 200 is increased to increase the collecting efficiency as a whole. The control unit 280 executes the first control routine so that the second dust amount becomes smaller than the emission threshold value within a short time. Particularly, in the case of the first case, since it is determined that the amount of dust deposited on the dust collecting plate is large, it is preferable to discharge the dust collected on the dust collecting plate to the outside quickly.

Accordingly, in accordance with the first control routine, the host controller 280 increases the conveying speed of the conveying device 240 so that the collected dust in the electrostatic precipitator 200 can be rapidly discharged to the outside, and at the same time, The voltage applied to the main body 210 by the power supply unit 220 is maintained at the reference voltage level and the chaotic intensity of the chatter unit 230 is increased by the first increase amount from the reference chatter intensity.

In one embodiment, the reference voltage level may be an average value that was applied to body 210 by high voltage power supply 220 for a period of time. Also, the increased chatter strength should not exceed 150% based on the reference chatter strength.

As described above, in the first control routine, the voltage applied to the main body 210 is maintained at the reference voltage level because if the voltage is too high, separation of dust due to the outputting force becomes difficult, Is due to the fact that an increase in chatter strength is more advantageous in removing the thick dust layer which is trapped on the dust collecting plate than the increase in the chatter frequency.

The host controller 280 compares the second dust amount re-measured by the second sensor 270 with the exhaustion threshold after the completion of the hunting according to the first control routine, and when the re-measured second dust amount is smaller than the exhaustion threshold The first control routine is terminated by returning the conveying speed of the conveying device 240 to the reference conveying speed, returning the voltage to the reference voltage level, and returning the contour strength to the reference contour strength.

On the other hand, if the re-measured second dust amount is not less than the emission threshold, the host controller 280 determines that the voltage applied to the main body 210 interferes with the chatter according to the first control routine, 1 reduction amount, and the increased chatter strength is maintained so that the chattering is performed again. In one embodiment, the reduced voltage level should not be less than a maximum of 80% based on the reference voltage level.

The second control routine

The host controller 280 selects the second control routine with the control routine to be executed when it is determined that the second case is generated in the electric dust collector 200 based on the exhaust gas amount, the first dust amount, and the second dust amount.

As described above, the amount of the second dust discharged from the main body 210 is not a problem, but the amount of the exhaust gas flowing into the main body 210 and the amount of the first dust increase, It is predicted that the second dust amount will exceed the emission threshold value when the time elapses, so that the control change is required on the preliminary level. That is, in the second case, dust accumulated inside gradually must be removed while maintaining the voltage level of the voltage, which is the electric force of dust collecting, the same.

Accordingly, the host controller 280 increases the conveying speed of the conveying device 240 in accordance with the second control routine so that dust accumulated in the conveying device 240 can be rapidly discharged to the outside, and the main body 210 ) Is maintained at the reference voltage level, the chatter frequency of the chattering device 230 is increased by a second increase amount in the reference chatter frequency, and the dust accumulated on the dust collecting plate is gradually transferred to the transferring device 240 .

In one embodiment, the increased chatter frequency does not exceed a maximum of 150% based on the reference chatter frequency.

The host controller 280 compares the second dust amount re-measured by the second sensor 270 with the exhaustion threshold after the completion of the hunting according to the second control routine, and when the re-measured second dust amount is smaller than the exhaustion threshold The first dust amount measured by the first sensor 260 is compared with the entrance threshold value and if the re-measured first dust amount is smaller than the entrance threshold value, the conveyance speed of the conveyance device 240 is returned to the reference conveyance speed, The second control routine is terminated by returning the chatter frequency of the device 230 to the reference chatter frequency. If the re-measured first dust amount is not less than the inlet threshold value, the second control routine is repeatedly performed while maintaining the voltage and the reverse frequency until the first dust amount re-measured becomes smaller than the inlet threshold value.

On the other hand, if the re-measured second dust amount is not smaller than the exhaustion threshold value, the host controller 280 determines that the second dust amount has increased abruptly due to the increase in the chatter frequency, and executes the first control routine described above.

The third control routine

The host controller 280 selects the third control routine with the control routine to be executed if it is determined that the third case has occurred in the electric dust collector 200 based on the exhaust gas amount, the first dust amount, and the second dust amount.

As described above, in the third case, when the exhaust gas amount and the first dust amount are in the reduced state but the second dust amount is in the maintained state, the input exhaust gas amount decreases and the second dust amount decreases as the first dust amount decreases However, since the amount of the second dust to be discharged is not increasing, it can be judged that the situation is not a situation requiring strengthening of the collection power.

Accordingly, the host controller 280 maintains the feed rate of the feeder 240 at the reference feed rate in accordance with the third control routine, and the voltage applied to the main body 210 so as to be advantageous to the chatter is reduced by a first decrease amount And the chatter intensity is increased by the second increase amount in the reference chatter frequency while maintaining the chatter intensity at the reference chatter intensity. In the third control routine, the chatter frequency is increased while maintaining the chatter strength because dust accumulated in the dust collecting plate can be induced to separate naturally, which is more advantageous than controlling the chatter strength.

The host controller 280 determines whether or not the second dust amount re-measured by the second sensor 270 is in the reduced state after the completion of the chatter according to the third control routine, and when the second dust amount is in the reduced state It is determined that the electric dust collector 200 is in a normal state, and the chatter frequency of the chattering device 230 is returned to the reference chatter frequency to end the third control routine.

On the other hand, when the re-measured second dust amount is not in the reduced state, the host controller 280 determines that the state of the dust collected on the dust collecting plate is very bad, returns the reverse frequency to the reference chatter frequency, The chaotic intensity is increased by the first increase amount from the reference chaotic intensity until it becomes the reduced state. This means that the dust collected on the dust collecting plate is in bad condition because the particles have a high water content or a viscous nature of the dust particles and the dust can not be separated from the dust collecting plate. To increase the rate of application of the target force is more advantageous than to increase the frequency.

As described above, the electric dust collector 200 according to the present invention normalizes the control routine of the electric dust collector 200 based on the amount of exhaust gas, the first dust amount, and the second dust amount, thereby operating the dust collecting apparatus 200 It is possible to minimize the difference in the control that can be caused by the technical deviation between the operators, thereby eliminating the place constraint and the time constraint that are generated in the individual control of each unit, Thereby allowing the amount of dust to be discharged to reach a steady state, which is an emission threshold value.

The "state determination" in which it is determined whether or not the control of the electric dust collector 200 is required is not determined by subjective judgment of the driver but the amount of exhaust gas measured by the flow sensor 250, And the second dust amount measured by the second sensor 270, the internal state of the electric dust collector 200 can be more accurately determined.

Control method of electric dust collector

Hereinafter, a method of controlling the electric dust collector according to the present invention will be described with reference to FIGS. 3 to 6. FIG.

3 is a flowchart illustrating a method of controlling an electric dust collector according to an embodiment of the present invention.

The control method of the electric dust collector shown in FIG. 3 can be performed by the host controller shown in FIG. 2 as a method for controlling the operation of the electric dust collector having the configuration as shown in FIG.

As shown in FIG. 3, when the amount of exhaust gas flowing into the main body, the first dust amount included in the exhaust gas flowing into the main body, and the second dust amount contained in the exhaust gas discharged from the main body are measured (S300) , The host controller selects a control routine to be executed according to the measured exhaust gas amount, the first dust amount, and the second dust amount (S310).

In one embodiment, the host controller determines an internal state of the electric dust collection state based on the measured amount of exhaust gas, the first dust amount, and the second dust amount to select a control routine to be executed, .

In one embodiment, as shown in Table 1 above, the host controller determines whether the electric dust collector is in a state where the gas amount, the first dust amount, and the second dust amount are both in the increased state (first case) When the amount of dust is in an increased state and the amount of second dust is in a holding state (second case), or when the amount of exhaust gas and the first dust amount are in a reduced state and the second dust amount is in a holding state (third case) 200) and determines to execute the control routine.

More specifically, in the case of the first case in which the exhaust gas amount, the first dust amount, and the second dust amount are all in an increased state, it is determined that the dust removal efficiency of the electrostatic precipitator should be increased by an increase in load, 1 Select the control routine.

In the case of the second case in which the exhaust gas amount and the first dust amount are in the increased state and the second dust amount is in the maintained state, the host controller suspects the dust accumulation of the dust collecting plate included in the main body due to the increase in load, The second control routine is selected.

In the case of the third case in which the exhaust gas amount and the first dust amount are in the reduced state but the second dust amount is in the maintained state, the host controller determines that the internal dust emission is not smooth and the third control routine is selected.

On the other hand, as shown in Table 2, when the electric dust collecting apparatus is in the state of increasing the exhaust gas amount but in the state where the first dust amount and the second dust amount are maintained (the fourth case) as shown in Table 2, It is determined that it is in the start sequence state and it is determined that no separate control routine is executed.

Further, when the electric dust collector is in the reduced state (fifth case) of the exhaust gas amount, the first dust amount, and the second dust amount, the host controller determines that the normal operation is possible under the load reduction state, It is determined not to execute.

Further, in the host controller, when the electric dust collector is in a state of decreasing the exhaust gas amount but in the state where the first dust amount and the second dust amount are maintained (sixth case), the concentration of the exhaust dust It is determined that the normal operation is possible and it is determined that no separate control routine is executed.

Next, the host controller executes the control routine selected in S310 (S320). In one embodiment, the host controller executes each control routine to control the voltage applied to the main body, the chatter intensity or the chatter frequency for separating the dust from the dust collecting plate included in the main body, and the dust separated from the dust collecting plate by the chattering If the first dust amount becomes smaller than the inlet threshold value or the second dust amount becomes smaller than the exhaustion threshold value through the adjustment, at least one of the transfer speeds of the transfer apparatuses is adjusted and the selected control routine is terminated.

Hereinafter, each of the control routines executed by the host controller will be described in more detail with reference to Figs. 4 to 6. Fig.

4 is a flowchart showing a control method of the electric dust collector according to the first control routine.

As shown in FIG. 4, when the first control routine is selected in S310 shown in FIG. 3, the host controller increases the conveying speed of the conveying apparatus from the reference conveying speed to the first conveying speed (S400).

Thereafter, the host controller maintains the voltage applied to the main body by the high-voltage power supply at the reference voltage level (S410). The upper controller keeps the voltage applied to the main body at the reference voltage level because if the voltage is too high, it becomes difficult to separate the dust by the applying force. In one embodiment, the reference voltage level may be an average value of voltage levels that have been applied to the body by the high voltage power supply for a certain period of time.

Thereafter, the host controller increases the contour of the contour by the first increment in the reference contour (S420). The reason why the host controller increases the chatter strength of the chattering unit is that the increase of the chatter strength is more advantageous in removing the thick dust layer collected in the dust collecting plate than the increase in the chatter frequency. In one embodiment, the increased chatter intensity does not exceed 150% based on the reference chatter intensity.

Thereafter, the host controller monitors the second dust amount (S430) and compares the second dust amount with the exhaust threshold (S440). If the second dust amount is smaller than the discharge threshold value, the conveying speed of the conveying device is returned to the reference conveying speed, the voltage is returned to the reference voltage level, the chaotic intensity is returned to the reference chaotic intensity, and the first control routine is terminated ).

On the other hand, if it is determined in S440 that the second dust amount is not less than the emission threshold value, the host controller determines that the voltage applied to the main body interferes with the chattering, and reduces the voltage applied to the main body by the first decrease amount S460), the chatter intensity is maintained at the increased chatter intensity, and the chattering is performed again (S470). In one embodiment, the reduced voltage level should not be less than a maximum of 80% based on the reference voltage level. Thereafter, the host controller returns to S430 and repeats the following steps.

5 is a flowchart showing a control method of the electric dust collector according to the second control routine.

As shown in FIG. 5, when the second control routine is selected in S310 shown in FIG. 3, the host controller increases the conveying speed of the conveying apparatus from the reference conveying speed to the first conveying speed (S500).

Thereafter, the host controller maintains the voltage applied to the main body by the high-voltage power supply at the reference voltage level (S510). The upper controller keeps the voltage applied to the main body at the reference voltage level because if the voltage is too high, it becomes difficult to separate the dust by the applying force.

Thereafter, the host controller increases the chatter frequency of the chattering device by the second increase amount in the reference chatter frequency (S520). The reason why the host controller increases the chatter frequency of the chattering unit is because the increase of the chatter frequency is more advantageous to gradually remove the dust accumulated in the dust collecting plate than the increase of the chatter strength. In one embodiment, the increased chatter frequency does not exceed 150% based on the reference chatter frequency.

Thereafter, the host controller monitors the second dust amount (S530) and compares the second dust amount with the exhaust threshold (S540). As a result of the comparison, if the second dust amount is not smaller than the emission threshold value, it is determined that the second dust amount has increased abruptly according to the increase of the reverse frequency, and the first control routine shown in FIG. 4 is executed (S550).

On the other hand, if it is determined in step S540 that the second dust amount is smaller than the discharge threshold value, the first dust amount is compared with the inlet threshold value (S560). As a result of the comparison, if the first dust amount is not smaller than the intake threshold value, the second control routine is repeatedly performed until the first dust amount is smaller than the intake threshold value and the chatter frequency is maintained in the current state (S570).

On the other hand, if it is determined in step S560 that the first dust amount is smaller than the entrance threshold value, the conveyance speed of the conveyance apparatus is returned to the reference conveyance speed, the chatter frequency is returned to the reference chatter frequency, and the second control routine is terminated (S580).

6 is a flowchart showing a control method of the electric dust collector according to the third control routine.

As shown in FIG. 6, when the third control routine is selected in S310 shown in FIG. 3, the host controller maintains the feed rate of the feeder at the reference feed rate (S600).

Thereafter, the host controller decreases the voltage applied to the main body by the high voltage power supply by the first decrease amount at the reference voltage level (S610).

Thereafter, the host controller increases the chatter frequency of the chattering device by a second increase amount in the reference chatter frequency (S620).

Thereafter, the host controller monitors the second dust amount (S630) and determines whether the second dust amount is in the reduced state (S640). As a result of the determination, if the second dust amount is not in the reduced state, the chatter frequency is restored to the reference chatter frequency, the chaotic intensity is increased by the first increase amount in the reference chatter intensity (S650), and the process after S630 is repeated.

On the other hand, if it is determined in step S640 that the second dust amount is decreased, the voltage supplied to the body is returned to the reference voltage level, the chatter frequency is returned to the reference chatter frequency, the chatter intensity is returned to the reference chatter intensity, (S660).

6, if it is determined in step S640 that the second dust amount is not in the reduced state, the chatter frequency is immediately restored to the reference chatter frequency, and the chatter intensity is increased by the first increase amount in the reference chatter intensity. However, if it is determined in step S640 that the second dust amount is not in the reduced state, the second dust amount measured after performing the third control routine again while maintaining the voltage and the chatter frequency in the current state is not in the reduced state The chaotic frequency may be restored to the reference chaotic frequency and the chaotic intensity may be increased by the first increase in the reference chaotic intensity.

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: electric dust collector 210: dust collector main body
220: high voltage power supply 230: chattering device
240: Feeding device 250: Flow sensor
260: first sensor 270: second sensor
280:

Claims (16)

A main body in which electric dust collection for collecting dust contained in the exhaust gas is performed;
A high voltage power supply for applying a high voltage to the body for electrostatic dust collection;
A chattering device for separating dust collected on a dust collecting plate included in the main body from the dust collecting plate;
A flow rate sensor for measuring an amount of exhaust gas supplied to the main body;
A first sensor for measuring a first dust amount contained in an exhaust gas flowing into the main body;
A second sensor for measuring a second amount of dust contained in the exhaust gas discharged from the main body; And
A control routine to be executed according to the amount of exhaust gas, the first dust amount, and the second dust amount is selected, the voltage applied by the high voltage power supply device is adjusted according to the selected control routine, And an upper controller for controlling the frequency of the electric power. The method according to claim 1,
Wherein the host controller comprises:
Wherein the first control routine is selected when the exhaust gas amount, the first dust amount, and the second dust amount are in an increasing state, and the voltage is maintained at a reference voltage level in accordance with the first control routine, By a first increase amount in the first electric field. 3. The method of claim 2,
Wherein the host controller comprises:
If the second dust amount is not less than the emission threshold value, maintains the increased roughness intensity and decreases the voltage by the first reduction amount at the reference voltage level until the second dust amount is smaller than the exhausted threshold value,
Returning the voltage to the reference voltage level when the second dust amount is smaller than the discharge threshold value, returning the chatter intensity to the reference chatter intensity, and terminating the first control routine. The method according to claim 1,
Wherein the host controller comprises:
A second control routine is selected when the exhaust gas amount and the first dust amount are in an increasing state and the second dust amount is in a holding state and the voltage is maintained at a reference voltage level in accordance with the second control routine, And increases by a second increment in the reference chatter frequency. 5. The method of claim 4,
Wherein the host controller comprises:
If the second dust amount is not smaller than the emission threshold value as a result of the completion of the first control routine,
If the second dust amount is smaller than the discharge threshold value and the first dust amount is not smaller than the inlet threshold value, the second control routine is performed by keeping the voltage and chatter frequency current until the first dust amount becomes smaller than the inlet threshold value ,
Returning the voltage to the reference voltage level and returning the chatter frequency to the reference chatter frequency and terminating the second control routine if the second dust amount is less than the discharge threshold and the first dust amount is less than the entrance threshold Characterized in that the electric dust collecting device 6. The method according to any one of claims 2 to 5,
Further comprising a transfer device for transferring dust separated by the chatter device to a storage,
Wherein the host controller increases the conveying speed of the conveying device from the reference conveying speed to the first conveying speed when execution of the control routine is determined. The method according to claim 1,
Wherein the host controller comprises:
The third control routine is selected when the exhaust gas amount and the first dust amount are in the reduced state and the second dust amount is in the maintained state, and the voltage is decreased by the first reduction amount at the reference voltage level in accordance with the third control routine, And increases the chatter frequency by a second increment in the reference chatter frequency. 8. The method of claim 7,
Wherein the host controller comprises:
If the second dust amount does not decrease, restoring the chatter frequency to the reference chatter frequency and increasing the chatter intensity by a first increase amount from the reference chatter intensity until the second dust amount decreases,
If the second dust amount decreases, returning the voltage to the reference voltage level, returning the chatter frequency to the reference chatter frequency, returning the chatter intensity to the reference chatter intensity, and ending the third control routine Wherein the electric dust collecting device is an electric dust collecting device. Measuring an amount of exhaust gas flowing into the main body in which the electric dust collection is performed, a first dust amount contained in the exhaust gas flowing into the main body, and a second dust amount contained in the exhaust gas discharged from the main body;
Selecting a control routine to be executed in accordance with the amount of exhaust gas, the first dust amount, and the second dust amount; And
A control device for executing a selected control routine to control a voltage applied to the main body, a chatter strength or a chatter frequency of the chattering device for separating dust from the dust collecting plate included in the main body, and a transfer device for transferring the dust separated from the dust- And controlling a conveying speed of the electric dust collecting apparatus. 10. The method of claim 9,
The first control routine is selected when the exhaust gas amount, the first dust amount, and the second dust amount are in an increasing state,
Increasing the feed rate from a reference feed rate to a first feed rate in accordance with the first control routine and maintaining the voltage at a reference voltage level in accordance with the first control routine, Of the electric dust collecting device. 11. The method of claim 10,
After the adjusting step,
Remeasuring the second dust amount; And
If the re-measured second dust amount is not less than the exhaust threshold value, the increased chatter intensity is maintained and the voltage is reduced from the reference voltage level by the first decrease amount until the re-measured second dust amount is less than the emission threshold And recovering the voltage to a reference voltage level and restoring the chaotic intensity to the reference chatter intensity and terminating the first control routine if the re-measured second dust amount is less than the emission threshold Wherein the electric dust collecting device is a control device. 10. The method of claim 9,
The second control routine is selected when the exhaust gas amount and the first dust amount are in an increasing state and the second dust amount is in a holding state,
Increasing the feed rate from a reference feed rate to a first feed rate in accordance with the second control routine and maintaining the voltage at a reference voltage level in accordance with the second control routine, Of the electric dust collecting device. 13. The method of claim 12,
After the adjusting step,
Remeasuring the second dust amount;
If the re-measured second dust amount is not smaller than the discharge threshold value, the first control routine is performed until the re-measured second dust amount becomes smaller than the discharge threshold value, and if the re-measured second dust amount is smaller than the discharge threshold value If the first dust amount is not smaller than the inlet threshold value, the second control routine is performed by keeping the voltage and chatter frequency current until the first dust amount becomes smaller than the inlet threshold value, and the first dust amount is greater than the inlet threshold value And returning the voltage to the reference voltage level and returning the chatter frequency to the reference chatter frequency to terminate the second control routine. 10. The method of claim 9,
The third control routine is selected when the exhaust gas amount and the first dust amount are in the reduced state and the second dust amount is in the maintained state,
In the adjusting step, the conveying speed is maintained at a reference conveying speed in accordance with the third control routine, the voltage is reduced by a first decreasing amount at a reference voltage level, and the chatter frequency is reduced by a second increasing amount Wherein the control unit controls the electric dust collecting apparatus to control the electric dust collecting apparatus. 15. The method of claim 14,
After the adjusting step,
Remeasuring the second dust amount;
If the re-measured second dust amount does not decrease, restoring the chaotic frequency to the reference chaotic frequency and increasing the chaotic intensity by a first increase amount from the reference chaotic intensity until the re-measured second dust amount decreases, Returning the voltage to the reference voltage level, returning the chaotic intensity to the reference chaotic intensity, returning the chaotic frequency to the reference chaotic frequency, and terminating the third control routine when the re- Wherein the electric dust collecting apparatus further comprises: A computer-readable recording medium having recorded thereon a program for performing a control method of an electric dust collector according to any one of claims 10 to 15.

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