KR101984321B1 - Electrostatic precipitator - Google Patents

Abstract

The electrostatic precipitator includes a charging section, a dust collecting section, and a fan, wherein all the positive and negative electrification plates and the negative electrification negative plates are formed by a needle-like precipitating front portion and an electrode side surface portion, And is provided on the side where the wind blows more than the entire saliva of the charging negative electrode plate. In the charging section, the entire acupuncture point and the electrode face portion are alternately arranged. The settling portion of the positive charging negative electrode plate generates a positive corona to the electrode surface portion of the negative charging negative electrode plate having a lower relative potential than that of the negative charging electrode plate and the set discharging portion of the negative charging negative plate has a relatively high potential And a negative corona is generated at the electrode surface portion of the negative electrode plate. The dust passing through the charging portion is charged with a positive polarity, and the dust is collected from the entire surface of the charging electrode plate and the grounding electrode plate of the dust collecting portion.

Description

ELECTROSTATIC PRECIPITATOR

The present invention relates to an electric dust collector.

Conventional electrostatic precipitators generate a positive corona discharge or a negative corona discharge in a charging section. A direct current high voltage is applied to the discharge electrode of the charging portion, either the positive corona or the negative corona is generated. Then, dust passing through the charging section is charged positively or negatively. This charged dust is collected on the ground electrode plate surface by the electrostatic force generated by the high electric field of the dust collecting portion having the charged electrode plate (load electrode plate) to which the direct current high voltage is applied and the dust electrode plate connected to the ground (for example, 1).

Hereinafter, the principle of the electrostatic dust collecting and blowing will be described with reference to Fig. Fig. 12 is a principle of dust collection of a conventional electric dust collector. As shown in Fig. 12, the electric dust collecting apparatus is composed of a charging section 104 and a dust collecting section 105. Fig. The ventilation direction is the dust collecting section 105 from the charging section 104. A direct current high voltage power source 108 of + 11 kV and a direct current high voltage power source 109 of +5.5 kV are connected to the charging section 104 and the dust collecting section 105, respectively.

The charging section 104 is composed of a discharge electrode 104A and a ground electrode plate 104B. A direct current high voltage of +11 kV is applied to the discharge electrode 104A and a positive corona occurs in the space between the discharge electrode 104A and the ground electrode plate 104B. The positive ions generated by the corona discharge charge the dust (not shown) in the space, and the dust is positively charged. In the dust collecting section 105 at the rear stage, a strong ammeter is formed between the charged electrode plate 105A and the ground electrode plate 105B. Then, the charged dust is collected on the grounding electrode plate 105B by the electrostatic force generated by this strong ammeter.

In the above description, the case where the positive high voltage is applied to the electrostatic precipitator has been described. However, when the negative high voltage is applied, the dust is collected on the ground electrode plate 105B. The conventional electric dust collecting apparatus is characterized in that the charging section 104 and the dust collecting section 105 are independent two-stage electric dust collecting systems.

Further, in this type of electric dust collecting apparatus, there is a problem of "re-scattering" in which a part of the dust collected in the dust collecting section 105 is peeled and returned to the air again, resulting in a decrease in the dust collecting efficiency. In order to solve this problem, dust is charged in a charging section 104 using a DC high voltage, and a square wave voltage in which positive and negative high voltages are periodically alternately inverted is applied to the dust collecting section 105. As a result, the dust collecting area of the dust collecting part 105 doubles, so that re-scattering is suppressed, and the dust collecting performance is improved (see, for example, Patent Document 2).

Hereinafter, the principle of the electrostatic dust collecting and blowing will be described with reference to Fig. 13 is a principle of dust collection of another conventional electric dust collector. 13 is different from that of FIG. 12 in that a high voltage applied to the dust collecting section 105 is not a direct current, but a square wave in which the phases are alternately inverted. Therefore, a square-wave high-voltage power source 110 is provided in Fig.

The dust (not shown) is charged positively by the corona discharge of the charging section 104, and flows into the dust collecting section 105. Here, when the voltage applied to the lower electrode plate 105A of the dust collecting section 105 is normal, the dust charged positively is collected on the grounding electrode plate 105B. Further, when the voltage applied to the charged electrode plate 105A is negative, dust that is positively charged is collected on the charged electrode plate 105A. That is, the dust is collected not only on the grounding electrode plate 105B but also on the lower electrode plate 105A in the dust collecting unit 105. [ Therefore, the dust collecting area is doubled, and the dust collecting performance is improved.

Fig. 14 is a principle of dust collection of another conventional electric dust collector. In the electric dust collector shown in Fig. 14, the positively charged dust and the negatively charged dust are simultaneously generated in the charging portion 104. Fig. The dust is collected at the ground electrode plate 104B connected to the ground in the dust collecting unit 105 and the lower electrode plate 105A to which the DC high voltage is applied (for example, see Patent Document 3). The dust that has passed through the dust collecting section 105 is prevented from being charged by the electric neutralizing action and the contamination of the wall surface and the like on the rear side of the electric dust collecting apparatus is prevented.

As shown in Fig. 14, the positive electrode 104A of the charging portion 104 generates a positive corona toward the grounding electrode plate 104B. At this time, the ground electrode plate 104B of the charging portion 104 and the discharge electrode 104C on the same potential are directed to the plane portion of the positive electrode 104A and generate a sub-corona. The applied voltage + 6 kV of the charging section 104 is a value obtained on the basis of the prior test. That is, the positive applied voltage is determined so that the amount of the charged dust generated from the positive corona from the positive discharge electrode 104A and the negative corona from the sub-discharge electrode 104C becomes equal. In Fig. 14, the portion connected to the ground line in the charging portion 104 is shown as being independent of the grounding electrode plate 104B and the sub-discharge electrode 104C, but they may be integrated.

Fig. 15 is a view showing an example of the configuration of a charging section of a conventional electrostatic precipitator, and Fig. 16 is a diagram showing another configuration example of a charging section of a conventional electrostatic precipitator. 15 and 16, the positive discharge electrode 104A and the negative discharge electrode 104D are arranged in parallel. Here, the sub-discharge electrode 104D is formed by integrating the planar portion of the ground electrode plate and the discharge electrode. The positive applied voltage is determined such that the amounts of the charged dust generated from the normal corona and the secondary corona are equal to each other. This improves the dust collecting performance. The applied voltage may be a negative voltage. In any case, the voltage value is determined by a preliminary test for each shape of the hardware.

Patent Document 1: JP-A-10-202143 Patent Document 2: Japanese Patent Application Laid-Open No. 2004-66063 Patent Document 3: Japanese Patent No. 3124193

In such a conventional electric dust collecting apparatus, a high voltage power source for a dust collecting section for generating a square wave high voltage for improving the dust collecting performance is special and high in cost. In consideration of the fact that the voltage of the dust collecting section 105 which changes periodically becomes different from the voltage of the charging section 104, the spatial insulation distance between the charging section 104 and the dust collecting section 105 It was necessary to keep it large. For this reason, there has been a problem that the size of the electric dust collector is increased.

In addition, it is necessary to previously determine the applied voltage for the positive discharge electrode in the charging section 104 and simultaneously generate the positive charged dust at the same amount. Therefore, when the applied voltage is changed and the air flow rate is lowered, the energy saving operation for reducing the amount of charge is not performed.

The electrostatic precipitator of the present invention includes a charging unit provided with a positively charged negative electrode plate and a negatively charged negative electrode plate alternately arranged in parallel to each other and a charging electrode plate to which a voltage is applied and a grounded electrode plate to be grounded in parallel And a fan for ventilation from the charging section toward the dust collecting section. All the positive and negative electrode negative plates are formed of the front side of the needle shape and the electrode side surface (electrode side surface portion), and the sediment discharge portion of the positive electrode negative electrode plate is formed in a direction of ventilation It is placed on the wind side. In the charging section, the front surface of the positive electrification negative electrode plate and the electrode side surface of the negative electrification negative electrode plate are alternately shifted, and the electrode surface portion of the positive electrification negative electrode plate and the needle discharge portion of the negative electrification negative electrode plate are alternately shifted. The settling portion of the positive electrification negative electrode plate generates a positive corona at the electrode face portion of the negative electrification negative electrode plate having a lower relative potential than that of the positive electrode of the positive electrification negative electrode plate, The secondary corona is generated at the electrode surface of the positive electrode having a relatively high potential. The dust passing through the charging section is charged with the positive polarity, and the dust is collected on the entire surface of the charged electrode plate and the ground electrode plate of the dust collecting section.

Such an electric dust collecting apparatus can use a DC high voltage power source for a general dust collecting unit without using an expensive square wave high voltage power source, resulting in low cost. In addition, since the DC voltage of the same polarity can be used in the electric dust collector, the spatial insulation distance between the charging portion and the dust collecting portion can be made small and compact. In addition, since the electric dust collector does not need to uniformly determine the applied voltage uniformly in the form of hardware, the applied voltage is changed, and when the air flow rate is lowered, the amount of charge is reduced and energy- .

1 is a schematic view of an electric dust collector according to an embodiment of the present invention.
2 (a) is an external view of an electrostatic electrode plate of the same electrostatic precipitator.
2 (b) is a schematic side view of the charging part of the electrostatic precipitator.
2 (c) is a schematic bottom view of the electrified part of the electrostatic precipitator.
3 is a characteristic diagram of the dust collecting efficiency of Experimental Example 1 of the electrostatic precipitator.
4 is a characteristic diagram of the dust collecting efficiency of Experimental Example 2 of the electrostatic precipitator.
5 is a characteristic diagram of the dust collecting efficiency of Experimental Example 3 of the electrostatic precipitator.
6 (a) is a positional relationship of the electrode plate when the concave distance X of the electrostatic precipitator is small.
6 (b) is a positional diagram of the electrode plate when the concave distance X of the electrostatic precipitator is large.
Fig. 6 (c) is a positional diagram of the electrode plate when the adjacent electrification negative electrode plate of the electrostatic precipitator has no overlap with the wind direction. Fig.
7 is a characteristic diagram of the dust collecting efficiency of Experimental Example 4 of the electrostatic precipitator.
8 is a characteristic diagram of the dust collecting efficiency of Experimental Example 5 of the electrostatic precipitator.
9 is a characteristic diagram of the dust collecting efficiency in Experimental Example 6 of the electrostatic precipitator.
10 is a characteristic diagram of the dust collecting efficiency of Experimental Example 7 of the electrostatic precipitator.
11 is a characteristic diagram of the dust collecting efficiency of Experimental Example 8 of the electrostatic precipitator.
Fig. 12 is a principle of dust collection of a conventional electric dust collector.
13 is a principle of dust collection of another conventional electric dust collector.
Fig. 14 is a principle of dust collection of another conventional electric dust collector.
Fig. 15 is a diagram showing one configuration example of a charging section of a conventional electric dust collector. Fig.
16 is a view showing another configuration example of the charging section of the conventional electric dust collector.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiments)

1 is a schematic view of an electric dust collector according to an embodiment of the present invention. 1, the electric dust collector 30 sucks air in the room from the suction duct 11 and charges the dust 31, which is atmospheric dust in the charging section 13, The dust 31 is collected. The air containing the dust 31 is sucked by the fan 19.

The applied voltage to the positively charged positive electrode negative electrode plate 1c or negative charged negative electrode plate 1 which is negative charged negative electrode plate 1d is variable. The charging section 13 is provided with a positive charging negative electrode plate 1c and a negative charging negative electrode plate 1d alternately in parallel to charge the dust 31 positively or negatively.

The dust collecting unit 16 is provided with a charged electrode plate 2a to which a voltage is applied and a ground electrode plate 2b to be grounded alternately in parallel. The distance between the charged electrode plate 2a and the ground electrode plate 2b is constant at 10 mm. A constant DC voltage of 9 kV is applied to the positive and negative electrode plates 1c and 2a. Then, how the change in the condition of the charging section 13 affects the dust collecting efficiency is examined.

The fan 19 is ventilated from the charging section 13 toward the dust collecting section 16, and the number of revolutions can be varied by frequency control. The ventilation direction 32 is a direction from the charging section 13 to the dust collecting section 16. The hot-wire anemometer 14 measures the wind speed in the suction duct 11. [ In the charging section 13, the inner opening area is narrow. The power frequency of the fan 19 is finely adjusted so that the air velocity in the charging section 13 is constant at 9 m / s.

In the charging section 13, the voltages from the positive and negative high-voltage power supply 22 are switched and applied. The voltage from the constant voltage source 23 is applied to the discharge electrode plate 2a and the ground electrode plate 2b as the dust collecting electrode plate 2. The shape of the charged electrode plate 2a and the ground electrode plate 2b are the same in both the number and the number of uses.

The particle counter 15 is used for the measurement of the concentration of the dust 31. The concentration of the dust 31 is measured on the windward side 33 in the ventilation direction 32 of the charging section 13 and on the windward side 32 in the ventilation direction 32 of the dust collecting section 16 (34). The dust 31 having a particle diameter of 0.3 micron meter or more is used for calculating the dust concentration, and the dust collection efficiency is calculated.

Fig. 2 (a) is an external view of the charging negative electrode plate of the electric dust collector according to the embodiment of the present invention. All the charging negative electrode plates 1 have the same shape. The long side L of the charging negative electrode 1 is 100 mm, the short side W is 36 mm, and the plate thickness is 0.4 mm. All of the charging negative electrode plates 1 are formed of a needle-like precipitating portion 1e and an electrode surface portion 1f. The tip angle of the needle tip 1e is 30 degrees and the height S of the needle tip 1e is 10 mm. Three charging units 1e are arranged in one charging negative electrode plate 1 and an interval P between the charging units 1e is 12 mm. The material of the charging negative electrode 1 is SUS304.

Fig. 2 (b) is a schematic side view of the charging section of the electric dust collector according to the embodiment of the present invention, showing the principle of the charging section 13 for carrying out the corona discharge of the bipolar electric power. Here, the case where the charging negative electrode plate 1a is the positive charging negative electrode plate 1c and the charging negative electrode plate 1b is the negative charging negative electrode plate 1d will be described. As shown in Fig. 2 (b), the charging section 13 is provided on the wind-blowing side 33 of the negative charging negative electrode plate 1d with respect to the entire positive charging section 1d, (1e). The pre-charging front portion 1e of the positive charging negative electrode plate 1c and the electrode side surface portion 1f of the negative charging negative electrode plate 1d are alternately arranged. The end portion of the electrode surface portion 1f of the negative charging negative electrode plate 1d is disposed on the side 33 on the wind blowing side than the charging portion 1e of the positive charging negative electrode plate 1c. In addition, the pre-charging portion 1e of the negative charging negative electrode plate 1d and the electrode surface portion 1f of the positive charging negative electrode plate 1c are alternately arranged. The electrode surface portion 1f of the positive electrification negative electrode plate 1c is disposed on the side 34 where the wind is blown more than the acupressure front portion 1e of the negative electrification negative electrode plate 1d. The charging negative electrode plate 1b is grounded, and a positive DC high voltage is applied to the charging negative electrode plate 1a. The number of the charging negative electrode plates 1a is one less than that of the charging negative electrode plate 1b.

In this case, for example, when positive high voltage is applied to the charging negative electrode plate 1a, positive corona discharge occurs in the discharge space (discharge band S1) of the wind-blowing side 33, (Discharging zone S2) of the discharge cells (negative discharge cells). In other words, the pre-salient portion 1e of the positive high-potential negative electrode plate 1c generates a positive corona at the electrode surface portion 1f of the negative-negative electrode plate 1d having a relatively low potential. In addition, the pre-charging portion 1e of the negative charging negative electrode plate 1d having a relatively low potential generates a negative corona at the electrode surface portion 1f of the positive charging negative electrode plate 1c having a relatively high potential. Further, by applying a negative high voltage to the charging negative electrode plate 1a, the generation position of the positive corona and the negative corona may be switched. 1, the dust 31 is collected on the entire surfaces of the lower electrode plate 2a and the ground electrode plate 2b of the dust collecting portion 16. [

Fig. 2 (c) is a schematic bottom view of the charging part of the electric dust collector according to the embodiment of the present invention. The tip of the needle 1e is represented by a double circle. The interval between the adjacent charging negative electrode plates 1 is G [mm]. The length of the front end of the front portion 1e which is recessed from the end of the adjacent charging negative electrode 1 is the concave distance X [mm]. The same applies to the concave distance X of the charging negative electrode plate 1b. In addition, the distance between the tip ends of the needle points 1e of the adjacent charging negative electrode plates 1 is Y [mm]. Y is changed by changing the height S of the entire depression 1e, or changing L.

Experimental conditions were 10 cases, 10 cases, 15 cases, 20 cases. In addition, six cases of 10 mm, 20 mm, 35 mm, 50 mm, 65 mm and 75 mm were prepared. However, for G10 (G = 10 mm), X05 (X = 5 mm) was also tested.

(Experimental Example 1)

3 is a characteristic diagram of the dust collecting efficiency of Experimental Example 1 of the electric dust collector according to the embodiment of the present invention. 3 shows an experimental result in the case of X35 (X = 35 mm) and shows the efficiency of dust collection (the efficiency with which the dust 31 introduced into the charging section 13 is collected by the dust collecting section 16) . The solid line indicates a positive corona at the windward side 33 shown in FIG. 1, and a case where a negative corona occurs at the windward side 34 (measurement corona that blows wind). On the other hand, the dashed line indicates a case where a sub-corona is formed on the wind-driven side 33 shown in Fig. 1 and a positive corona occurs on the wind-blowing side 34 (side corona that blows wind).

The combination of G and number is a case where the interval between adjacent electrification negative electrode plates 1 is 10 mm, 15 mm, and 20 mm. In all of these six cases, the power consumption of the corona discharge is increased and the dust collecting efficiency is increased, which is a normal tendency. However, in the case where a negative voltage is applied to the entire acupuncture portion 1e toward the opposite side of the dust collecting portion 16 (hereinafter referred to as the half dust collecting portion side) in the ventilation direction 32 shown in Fig. 1 (Positive corona in which the wind is blown) than in the case where a positive voltage is applied to the entire acupuncture portion 1e directed to the half dust collecting portion side (the wind blowing side 33) So that the dust collecting efficiency tends to be good. This tendency is also true under the conditions of X20, X50, X65, and X75.

The reason for this is thought to be the promotion of ionization by the " gamma (gamma) action ", although it has not yet been completely clarified. The gamma action is represented by, for example, Yasunori Miyoshi, "Evolution of Gas" (Material Science Magazine Vol. 8, No. 1 (March 1971), page 34). The point is that when a positive ion collides with a negative discharge portion, the secondary electron emission from the sub-discharge portion and the ionization become active so that the secondary ion is likely to be generated. This is considered by applying it to the charging process which is the initial process of electrostatic dust collection.

That is, the dust 31 is positively charged by the positive corona discharge at the windward side 33 shown in FIG. 1, and the dust 31 charged positively and the remaining positive ions not contributing to the charge Is introduced into the secondary corona discharge space of the blowing side (34). In this case, the remaining positive ions collide with the sub-bipolar part to cause a? Action, so that generation of negative ions becomes active. That is, the dust 31 charged in the sub-corona discharge region of the wind-blowing side 34 increases, and as a result, the dust collection efficiency is improved. That is, in the opposite case, that is, when the wind-blowing side 33 discharges the sub-corona, even if negative ions collide with the whole front side of the wind-blowing side 34, no gamma action is caused.

As for the detailed mechanism of the corona discharge, there remains an unknown part in the academic arts. However, it is true that "when the positive corona occurs at the discharge part of the wind blowing side, the collection efficiency is clearly better than when the negative corona occurs at the discharge part of the wind blowing side".

That is, in the charging section 13, positive corona discharge and negative corona discharge occur at the same time. Then, the positive corona discharge is generated at the windward side 33 rather than the negative corona discharge, whereby the electric dust collector 30 having high dust collecting efficiency can be obtained.

In addition, the number of all the acupuncture needles 1e of the charging negative electrode plate 1 is not limited to three but may be one or more.

In addition, the number of all the salivating portions 1e of the charging negative electrode 1 may not be all the same.

The tip angle of the acupuncture sensitive portion 1e of the charging negative electrode 1 may be about 10 degrees to about 40 degrees even if the tip angle is not 30 degrees.

In addition, S may be not more than 10 mm but may be about 5 to 20 mm.

Further, P may be about 4 mm to 20 mm even if it is not 12 mm.

Further, the plate thickness of the charging negative electrode 1 is not limited to 0.4 mm but may be about 0.2 mm to 1.5 mm.

The material of the charging negative electrode 1 is not limited to SUS304, but may be a flat plate-like metal.

The size of the charging negative electrode 1 may not be 100 mm x 36 mm.

The direction of the tips of the needles is not limited to the examples shown in Figs. 1 and 2, but is set to a positive voltage applied to the wind-blowing side 33 rather than the all of the shoulder 1e applied with a negative voltage The same effect can be obtained by disposing the front portion 1e.

(Experimental Example 2)

4 is a characteristic diagram of the dust collecting efficiency of Experimental Example 2 of the electric dust collector according to the embodiment of the present invention. 4 is a characteristic of the dust collecting efficiency when the power consumed in the corona discharge of the charging section 13 is constant and the gap G between adjacent charging negative electrode plates 1 is changed. In Experimental Example 1, since experimental conditions are described in detail, overlapping description is omitted.

The power consumption was 1.3W, 2.0W, and 2.8W. The concave distance was set to X = 35 mm.

As the G increases, the dust collection efficiency increases, but when G increases further, the dust collection efficiency decreases. Generally, the larger the power consumption, the better the dust collecting efficiency. Here, when G is in the range of approximately 10 mm to 20 mm, the dust collecting efficiency is increased. This tendency is also true under the conditions of X20, X50, X65, and X75.

That is, when the gap G between the adjacent charging negative electrode plates 1 is 10 mm or more and 20 mm or less in the charging section 13, the electric dust collector 30 having high dust collection efficiency can be obtained.

(Experimental Example 3)

5 is a characteristic diagram of the dust collecting efficiency of Experimental Example 3 of the electric dust collector according to the embodiment of the present invention. 5 shows the dust collection efficiency when the concave distance X is changed when G is G10, G15, and G20. Power consumption is constant at 2.0W. In Experimental Example 1, since experimental conditions are described in detail, overlapping description is omitted.

When X is 20 mm or more, the dust collecting efficiency is high and stable. This tendency is the same under the conditions of the power consumption of 1.3W and 2.8W.

Fig. 6 (a) is a positional relationship of the electrode plate when the concave distance X of the electric dust collector of the embodiment of the present invention is small, and Fig. 6 (b) And Fig. 6 (c) is a positional diagram of the electrode plate when the adjacent electrification negative electrode plate of the electrostatic precipitator has no overlap with the wind direction. In FIG. 6 (a), the value of X is small, and the discharge band S1 of the wind-up side 33 and the discharge band S2 of the wind-blowing side 34 are shown separately. As shown in Fig. 6 (b), even if X is larger, the discharge bands S1 and S2 are similarly displayed separately. 6 (c), the value of X becomes larger, and the tip of the projection 1e of the charging negative electrode plate 1a is longer than the tip of the projection 1e of the charging negative electrode plate 1b When the air is blown on the windward side 34, the discharge band S1 and the discharge band S2 become the same space, and the charging efficiency to the dust 31 is lowered. Thus, for the optimum concave distance X, there is a range.

As described above, in the charging section 13, the protrusion tip of the all-saline discharge section 1e, which has the X of 20 mm or more and is directed to the wind-blowing side 33, (33) than the tip of the protrusion of the first housing (1e). As a result, the electric dust collector 30 having high dust collection efficiency can be obtained.

(Experimental Example 4)

7 is a characteristic diagram of the dust collecting efficiency of Experimental Example 4 of the electric dust collector according to the embodiment of the present invention. Fig. 7 shows the dust collecting efficiency when G is changed and Y is changed. In Experimental Example 1, since experimental conditions are described in detail, overlapping description is omitted.

The constant power consumption is three cases of 1.3W, 2.0W, and 2.8W. As shown in Fig. 7, when Y is increased, the dust collecting efficiency is increased, but when Y is about 60 mm or more, the dust collecting efficiency is saturated. This tendency is also true for the conditions of G10 and G20.

6, since the discharge band S1 and the discharge band S2 are not formed unless the all-needle preinsection 1e is positioned on the vertical projection plane of the adjacent electrifying negative electrode plate 1, The efficiency is lowered. Therefore, there is a range in the optimum Y.

That is, in the charging section 13 shown in Fig. 1, the protrusion tip of the acupunture front portion 1e toward the semi-collecting section side (the wind blowing side 33) The distance from the front end of the projection part 1e to the projection part 16 side (hereinafter referred to as the dust collecting part side (blowing side 34)) is 60 mm or more. The tip of the protrusion of the acupuncture preventing portion 1e toward the dust collecting portion side (the wind blowing side 34) may be located within the length of the adjacent electrode surface portion 1f in the ventilation direction 32. [ As a result, the electric dust collector 30 having high dust collection efficiency can be obtained.

(Experimental Example 5)

8 is a characteristic diagram of the dust collecting efficiency of Experimental Example 5 of the electric dust collector according to the embodiment of the present invention. Fig. 8 shows the dust collecting efficiency when the power consumption per one piece of the suction portion 1e is changed. In Experimental Example 1, duplicate description is omitted because experimental conditions are described in detail.

X was 65 mm. As shown in Fig. 8, even if G is changed, the power consumption becomes high, and the dust collecting efficiency becomes high. However, if the power consumption exceeds 130 mW, the applied voltage value becomes high, and spark discharge (spark) occurs frequently, so that dust collection becomes impossible. Therefore, when the power consumption per one unit of the precipitating portion 1e is in the range of approximately 40 mW to 130 mW, good collecting efficiency can be obtained. This tendency is also true under the conditions of X20, X35, X50, and X75. Here, although G is set to 10 mm to 20 mm in the present invention, if G is small, flame is easily discharged and the resistance at the time of blowing becomes large, which is not practical. In addition, if G is large, a large voltage is required to discharge, which leads to a problem of insulation.

That is, in the charging section 13 shown in Fig. 1, when G is 10 mm to 20 mm, the power consumption per one acupuncture section 1e is set to 40 mW or more and 130 mW or less, The electric dust collector 30 is obtained.

(Experimental Example 6)

9 is a characteristic diagram of the dust collecting efficiency of Experimental Example 6 of the electric dust collector according to the embodiment of the present invention. Fig. 9 shows the dust collecting efficiency when the average discharge current per one acupuncture portion 1e is changed. In Experimental Example 1, since experimental conditions are described in detail, overlapping description is omitted.

X was 65 mm. G was G10, G15, and G20. If the average discharge current exceeds 5 占 어 even though G is changed, the dust collecting efficiency becomes high. If the average discharge current exceeds 8 mu A, the applied voltage value becomes high, and spark discharge (spark) occurs frequently, so that dust collection becomes impossible. Therefore, when the average discharge current is approximately in the range of 5 [micro] A to 8 [micro] A, good dust collection efficiency is obtained. This tendency is also true under the conditions of X20, X35, X50, and X75.

That is, in the charging unit 13 shown in Fig. 1, if G is 10 mm to 20 mm, and the average discharge current per one acupuncture unit 1e is 5 mu A or more and 8 mu A or less, (30) is obtained.

(Experimental Example 7)

10 is a characteristic diagram of the dust collecting efficiency of Experimental Example 7 of the electric dust collector according to the embodiment of the present invention. Fig. 10 shows experimental results of measuring the dust collecting efficiency by changing the ratio of the power consumption of the static corona to the total power consumption. The abscissa indicates the percentage of the power consumed by the normal corona from the total power consumption (the sum of the power consumption of the positive corona and the sub corona). In this experiment, the positive corona discharge is generated by the all-needle discharge portion 1e toward the half dust collection portion (wind-blowing side 33), and all the saliva discharge toward the dust collecting portion side (wind-blowing side 34) 1e) caused a negative corona discharge. In Experimental Example 1, since the experiment conditions are described in detail, the overlapping technique is omitted and only the other portions are described.

Originally, when the positional relationship between the shapes of the charging negative electrode plate 1a and the charging negative electrode plate 1b shown in Fig. 1 is determined and the applied voltage is determined, the current value of the positive corona discharge and the current value of the sub- It is determined by intention. That is, the ratio of the power consumption of the static corona discharge to the power consumption of the sub-corona discharge is generally a constant ratio. However, when the number of the needle tip portions 1e of the charging negative electrode plate 1a and the number of needle tip portions 1e of the charging negative electrode plate 1b are changed, the power consumption of the positive corona discharge and the power consumption of the sub- The ratio can change freely. That is, it is possible to determine whether the dust collecting efficiency is improved when the power consumption of the static corona discharge is about several percent of the total power consumption (the sum of the power consumption of the static corona and the sub-corona).

Thus, in the experimental method, the electrode plate in which the charging negative electrode plate 1a and the charging negative electrode plate 1b were each divided into two pieces (cut) in the vertical direction was used. Then, a positive high voltage is applied to the entire acupuncture point 1e toward the half dust collecting part side (the wind blowing side 33) shown in Fig. 1, and the saline solution toward the dust collecting part side (wind blowing side 34) A negative high voltage was applied to the entire portion 1e. That is to say, the power consumption of the normal corona of the entire acupuncture portion 1e toward the half dust collecting portion side (windward side 33) and the power consumption of the entire acupuncture portion 1e toward the dust collecting portion side (windward side 34) The power consumption of the sub-corona of the sub-corona can be changed freely (forcibly). Then, the total power consumption of the normal corona and the sub corona was kept constant, and the power consumption of the corona and the sub corona was varied. Fig. 10 shows the result of this experiment. G is 15 mm, and X is 35 mm. Total power consumption is constant at 1.3W. Fig. 10 shows the characteristics of the acid type. Particularly, when the ratio of the power consumption of the static corona in the total power consumption is in the range of about 10% to about 50%, high dust collection efficiency is exhibited. This tendency is also true under the conditions of G10 and G20, and also under the conditions of X20, X50, X65, and X75. Also, the total power consumption value to be constant may be a value other than 1.3W.

That is, in the charging section 13 shown in Fig. 1, electric power is supplied so that the power consumption of the forward corona becomes 10% or more and 50% or less with respect to the total electric power consumption, whereby the electric dust collector 30 of high dust collection efficiency .

(Experimental Example 8)

11 is a characteristic diagram of the dust collecting efficiency of Experimental Example 8 of the electric dust collector according to the embodiment of the present invention. 11 shows the dust collection efficiency characteristics with respect to the power consumption when X is in the range of 5 mm to 10 mm. G is 10 mm, 15 mm, and 20 mm. In Experimental Example 1, since experimental conditions are described in detail, overlapping description is omitted.

In the case where a negative voltage is applied to the acupuncture resistive portion 1e toward the half dust collecting portion side (wind side 33), as shown in Fig. 11, the power consumption is increased and the dust collecting efficiency is increased. However, when a constant voltage is applied to the entire acupuncture point 1e toward the half dust collecting part side (wind side 33), the power consumption is increased and the dust collecting efficiency is lowered. Further, when X is not less than 5 mm and not more than 10 mm, the application of the negative voltage to the pre-precipitating portion 1e toward the half dust collecting portion side (the wind blowing side 33) Efficiency is obtained. This is because the value of X is small, so that the discharge from the tip of the all-needle discharge portion 1e and the reverse discharge from the electrode surface portion 1f of the adjacent charging negative electrode plate 1 interfere with each other, It can be considered that the dust collection efficiency is achieved.

That is to say, the charging section 13 generates a negative corona discharge from the tip of the charging section 1e of the charging negative electrode plate 1a and discharges the positive corona discharge from the tip of the charging section 1e of the charging negative electrode plate 1b The following conditions are preferable. That is, the tip end of the acupuncture preventing portion 1e toward the half dust collecting portion side (the wind blowing side 33) is extended to the wind blowing side 34 from the adjacent electrode surface portion 1f by 5 mm to 10 mm Or less.

(Industrial availability)

The present invention is useful for an electrostatic precipitator in which a static corona discharge and a sub-corona discharge are generated in the same charging portion.

1: Charging negative electrode plate
1a: a charging negative electrode (with the leading end of the sedimentation front facing away from the dust collecting portion in the direction of ventilation)
1b: (the tip of the needle at the front of the dust collecting part in the ventilation direction)
1c: Positive charging negative electrode plate
1d: negative charging negative plate
1e: All of the saliva
1f: electrode surface
2: Dust collector plate
2a: charge electrode plate
2b: Grounding plate
11: Suction duct
13:
14: Hot wire anemometer
15: Particle counter
16: Dust collector
19: Fans
22: High voltage power source
23: High voltage power source
30: Electrostatic precipitator
31: Dust
32: Direction of ventilation
33: Wind blowing side
34: Wind blowing side
S1: discharge band
S2: discharge band

Claims (10)

A charging unit in which a positive charging electrode and a negative charging electrode are alternately and parallelly charged by applying a direct current high voltage and a negative charging plate to which a voltage is applied and a grounding electrode plate that is grounded, A dust collecting apparatus comprising: a dust collecting unit alternately provided in parallel; and a fan for ventilating the charging unit toward the dust collecting unit,
All of the positive and negative electrode negative electrode plates and the negative electrode negative electrode plate are formed of a needle-like precipitate front portion and an electrode surface portion (electrode surface portion)
Wherein the sedimentary discharge portion of the positive electrification negative electrode plate is disposed on a side where the wind is blown in the direction of the ventilation than the entire acupressure portion of the negative electrification negative electrode plate,
And the electrode surface portion of the negative electrification negative electrode plate is disposed so as to be alternately shifted from the electrode surface portion of the positive electrification negative electrode plate to the needle surface of the negative electrification negative electrode plate, The discharge portions are alternately arranged to be shifted,
The tip end of the projection of the entire positive electrode negative electrode plate is displaced by 20 mm or more from the side of the electrode face portion of the adjacent negative electrode negative plate to the wind side of the adjacent electrode plate, Is positioned on the side where the wind blows from the tip of the projection,
Wherein the sedimentary discharge portion of the positive electrification negative electrode plate generates a positive corona to the electrode side face portion of the negative electrification negative electrode plate having a lower potential than that of the positive side of the positive electrification negative electrode plate,
Discharge portion of the negative charging negative electrode plate generates a negative corona at the electrode surface portion of the positive charging negative electrode plate having a relatively higher potential than that of the negative charging negative electrode plate,
The dust passing through the charging section is charged with positive (positive) and negative (positive) charges, and the dust is collected on the entire surface of the charged electrode plate and the ground electrode plate of the dust collecting section
And the electric dust collecting device.
The method according to claim 1,
And the interval between the adjacent positive static negative electrode and the negative static negative electrode is 10 mm or more and 20 mm or less
And the electric dust collecting device.
delete 3. The method of claim 2,
Wherein a distance between a tip end of the projection on the front side of the positive charging negative electrode and a tip end of the projection on the negative charging negative electrode plate is 60 mm or more and a tip end of the projection on the negative charging negative plate And the tip of the projection of the all of the needle on the positive electrification negative plate is located within the length of the electrode face of the adjacent positive electrification negative plate in the direction of the ventilation, Those located within the length of the electrode surface portion
And the electric dust collecting device.
3. The method of claim 2,
The average power consumption per one set of the above precipitates is 40 mW or more and 130 mW or less
And the electric dust collecting device.
3. The method of claim 2,
The average discharge current per one set of the above-mentioned precipitates is 5 ㎂ to 8 것
And the electric dust collecting device.
The method according to claim 1,
The ratio of the power consumption by the normal corona in the total power consumption of the charging portion is 10% or more and 50% or less
And the electric dust collecting device.
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