KR20180038504A - Electrostatic precipitator and exhaust gas purification system - Google Patents

Abstract

According to the present invention, if there is a protruding portion of a visible shape on the discharge electrode, the corona discharge occurs between the protruding portion of the visible shape of the discharge electrode and the counter electrode. Therefore, when the electrostatic dust precipitator is operated for a long period of time, erosion of the counter electrode may proceed in a specific spot of the counter electrode corresponding to the protruding portion of the visual appearance. And a second electrode plate that is provided to face the first electrode plate and has an end located inside the end of the first electrode plate, and the second electrode plate has a structure in which the end has no protruding portion , And an electrostatic precipitator.

Description

Electrostatic precipitator and exhaust gas purification system

TECHNICAL FIELD [0001] The present invention relates to an electrostatic precipitator and an exhaust gas purifying system.

[0002] Electrostatic precipitators have been used for trapping fine particles in exhaust gas in various areas such as various plants and tunnels. Conventionally, in an electrostatic precipitator in which a flat plate-like discharge electrode and a flat plate-like counter electrode are opposed to each other, the discharge electrode has a protruding portion in a visible shape at an end portion like a saw blade (for example, see Patent Document 1) . The discharge electrode generates a corona discharge between the protruding portion of the visible shape and the counter electrode, and charges the fine particles by corona discharge. The electrode for collecting collected the charged fine particles by a Coulomb force (see, for example, Patent Document 1).

Japanese Patent No. 2971461

The corona discharge occurs between the protruding portion of the visible shape of the discharge electrode and the counter electrode. Therefore, when the electrostatic precipitator is operated for a long period of time, erosion of the counter electrode may progress in a specific spot of the counter electrode corresponding to the protruding portion of the visual appearance.

(General Disclosure of the Invention) The electrostatic dust precipitator may include a first electrode plate and a second electrode plate. The second electrode plate may be provided opposite to the first electrode plate. The end portion of the second electrode plate may be located inside the end portion of the first electrode plate. The end portion of the second electrode plate may not have a protruding portion.

[0005] The second electrode plate may have a flat flat plate shape. The second electrode plate may have a radius of curvature of at least half of a gap between the first electrode plate and the second electrode plate in all regions.

[0006] The second electrode plate may be in the form of a flat plate including a linear portion and a corner portion having a radius of curvature.

[0007] The second electrode plate may have a disc shape.

[0008] The second electrode plate may have at least one through-hole.

[0009] The at least one through opening may include a plurality of independent through openings.

[0010] The at least one through-opening may have a central opening and a peripheral opening. The central opening may be the largest. The peripheral opening portion may have a smaller opening area than the central opening portion. The peripheral opening may be arranged around the central opening.

[0011] The second electrode plate may have at least one through-hole. At least one of the at least one through-opening may have an edge protruding toward the first electrode plate.

[0012] A plurality of through openings having edge portions protruding toward the first electrode plate may be provided. The length at which the edge portion protrudes may be different on the upstream side and the downstream side of the gas introduced into the electrostatic precipitator.

[0013] The length of the edge portion protruding may be longer on the upstream side than on the downstream side.

[0014] A plurality of first units each having a first electrode plate and a second electrode plate may be stacked.

The gap length between the first electrode plate and the second electrode plate at the end portion in the stacking direction of the plurality of stacked first units is determined by the gap length between the first electrode plate and the second electrode plate at the central portion in the stacking direction of the plurality of stacked first units May be larger than the gap length between the second electrode plates.

[0016] The electrostatic precipitator may further comprise a second unit. The second unit may have a third electrode plate and a fourth electrode plate. The fourth electrode plate may be provided so as to face the third electrode plate. The end portion of the fourth electrode plate may be located inside the end portion of the third electrode plate. The end portion of the fourth electrode plate may have a protruding portion. The second unit may be provided at least at both ends of the plurality of stacked first units in the stacking direction.

The exhaust gas purifying system may include a scrubber and the above-described electrostatic precipitator. The scrubber may purify the exhaust gas. The electrostatic precipitator may be installed upstream of the scrubber.

The above summary of the invention does not list all the necessary features of the present invention. In addition, a sub combination of these feature groups may also be an invention.

1 is a perspective view showing a configuration of an electrostatic precipitator 200 of the first embodiment.
2 is a cross-sectional view showing the configuration of the electrostatic precipitator 200 of the first embodiment.
3 is a top view of AA 'in FIG. 2. FIG.
4 is a view showing the shape of the discharge electrode 100 of the second embodiment.
5 is a view showing the shape of the discharge electrode 100 of the third embodiment.
6 is a view showing the shape of the discharge electrode 100 of the fourth embodiment.
7 is a view showing the shape of the discharge electrode 100 of the fifth embodiment.
8 is a view showing the shape of the discharge electrode 100 of the sixth embodiment.
9 is a view showing the shape of the discharge electrode 100 of the seventh embodiment.
10 is a view showing the shape of the discharge electrode 100 of the eighth embodiment.
11 is a sectional view of the discharge electrode 100 of the eighth embodiment viewed from the side direction.
12 is a view showing the shape of the discharge electrode 100 of the ninth embodiment.
13 is a sectional view of the discharge electrode 100 of the ninth embodiment viewed from the side direction.
14 is a perspective view showing a configuration of the electric dust collector 200 of the tenth embodiment.
15 is a perspective view showing the configuration of the electrostatic precipitator 200 of the eleventh embodiment.
16 is a perspective view showing the configuration of the electrostatic precipitator 200 of the twelfth embodiment.
17 is a perspective view showing the configuration of the electrostatic precipitator 200 of the thirteenth embodiment.
18 is a diagram showing an outline of the exhaust gas purifying system 400. As shown in Fig.

Hereinafter, the present invention will be described through embodiments of the present invention. However, the following embodiments do not limit the invention according to the claims. It should be noted that not all of the combinations of the features described in the embodiments are essential to the solution of the invention.

In this specification, the technical matters will be described using the orthogonal coordinate axes of the X-axis, the Y-axis and the Z-axis. The orthogonal coordinate axes specify the relative positions of the constituent elements, and do not limit the specific directions. For example, the Z axis does not limit the height direction to the ground. The + Z axis direction and the -Z axis direction are opposite to each other. When positive and negative signs are not described, and the Z axis direction is described, it means a direction parallel to the + Z axis and the -Z axis. In this specification, "straight line" is assumed to have infinite radius of curvature.

1 is a perspective view showing a configuration of an electric dust collector 200 of the first embodiment. The electrostatic precipitator 200 collects the particulates in the exhaust gas. The fine particles include soot and dust. The electrostatic precipitator 200 has a counter electrode 10-1 and a discharge electrode 100. [ The counter electrode 10-1 as the first electrode plate is an electrode plate having a GND potential, which is also called a GND electrode. The discharge electrode 100 as the second electrode plate is a high-potential electrode plate. The discharge electrode 100 is provided so as to face the counter electrode 10-1.

The electrostatic precipitator 200 of this embodiment has the counter electrode 10 - 2 in addition to the counter electrode 10 - 1 and the discharge electrode 100. The counter electrode 10-1 and the counter electrode 10-2 are disposed so as to sandwich the discharge electrode 100. [ Thereby, the corona discharge 2 can be generated at the end portions 102 on both sides of one discharge electrode 100. However, unlike the present example, the electrostatic precipitator 200 may be formed of only the counter electrode 10-1 and the discharge electrode 100. [

In order to make the gap length in the Z direction from the discharge electrode 100 to the counter electrode 10-1 equal to the gap length in the Z direction from the discharge electrode 100 to the counter electrode 10-2, The counter electrode 10-1, the discharge electrode 100, and the counter electrode 10-2 may be stacked in the Z direction. The counter electrode 10-1, the counter electrode 10-2, and the discharge electrode 100 may be arranged parallel to the XY plane.

The counter electrode 10-1 and the counter electrode 10-2 (hereinafter sometimes referred to as the counter electrode 10) and the discharge electrode 100 have a flat flat plate shape. The thickness of the counter electrode 10 and the discharge electrode 100 may be 1 mm or more and 2 mm or less. The plate area of the counter electrode 10 and the discharge electrode 100 may be 0.3 m2 or more and 3 m2 or less. For example, the counter electrode 10 and the discharge electrode 100 are flat plates of about 1 m x 1 m. However, the area of the discharge electrode 100 is smaller than the area of the counter electrode 10. The material of the counter electrode 10 and the discharge electrode 100 may be stainless steel material such as SUS304 according to the JIS standard.

The counter electrode 10 of this embodiment has a rectangular shape. The counter electrode 10 of this example has an end portion 12. The end 12 includes four sides 14 of a right-angled rectangle. Here, the term " end portion " means an end portion in a direction parallel to the XY plane. However, unlike the present example, the counter electrode 10 may have any shape such as a polygonal shape, a circular shape, and an elliptical shape. The discharge electrode 100 of this embodiment has a shape that can be approximated by a rectangular square. The discharge electrode (100) has an end portion (102). The end portion 102 of the discharge electrode 100 is positioned inside the end portion 12 of the counter electrode 10. As shown in Fig. 1, the end portion 102 of the discharge electrode 100 does not include a projected portion such as a visible shape.

A negative high voltage is applied to the discharge electrode 100 of the present example by the DC power supply 20. The counter electrode 10 is grounded. As a result, a high electric field area is formed between the discharge electrode 100 and the counter electrode 10.

Unlike the present embodiment, when the discharge electrode 100 has a protruding portion such as a spiral or the like, the position where the corona discharge 2 is generated is located immediately below (directly below) the protruding portion or directly above . When the electrostatic precipitator 200 is operated for a long period of time, particulates such as dust locally are likely to deposit locally on the counter electrode 10 immediately below or above the protruding portion of the discharge electrode 100 . Deposition of the fine particles shortens the gap length between the discharge electrode 100 and the counter electrode 10. As a result, at a portion where the gap length is short, the electric field becomes higher than other portions, and the electric field required for the transition to the spark (spark discharge) is more likely to be exceeded. If the spark occurs, the counter electrode 10 may be easily eroded.

When the charged fine particles are attracted to and deposited on the counter electrode 10 having a different potential, a back discharge occurs. When the generation position of the corona discharge 2 is fixed and the charged fine particles locally accumulate at a constant position, reverse discharge occurs at a constant position. If the counter discharge is generated at a constant position in a normal state, the counter electrode 10 may be partially damaged. In order to suppress such a state, it is necessary to clean the discharge electrode 100 and the counter electrode 10 regularly to remove fine particles, which increases the burden of maintenance.

On the other hand, according to this example, since the protruding portion of the discharge electrode 100 is absent, the generation position of the corona discharge 2 is not fixed to a specific spot. Therefore, the corona discharge 2 can be generated over the entire linear region corresponding to the side of the end portion 102 of the discharge electrode 100. Even if the corona discharge 2 is formed in a spot shape, the spot of the corona discharge 2 can be moved in a linear region without being fixed at one place. Therefore, the erosion of the counter electrode 10 can be prevented from progressing locally. It is also possible to suppress deposition of fine particles such as dust locally in the discharge electrode 100 and the counter electrode 10 even when the electrostatic precipitator 200 is operated for a long period of time. As a result, it is possible to prevent the gap length between the discharge electrode 100 and the counter electrode 10 from changing due to the deposition of the fine particles, so that the occurrence of sparks can be suppressed. Further, since the particulates are not deposited locally, the influence of the reverse discharge can also be reduced.

2 is a cross-sectional view showing a configuration of the electrostatic precipitator 200 of the first embodiment. By the corona discharge 2, the fine particles in the exhaust gas are negatively charged between the discharge electrode 100 and the counter electrode 10. The negatively charged fine particles are collected by the counter electrode 10 by the Coulomb force.

FIG. 3 shows a top view of the section taken along the line A-A 'in FIG. 2. The discharge electrode 100 includes a straight portion 104 and an edge portion 106 as an end portion 102. [ The case where the end portion 102 of the discharge electrode 100 does not have a protruding portion includes a case where the end portion 102 of the discharge electrode 100 can be approximated by a polygon such as a quadrangle, a pentagon and a hexagon. The end portion 102 of the discharge electrode 100 may have a shape in which a rectilinear portion 104 corresponding to a side of a polygon and a corner portion 106 obtained by smoothing a portion of a vertex with a curved line are connected. The corner portion 106 has a radius of curvature of half or more of the gap length d between the counter electrode 10 and the discharge electrode 100. The discharge electrode 100 of this example has a radius of curvature of at least half the gap length d in all regions.

All of the corner portions 106 of the discharge electrode 100 may have a shape approximate to the shape of an arc-shaped Rogowskii electrode. Thereby, it is possible to alleviate the electric field concentration at the corner portion 106. The Rogowski electrode is an electrode in which a quasi-equal electric field having a magnitude of almost the same electric field is formed in the corner portion 106 and the straight portion 104. According to the discharge electrode 100 of this example, a quasi-uniform electric field can be formed by alleviating the end effect (edge effect) of the parallel flat plate electrodes, and the corona discharge (2) can be prevented from concentrating.

FIG. 4 is a view showing the shape of the discharge electrode 100 of the second embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 of the second embodiment is the same as the electrostatic precipitator 200 of the first embodiment except for the shape of the discharge electrode 100. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals. The discharge electrode 100 of this example is a rectangular square. R (round) chamfer is not applied to the corner portion 106. [ Therefore, the manufacturing process of the discharge electrode 100 can be simplified.

Also in the present example, the end portion 102 of the discharge electrode 100 does not have a protruding portion. In this example, the end portion 102 of the discharge electrode 100 does not necessarily have a radius of curvature of half or more of the gap length d in all regions. The discharge electrode 100 of the present embodiment can reduce the phenomenon that the generation position of the corona discharge 2 is fixed as compared with the case where the discharge electrode 100 has a protruding portion such as a visible shape. Also, unlike the present example, the shape of the discharge electrode 100 may be a convex polygon such as a pentagon and a hexagon which are not R-chamfered.

FIG. 5 is a view showing the shape of the discharge electrode 100 of the third embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 of the third embodiment is the same as the electrostatic precipitator 200 except for the shape of the discharge electrode 100 in the first and second embodiments. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

The discharge electrode 100 of this example is in the form of a disk. That is, the end portion 102 of the discharge electrode 100 is circular. The case where the end portion 102 of the discharge electrode 100 does not have a protruding portion includes a case in which the end portion 102 of the discharge electrode 100 is formed of a closed curve such as a circle and an ellipse . In this example, the radius of the discharge electrode 100 is larger than the gap length d in the Z direction between the counter electrode 10 and the discharge electrode 100. Therefore, the discharge electrode 100 has a radius of curvature of at least half the gap length d in all regions.

According to this example, the end portion 102 of the discharge electrode 100 is formed with a curve having the same radius of curvature. Therefore, the generated electric field is substantially the same regardless of the position in the end portion 102. [ Therefore, the corona discharge 2 can be uniformly generated over the entirety of the end portion 102 of the discharge electrode 100 without being affected by the corner portion 106. [ The spot of the corona discharge 2 can be randomly moved along the circular end 102 without being fixed at one place even when the corona discharge 2 is formed in a spot shape. Therefore, the occurrence of spark can be suppressed and the erosion of the discharge electrode 100 can be delayed.

FIG. 6 is a view showing the shape of the discharge electrode 100 of the fourth embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 according to the fourth embodiment is the same as the electrostatic precipitator 200 according to the first embodiment except that the discharge electrode 100 has the through-hole 110. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

The edge portion 112 of the through-hole 110 may have a polygonal shape in which chamfered R is formed at a corner portion. The edge portion 112 includes a straight edge portion 114 corresponding to four sides of a rectangular shape and a corner edge portion 116 obtained by smoothing a portion of the corner point with a curved line. The edge portion 116 has a radius of curvature of at least half the gap length d between the counter electrode 10 and the discharge electrode 100. Therefore, the discharge electrode 100 of the present embodiment is formed so as to cover not only the end portion 102 but also the central region including the edge portion 112 of the through-hole portion 110, And has a radius of curvature.

When the high electric field area is formed between the discharge electrode 100 and the counter electrode 10 in this example, not only the end portion 102 of the discharge electrode 100 but also the edge portion of the through hole 110 The corona discharge 2 can be generated also in the corona discharge cell 112. Therefore, by using the discharge electrode 100 having the through-hole 110, the position where the corona discharge 2 is generated can be reduced compared to the case of using the discharge electrode 100 having no through-hole 110 I can increase it. Therefore, in this embodiment, the collecting amount per unit area (collecting efficiency) of the electrostatic precipitator 200 can be improved as compared with the first to third embodiments.

6 shows a case where the edge portion 102 of the discharge electrode 100 and the edge portion 112 of the through opening 110 have a polygonal shape in which R chamfering is applied to the corner portions. However, the discharge electrode 100 of this embodiment is not limited to this case, and may have a through-hole 110 having a shape different from the shape of the end portion 102 of the discharge electrode 100.

FIG. 7 is a view showing the shape of the discharge electrode 100 of the fifth embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 according to the fifth embodiment is the same as the electrostatic precipitator 200 according to the third embodiment except that the discharge electrode 100 has the through-hole 110 as compared with the electrostatic precipitator 200 according to the third embodiment. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

In this example, the edge portion 112 of the through-hole 110 has a circular shape. The edge portion 112 of the through-hole 110 may have an elliptical shape or other shapes. By using the discharge electrode 100 having the through-hole 110 in this example, compared with the case of using the discharge electrode 100 having no through-hole 110, the portion where the corona discharge 2 is generated I can increase it.

FIG. 8 is a view showing the shape of the discharge electrode 100 of the sixth embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 of the sixth embodiment is the same as the electrostatic precipitator 200 of the fifth embodiment except for the shape of the discharge electrode 100 and the shape of the through-hole 110. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

The discharge electrode 100 of the present example has a plurality of concentric annular portions. Specifically, the discharge electrode 100 has a first ring portion 101 and a second ring portion 103 disposed inside the first ring portion 101. As shown in Fig. Between the first ring portion 101 and the second ring portion 103, a first opening 111, which is an annular ring-shaped opening, is formed. On the inside of the second ring portion 103, a second opening portion 113 which is a circular opening portion is formed. In other words, the discharge electrode 100 of the present example has a plurality of independent through openings 110, and has a first opening 111 and a second opening 113.

The end portion 102 of the first ring portion 101 of the present example corresponds to the outer periphery of the first ring portion 101 and forms the end portion 102 of the discharge electrode 100. The outer circumference of the first ring portion 101 has a radius of half or more of the gap length d. The first edge portion 115 which is the edge of the first opening 111 corresponds to the inner periphery of the first ring portion 101 and the outer periphery of the second ring portion 103. [ The inner circumference of the first ring portion 101 and the outer circumference of the second ring portion 103 have a radius of half or more of the gap length d. The second edge portion 117, which is the edge portion of the second opening 113, corresponds to the inner periphery of the second ring portion 103. The inner circumference of the second ring portion 103 also has a radius of half or more of the gap length d. Therefore, the discharge electrode 100 of this embodiment also has a radius of curvature of not less than half of the gap length d in not only the end portion 102, but also all regions including the central region.

In the discharge electrode 100 of the present example, a plurality of independent through openings 110 are included. As a result, the portion where the corona discharge 2 is generated can be increased as compared with the case where the number of the through openings 110 is one.

FIG. 9 is a view showing the shape of the discharge electrode 100 of the seventh embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 of the seventh embodiment is different from the electrostatic precipitator 200 of the fourth embodiment except that the shape of the discharge electrode 100 and the shape and number of the through openings 110 are different same. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

The discharge electrode 100 of this example has a plurality of independent through openings 110. The through openings 110 may have a central opening 140 and a plurality of peripheral openings 146. In this example, one central opening 140 and four peripheral openings 146 are provided. The central opening 140 has the largest opening area among the plurality of through-holes 110. Each peripheral opening 146 has a smaller opening area than the central opening 140. Each peripheral opening 146 is disposed around the central opening 140.

In this example, the center edge portion 122, which is the edge portion of the center opening portion 140, has a circular shape. The peripheral edge portion 123, which is the edge portion of the surrounding opening portion 146, has a polygonal shape in which the apex portion is smoothed. However, the shape of the center edge portion 122 and the peripheral edge portion 123 is not limited to this case. The discharge electrode 100 has a radius of curvature equal to or larger than half of the gap length d in all the regions including the center edge portion 122 and the peripheral edge portion 123 as well as the end portion 102.

Generally, the electric field is concentrated at the end portion 102 of the discharge electrode 100, and the electric field is hardly concentrated at the central portion of the inside of the discharge electrode 100. Therefore, at the center of the inside of the discharge electrode 100, the region not in the high electric field is enlarged. However, according to the discharge electrode 100 of the present embodiment, the central opening 140 located inside the discharge electrode 100 is made larger than the peripheral opening 146. This increases the electric field intensity at the center edge portion 122, which is the edge of the central opening portion 140, so that the corona discharge 2 can also be generated at the center portion of the discharge electrode 100.

FIG. 10 is a view showing the shape of the discharge electrode 100 of the eighth embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 of the eighth embodiment is different from the electrostatic precipitator 200 of the fourth embodiment in the shape and number of the through openings 110 and the edge portions 112 of the through openings 110, Except for the protrusion of the same. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

The discharge electrode 100 of this example has a total of four through-holes 110 arranged in two rows and two columns on the X-Y plane. However, the number of through openings 110 is not limited to this case, and may be different from this example. The discharge electrode 100 of this example has a curvature of not less than half the gap length d in all regions including the edge portion 102 of the through hole 110 as well as the edge portion 102 of the discharge electrode 100. [ Radius.

FIG. 11 is a sectional view of the discharge electrode 100 of the eighth embodiment viewed from the side direction. Specifically, Fig. 11 is a cross-sectional view taken along the line B-B 'in Fig. In the discharge electrode 100 of this embodiment, the through-hole 110 has an edge portion 112 that protrudes toward the counter electrode 10. The protruding length of the edge portion 112 is q.

In this example, the edge portions 112 of the plurality of through openings 110 protrude. However, unlike the present example, at least one of the plurality of through openings 110 may have the edge portion 112 protruding toward the counter electrode 10. The through-hole 110 may have one edge portion 112 protruding toward the counter electrode 10. The discharge electrode 100 may be formed by machining such as press working so that the edge portions 112 of the through openings 110 protrude. According to the discharge electrode 100 of this example, the corona discharge 2 can be more easily generated than in the case where the edge portion 112 does not protrude.

FIG. 12 is a view showing the shape of the discharge electrode 100 of the ninth embodiment. Like FIG. 3, FIG. 2 shows a cross-sectional view taken along the line A-A 'in FIG. The electrostatic precipitator 200 according to the ninth embodiment is different from the electrostatic precipitator 200 according to the eighth embodiment in that the protruding length of the edge portion 112 of the through-hole 110 is changed in accordance with the position in the X direction Except that the rim portion 112 of the through-hole 110 is not chamfered at the apex portion. However, the rim portion 112 of the through-hole 110 may be chamfered R at the vertex portion. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals. The discharge electrode 100 of this example has nine through openings 110 arranged in three rows and three columns on the X-Y plane. However, the number of through openings 110 is not limited to this case, and may be different from this example.

FIG. 13 is a cross-sectional view of the discharge electrode 100 of the ninth embodiment viewed from the side direction. Specifically, Fig. 13 is a cross-sectional view taken along the line C-C 'in Fig. The exhaust gas introduced into the electrostatic precipitator 200 flows in the X direction. The discharge electrode 100 of this embodiment has a plurality of through openings 100 having edge portions 112 protruding toward the counter electrode 10. In the discharge electrode 100 of this example, the protruding length of the edge portion 112 of the through-hole 110 differs between the upstream side and the downstream side of the exhaust gas. As a result, the ease of generation of the corona discharge 2 can be changed in the upstream and downstream of the exhaust gas.

In this example, three rows of through-holes 110 are arranged along the X direction. The length of the edge 112 of the through-hole 110 protruding is q1 in the upstream, q2 in the middle, and q3 in the downstream. As shown in Fig. 13, q1 is the longest, q3 is the shortest, and q2 is the length between q1 and q3. That is, the length of the edge portion 112 protruding is longer on the upstream side than on the downstream side.

The corona discharge 2 can be easily generated on the upstream side relative to the downstream side by making the length of the edge portion 112 protruding on the upstream side compared with the downstream side. As a result, the upstream side region is easier to collect than the downstream side region. The concentration of the fine particles contained in the exhaust gas is highest in the region on the upstream side and lowered in the region on the downstream side. Therefore, according to this example, the concentration of the fine particles can be efficiently collected on the upstream side higher than the downstream side.

However, unlike the present embodiment, with respect to the protruding length of the edge portion 112 of the through-hole 110, the downstream side may be made longer than the upstream side to improve the dust collecting performance on the downstream side. Thereby, it is possible to prevent the fine particles from being deposited rapidly on the upstream side, and it is possible to reduce the deviation (deviation) of the deposition of the fine particles on the upstream side and the downstream side. Therefore, an increase in the maintenance burden for removing the fine particles can be suppressed.

FIG. 14 is a perspective view showing the configuration of the electrostatic precipitator 200 of the tenth embodiment. The electrostatic precipitator 200 of this embodiment has a structure in which a plurality of first units 210 each having a counter electrode 10 and a discharge electrode 100 are stacked. In other words, the electrostatic precipitator 200 of this embodiment has a redundancy in the vertical direction. One counter electrode 10 and one discharge electrode 100 constitute one first unit 210. In this example, the gap length between adjacent electrodes may be all the same.

In this example, the counter electrode 10 - 1 and the discharge electrode 100 - 1 constitute one first unit 210. Likewise, the counter electrode 10-2 and the discharge electrode 100-2 constitute one first unit 210. The counter electrode 10-3 and the discharge electrode 100-3 constitute one first unit 210. FIG. In this example, three first units 210 are stacked in the Z direction. However, the number of layers of the first unit 210 is not limited to this, and the number of layers may be four or more.

In this example, of the discharge electrodes 100-1, 100-2, and 100-3, among the discharge electrodes 100-3 located at the upper end in the stacking direction, And a counter electrode 10-4, which is a single body, are arranged opposite to each other. The single opposite electrode 10-4 may be omitted.

The counter electrode 10-1 to the counter electrode 10-4 (hereinafter also referred to as the counter electrode 10) may be formed in the same manner as the counter electrode 10 (described in the first to ninth embodiments) ). The discharge electrodes 100-1 to 100-3 (hereinafter sometimes referred to as the discharge electrode 100) may be the discharge electrode 100 described in the first to ninth embodiments . Therefore, the detailed description of the counter electrode 10 and the discharge electrode 100 is omitted.

According to this example, since a plurality of the first units 210 are stacked, the dust collecting efficiency can be improved as compared with the case of one unit. Even when a plurality of first units are stacked, each discharge electrode 100 constituting the first unit 210 does not have a projected portion such as a visible shape. Therefore, the generation position of the corona discharge 2 can be prevented from being fixed.

FIG. 15 is a perspective view showing the configuration of the electrostatic precipitator 200 of the eleventh embodiment. The electrostatic precipitator 200 of the present embodiment is different from the electrostatic precipitator 200 of the present embodiment except that the gap length between the counter electrode 10 and the discharge electrode 100 is different depending on the position in the stacking direction of the first unit 210 Is the same as that of the electrostatic precipitator 200 of the tenth embodiment. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

In this example, the stacking direction of the first unit 210 is the Z direction. Among the discharge electrodes 100-1 to 100-3, the discharge electrode 100-3 is located at the upper end in the Z direction. The discharge electrode 100-3 is paired with the counter electrode 10-3. The counter electrode (10-3) and the discharge electrode (100-3) constitute the first unit (210). In this example, the gap length d2 between the counter electrode 10-3 and the discharge electrode 100-3 is larger than the gap length d2 between the counter electrode 10-3 and the discharge electrode 100-3 at the upper end in the Z- Quot ;, respectively.

On the other hand, when the gap length d1 between the counter electrode 10-2 and the discharge electrode 100-2 is larger than the gap length d1 between the counter electrode 10-3 and the discharge electrode 100-3 ) Of the gap length. In this example, the gap length d2 between the counter electrode 10-3 and the discharge electrode 100-3 is larger than the gap length d1 between the counter electrode 10-2 and the discharge electrode 100-2 Big.

In this example, among the discharge electrodes 100-1 to 100-3, the discharge electrode 100-1 is located at the lower end in the Z direction. The gap length between the counter electrode 10-1 and the discharge electrode 100-1 at the lower end in the stacking direction of the plurality of stacked first units 210 may be d2. Therefore, in this example, the gap length d2 at the upper end portion and the lower end portion in the Z direction is larger than the gap length d1 at the center portion in the Z direction. However, unlike the present embodiment, the gap length may be made larger at the end portion of either the upper end or the lower end in the Z direction than the center portion.

In this example, the respective gap lengths between the discharge electrode 100 and the adjacent two opposing electrodes 10 are the same. Specifically, the gap length between the discharge electrode 100-1 and the counter electrode 10-1 is equal to the gap length between the discharge electrode 100-1 and the counter electrode 10-2, and is d2 . The gap length between the discharge electrode 100-2 and the counter electrode 10-2 is equal to the gap length between the discharge electrode 100-2 and the counter electrode 10-3 and is d1. The gap length between the discharge electrode 100-3 and the counter electrode 10-3 is equal to the gap length between the discharge electrode 100-3 and the counter electrode 10-4 and is d2.

However, unlike the present example, the gap lengths between the discharge electrode 100 and the adjacent two opposing electrodes 10 may be different from each other. Specifically, the gap length between the counter electrode 10 and the discharge electrode 100 near the end in the Z direction among the two adjacent counter electrodes 10 may be increased.

It is preferable that the gap length between the discharge electrode 100-1 and the counter electrode 10-1 is set to be larger than the gap length at the center of the discharge electrode 100-1 in the Z direction, May be larger than the gap length between the counter electrode (100-1) and the counter electrode (10-2). The gap length between the discharge electrode 100-3 and the counter electrode 10-4 is set to be shorter than the gap length at the center of the discharge electrode 100- 3 and the counter electrode 10-3.

In this example, the case where three first units 210 are laminated has been described, but unlike the present example, four or more first units 210 may be stacked. In this case, the gap length between the opposing electrode 10 and the discharge electrode 100 may be gradually increased as the distance from the center portion in the Z direction becomes closer to the upper end portion or the lower end portion.

When a plurality of the first units 210 are stacked to form a laminated structure, the exhaust gas hardly flows at the end of the first unit 210 in the stacking direction. However, in the electrostatic precipitator 200 of this embodiment, it is easy to collect dust by increasing the gap length at the end portion in the stacking direction of the first unit 210.

FIG. 16 is a perspective view showing the configuration of the electrostatic precipitator 200 of the twelfth embodiment. In the electrostatic precipitator 200 of this embodiment, the second unit 220 is provided at least at both ends in the Z direction. Except for this point, the configuration of the electrostatic precipitator 200 of this embodiment is the same as that of the electrostatic precipitator 200 of the tenth embodiment. Therefore, repeated description of other components will be omitted, and the same members will be described with the same reference numerals.

In this example, a plurality of first units 210 are stacked at the center in the Z direction. In this example, two first units 210 are stacked. However, unlike the present example, three or more first units 210 may be stacked. The structure of the first unit 210 is the same as that of the tenth embodiment. On the other hand, a second unit 220 is provided at least at both ends in the Z direction.

In the lower end portion in the Z direction, the second unit 220 has an end counter electrode 190-1 and a protruding discharge electrode 180-1. The end counter electrode 190-1 as the third electrode plate is an electrode plate having a GND potential, which is also called a GND electrode. The projection-type discharge electrode 180-1 as the fourth electrode plate is a high-potential electrode plate. The protruding discharge electrode 180-1 is provided opposite to the end counter electrode 190-1. The protruding discharge electrode 180-1 and the end counter-electrode 190-1 may be arranged parallel to the XY plane.

The end portion 182 of the protruded discharge electrode 180-1 is located inside the end portion 192 of the end counter electrode 190-1. Here, the end portion 182 means an end portion in a direction parallel to the XY plane. A negative high voltage is applied to the protruding discharge electrode 180-1 of the present embodiment by the DC power supply 20. [ The end counter electrode 190-1 is grounded.

As shown in FIG. 16, the end portion 182 of the projection-type discharge electrode 180-1 has the protruding portion 184. The protruding portion 184 may have a triangular shape that is projected on the XY plane. The protruding portion 184 in this embodiment has a spiral shape or a saw blade shape. A plurality of projecting portions 184 are provided along the end portion 182. The protruding portion 184 may have a protruding length of about 1 mm to 5 mm. The pitch of the protruding portion 184 may be determined so that 3 to 5 protruding portions 184 are provided per 1 cm. The protruding portion 184 may be provided along all sides of the end portion 182 of the protruding discharge electrode 180-1 or the protruding portion 184 may be provided depending on the specific path.

At the upper end in the Z direction, the second unit 220 has an end counter electrode 190 - 2 and a protruding discharge electrode 180 - 2. The end counter electrode 190-2 is the third electrode plate, and the protruding discharge electrode 180-2 is the fourth electrode plate. The configuration and applied voltage of the second unit 220 at the upper end in the Z direction may be the same as that of the second unit 220 disposed at the lower end.

In this example, the second unit 220 is provided at each end in the Z direction. However, unlike the present embodiment, a plurality of second units 220 may be provided on the upper and lower ends in the Z direction, respectively. However, the first unit 210 is stacked at the center in the stacking direction. It is preferable that the stacking number of the second unit 220 does not exceed the stacking number of the first unit 210. [

When a plurality of units are stacked to form a stacked structure, since the exhaust gas hardly flows at the end of the unit stacking method, the amount of sediment such as fine particles is smaller than that at the center of the stacked structure. Therefore, even at the end of the stacking method, even if the protruding discharge electrode 180 having the protruding portion 184 of the conventional type is used, the possibility of sparking due to the deposit is lower than the center portion of the stacked structure . Therefore, at least at both ends in the stacking direction, while using the protruding discharge electrode 180 having the protruding portion 184 of the conventional shape, the protruding portion 180 is formed at the central portion in the stacking direction, 1 units 210 can be stacked to positively reduce the occurrence of sparks.

FIG. 17 is a view showing the electrostatic precipitator 200 of the thirteenth embodiment. The electrostatic precipitator 200 of the thirteenth embodiment is the same as the electrostatic precipitator 200 of the first to the twelfth embodiments except that a positive high voltage is applied to the discharge electrode 100 by the DC power source 20 ). In the first to twelfth embodiments, the counter electrode 10 (or the end counter electrode 190) is grounded, and a negative high voltage is applied to the discharge electrode 100. On the other hand, in the present embodiment, a positive high voltage is applied instead of a negative high voltage in the first to twelfth embodiments.

Even when a positive high voltage is applied to the discharge electrode 100 by the DC power supply 20, since the end portion 102 of the discharge electrode 100 does not have a protruding portion, the occurrence position of the corona discharge is And can be prevented from being fixed directly below or directly above the protruding portion. Thereby, erosion of the counter electrode can be suppressed.

FIG. 18 is a diagram showing an outline of an exhaust gas purifying system 400. The exhaust gas purifying system 400 removes harmful substances such as sulfur components contained in the exhaust gas discharged from an engine or the like of a vehicle. The exhaust gas purifying system 400 has an electrostatic precipitator 200, a scrubber 300 and a pumping-up pump 350. The electrostatic precipitator (200) is installed upstream of the scrubber (300). The exhaust gas is introduced into the scrubber 300 through the exhaust gas introduction pipe 306 from the electrostatic precipitator 200. The electrostatic precipitator 200 of the first to thirteenth embodiments is used as the electrostatic precipitator 200.

The scrubber 300 has a reaction tower 302, a nozzle 304, and an exhaust gas introduction pipe 306. The reaction tower 302 has an inner space that is elongated in the height direction. The height direction in this example indicates a direction in which the exhaust gas is drawn from the bottom side 308 where the exhaust gas is introduced to the upper side 310 from which the exhaust gas is discharged in the reaction tower 302.

In the scrubber 300, the exhaust gas introduction pipe 306 is located in the vicinity of the bottom side 308 of the reaction tower 302. The exhaust gas introduction pipe 306 may be provided so that the exhaust gas introduced from the exhaust gas introduction pipe 306 turns in a spiral shape along the inner side surface of the reaction tower 302. The radius of the reaction tower 302 may be 0.3 m or more and 10 m or less.

A cleaning water pipe 312 through which the washing water flows is disposed inside the scrubber 300. In this example, the washing water pipe 312 is disposed in the vicinity of the upper side 310 of the reaction tower 302. The washing water pipe 312 of this example transports washing water in a direction perpendicular to the height direction of the reaction tower 302. The washing water is supplied from the raising pump 350 to the washing water pipe 312.

The cleaning water pipe 312 is provided with a nozzle 304. The nozzle 304 processes the exhaust gas by spraying the washing water 314 from the upper side 310 to the lower side 308 with respect to the exhaust gas. The washing water 314 injected from the nozzle 304 comes into contact with the exhaust gas passing through the inside of the reaction tower 302 and absorbs the sulfur component contained in the exhaust gas. The liquid absorbing the sulfur component or the like is solid at the bottom side 308 of the reaction tower 302 and discharged as waste water to the outside of the reaction tower 302.

According to the exhaust gas purifying system 400 of the present embodiment, it is possible to remove harmful substances that can not be removed only by the electrostatic precipitator 200. Since the exhaust gas purifying system 400 uses the electrostatic precipitator 200 of the first to thirteenth embodiments, erosion of the counter electrode 10 due to the fixed position of the corona discharge 2 is suppressed There is a number.

The above-described embodiment is also applied to a two-stage electrostatic precipitator having a charging section and a dust collecting section.

[0092] While the present invention has been described with reference to the embodiment, the technical scope of the present invention is not limited to the scope described in the above embodiment. It will be apparent to those skilled in the art that various changes and modifications can be made to the above embodiments. It is apparent from the description of the claims that the form of such modification or improvement can be included in the technical scope of the present invention.

[0093] 2; Corona discharge
10; Opposite electrode
12; End
14; Side
20; DC power
100; Discharge electrode
101; The first ring portion
102; End
103; The second ring portion
104; Straight portion
106; Corner portion
110; Through opening
111; The first opening
112; Edge portion
113; The second opening
114; The straight-
115; The first edge portion
116; Edge edge portion
117; The second edge portion
122; Center edge portion
123; Peripheral edge portion
140; Central opening
146; Surrounding opening
180; The protruding discharge electrode
182; End
184; Projecting portion
190; The end-
192; End
200; Electrostatic precipitator
210; The first unit
220; The second unit
300; Scrubber
302; Reaction tower
304; Nozzle
306; Exhaust gas introduction pipe
308; Bottom side
310; Upper side
312; Washing water pipe
314; Washing water
350; Pump Up Pump
400; Exhaust gas purification system

Claims (14)

A first electrode plate,
A second electrode plate provided opposite to the first electrode plate and having an end located inside the end of the first electrode plate,
And,
Wherein the second electrode plate has an end portion having no protruding portion
Electrostatic precipitator. The method according to claim 1,
The second electrode plate has a flat flat plate shape,
Wherein the second electrode plate has a radius of curvature of half or more of a gap between the first electrode plate and the second electrode plate in all regions,
Electrostatic precipitator. 3. The method of claim 2,
Wherein the second electrode plate has a shape of a flat plate including a linear portion and a corner portion having the radius of curvature,
Electrostatic precipitator. 3. The method of claim 2,
The second electrode plate has a disc shape
Electrostatic precipitator. 5. The method according to any one of claims 1 to 4,
Wherein the second electrode plate has at least one through-
Electrostatic precipitator. 6. The method of claim 5,
Wherein the at least one through opening includes a plurality of independent through openings,
Electrostatic precipitator. The method according to claim 6,
Wherein the at least one through-
A central opening having the largest opening area,
Wherein the central opening has a smaller opening area than the central opening,
Having
Electrostatic precipitator. The method according to claim 1,
Wherein the second electrode plate has at least one through-hole,
Wherein at least one of the at least one through-hole has an edge portion protruding toward the first electrode plate,
Electrostatic precipitator. 9. The method of claim 8,
And a plurality of through-holes each having an edge portion protruding toward the first electrode plate,
The length of the edge portion protruded is different from the upstream side and the downstream side of the gas introduced into the electrostatic precipitator,
Electrostatic precipitator. 10. The method of claim 9,
Wherein the length of the edge portion protrudes from the upstream side toward the downstream side,
Electrostatic precipitator. 11. The method according to any one of claims 1 to 10,
And a plurality of first units each having the first electrode plate and the second electrode plate are stacked,
Electrostatic precipitator. 12. The method of claim 11,
The gap length between the first electrode plate and the second electrode plate at the end in the stacking direction of the plurality of stacked first units is set so that the gap length between the first electrode plate and the second electrode plate at the central portion in the stacking direction of the plurality of stacked first units Is larger than the gap length between the plate and the second electrode plate
Electrostatic precipitator. 12. The method of claim 11,
A third electrode plate,
Further comprising a second unit provided opposite to the third electrode plate and having a fourth electrode plate having an end located inside the end of the third electrode plate and an end having a protruding portion,
Wherein at least both ends of the plurality of stacked first units in the stacking direction are provided with the second unit
Electrostatic precipitator. A scrubber for purifying the exhaust gas,
The electric dust collector according to any one of claims 1 to 13, which is installed upstream of the scrubber
.
Exhaust gas purification system.

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