JP2015127025A - Charging equipment and air treatment apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide charging equipment (20) with a discharge electrode (21) and a counter electrode (25), which can increase efficiency of collection of airborne particulates in an air treatment apparatus (10) by enhancing electron and ion diffusion performance.SOLUTION: A discharge electrode (21) is configured as a saw-toothed electrode having a longitudinally-elongated base (22) and a plurality of needle-like discharge ends (23) protruding from the base (22). Protrusion directions of the needle-like discharge ends (23) are set to be three or more directions different from one another.

Description

  The present invention relates to a charging device that forms an electric field between a discharge electrode and a counter electrode to charge suspended particles in air to be processed, and an air processing device including the charging device.

  2. Description of the Related Art Conventionally, an air treatment device including a charging unit (charging device) that charges floating particles such as dust is known (see, for example, Patent Document 1). In the air treatment device of Patent Literature 1, a charging unit, a dust collection unit (dust collection electrode), and a fan are arranged in this order from the air suction port of the casing toward the air outlet.

  The charging unit has a discharge electrode and a counter electrode. An electric field is formed between the discharge electrode and the counter electrode. When the air to be treated passes through the charged portion, electrons and ions traveling from the discharge electrode to the counter electrode collide with suspended particles contained in the air to be treated. As a result, the suspended particles are charged. Charged suspended particles are attracted and collected by the Coulomb force in the dust collecting section downstream of the charging section. As described above, in this air treatment apparatus, dust particles and the like in the air to be treated are removed by charging the floating particles in the charging unit and collecting the charged floating particles in the dust collecting unit. .

  By the way, as the charging method, a collision charging method and a diffusion charging method are known. The collision charging method is a method in which electrons and ions jumping out from the discharge electrode jump into the counter electrode, and the diffusion charging method is a method in which electrons and ions jumping out from the discharge electrode do not reach the counter electrode. In the diffusion charging method, the diffused electrons and ions adhere to floating particles such as dust and flow downstream, so that dust and the like can be sufficiently collected at the dust collecting portion.

JP 2009-131829 A

  In the charging device of Patent Document 1, as shown in FIGS. 6A and 6B, a discharge electrode (100) and a counter electrode (105) are provided. The discharge electrode (100) is composed of a strip-shaped substrate portion (101) and a needle-like discharge end portion (102) protruding in opposite directions from both edge portions. That is, the discharge electrode (100) is formed as a planar member. For this reason, there are only two directions in which electrons jump out from the needle-like discharge end (102), and there is a problem that electrons and ions are not sufficiently diffused. As a result, when the charging unit is provided in the air treatment device, there is a problem that it is difficult to increase the collection efficiency of the suspended particles in the air treatment device.

  The present invention has been made in view of such problems, and the object thereof is to improve the diffusion performance of electrons and ions in a charging device including a discharge electrode and a counter electrode. It is to improve the collection efficiency of suspended particles in an air treatment device using a charging device.

  1st invention presupposes the charging device provided with the discharge electrode (21) and the counter electrode (25).

  In this charging device, the discharge electrode (21) is a sawtooth electrode having a base (22) extending in the longitudinal direction and a plurality of needle-like discharge ends (23) protruding from the base (22), The needle discharge ends (23) are projected in three or more different directions.

  In the first aspect of the invention, since the protruding directions of the needle-like discharge end (23) are three or more directions different from each other, ions jump out as compared with the case where a conventional planar sawtooth electrode is used. The direction becomes three-dimensional. Since the direction in which the ions jump out is three-dimensional, the ions are likely to diffuse, and suspended particles such as dust contained in the surrounding air are easily combined with the ions to be charged.

  According to a second invention, in the first invention, the needle-like discharge end portion (23) includes a plurality of base-connected discharge end portions (23a) protruding from an edge portion of the base portion (22), and a base portion (22). A plurality of cut-and-raised discharge ends (23b) formed by cutting and raising at least one of the base-connected discharge end (23a) and the cut-and-discharge end (23b) in two or more directions. It is characterized by protruding.

  According to a third invention, in the second invention, the discharge electrode (21) includes a plurality of base-connected discharge ends (23a) protruding in opposite directions from both side edges of the base (22), It is characterized in that at least a part of the base connected discharge end (23a) is bent so that the projecting directions are three or more.

  According to a fourth invention, in any one of the first to third inventions, the discharge electrode (21) is different from the electrode substrate (24a) having a strip shape or a rod shape, and the electrode substrate (24a). And a plurality of electrode plates (24b) having three or more discharge end portions (24c) protruding in different directions from each other, and each electrode plate (24b) with respect to the electrode substrate (24a) It is characterized by being arranged with a predetermined interval in a state substantially orthogonal to the longitudinal direction.

  In the second to fourth inventions, the ion diffusion performance can be enhanced by using the discharge electrode (21) having the needle-like discharge end portion (23) protruding in three or more directions. And the suspended particles contained in the surrounding air are easily charged.

  5th invention was provided with the charge part (20) which charges the floating particle | grains in to-be-processed air, and the dust collection part (30) which collects the floating particle charged by this charge part (20) An air treatment device is assumed.

  The air treatment apparatus is characterized in that the charging unit (20) is configured by any one of the charging apparatuses according to the first to fourth aspects of the invention.

  In the fifth invention, in the air treatment device using the charging device of the present invention, by using the discharge electrode (21) in which the protruding directions of the needle-like discharge end (23) are three or more different directions. , Ion diffusion effect can be enhanced.

  According to the present invention, the protruding direction of the needle-like discharge end (23) is set to three or more directions different from each other, so that the direction in which ions jump out compared to the case of using a conventional planar sawtooth electrode is obtained. Try to be three-dimensional. Therefore, ions are easily diffused, and suspended particles such as dust contained in the surrounding air are easily charged. Therefore, when this charging device is used in an air treatment device, it is possible to increase the collection efficiency of suspended particles in the air treatment device.

  According to the second to fourth inventions, the discharge electrode (21) can be easily formed and the ion diffusion effect can be enhanced, so that the collection efficiency of suspended particles in the air treatment device is reliably increased. It is done.

  According to the fifth aspect of the present invention, in the air treatment device using the charging portion (20) having the discharge electrode (21), the protruding directions of the needle-like discharge end portion (23) are in three or more different directions. By using a certain discharge electrode (21), the ion diffusion effect can be enhanced, so that the collection efficiency of suspended particles can be enhanced.

FIG. 1 is a cross-sectional view showing a schematic internal structure of an air purification device according to an embodiment of the present invention. FIG. 2 is a perspective view of the discharge electrode. FIG. 3 is a cross-sectional view of a main part of the charging unit. FIG. 4 is a perspective view showing a modification of the discharge electrode. FIG. 5 is a perspective view showing another modification of the discharge electrode. 6A is a perspective view showing a discharge electrode and a counter electrode of a conventional charging device, and FIG. 6B is a cross-sectional view.

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

  This embodiment is an example in which the charging device according to the present invention is applied to an air purification device (10). The air purification device (10) includes a charging unit (charging device) (20) that charges floating particles in the air to be treated, and a dust collecting unit (electric dust collecting unit) that collects floating particles charged by the charging unit. ). FIG. 1 is a cross-sectional view showing a schematic internal structure of the air purification device (10).

  This air purification device (10) includes a box-shaped hollow casing (11), and a plurality of functional parts are accommodated in the casing (11). The casing (11) has an air inlet (12a) at the right end of the figure on the upper and lower (or left and right) wall surfaces, and an air outlet at the left end of the figure on the upper and lower (or left and right) wall surfaces. (12b) is formed. The air suction port (12a) is provided with a prefilter (14) that captures relatively large particles of dust (floating particles) contained in the air to be treated.

  An air passage (13) through which air flows from the air inlet (12a) toward the air outlet (12b) is formed in the casing (11). In this air passage (13), in order from the upstream side to the downstream side in the air flow direction, a charging part (ionization part) (20), a dust collecting part (30), an adsorbing member (15), and a centrifugal fan (Sirocco fan) (17) is arranged. The air passage (13) enters the air inlet (12a) from the top and bottom (or left and right) with respect to the casing (11) and then bends at a substantially right angle toward the air outlet (12b). At (17), it is further bent toward the direction of the air outlet (12b).

  Two sets of charging units (20) configured in the same manner are arranged one above the other. Each charging part (20) has a discharge electrode (21) and a counter electrode (25) as shown in FIGS. The discharge electrode (21) is a sawtooth electrode having a strip-shaped base (22) extending in the longitudinal direction and a plurality of needle-like discharge ends (23) protruding from the base (22). The discharge direction of the discharge end portion (23) is four directions with 90 ° intervals different from each other. Specifically, the acicular discharge end portion (23) is formed by cutting and raising the base portion (22) with a plurality of base-connected discharge end portions (23a) protruding from both side edges of the base portion (22). A plurality of cut-and-raised discharge end portions (23b), and the base-connected discharge end portion (23a) and the cut-and-raised discharge end portion (23b) protrude in two opposite directions. . The acicular discharge end (23) protrudes in four directions as a whole.

  As shown in FIG. 3, the counter electrode (25) is a rod-shaped (or columnar) electrode, and a total of four counter electrodes (25) are arranged one by one between adjacent acicular discharge ends (23). Each counter electrode (25) is arranged at a position sandwiching each needle-like discharge end (23) projecting in four directions, and each of them is inside the tip of the needle-like discharge end (23) (discharge electrode). Located on the center side). By doing so, the degree of bending of the electric lines of force indicated by the broken line in the figure becomes stronger, and electrons (ions) that have jumped out from the needle-like discharge end (23) do not easily reach the counter electrode (25), and in the air It is easy to spread.

  Although not shown, the discharge electrode (21) is connected to the high-voltage pole of a DC high-voltage power supply for discharge, and the counter electrode (25) is connected to the low-voltage pole of the power supply. This high voltage power source is grounded on the low voltage pole side.

  The dust collector (30) includes a first electrode (31) connected to a high-voltage pole having the same polarity as a discharge electrode (21) of a DC high-voltage power source (not shown) for dust collection, and a low-voltage pole of the power source. And a second electrode (32) connected thereto. The low voltage pole side of the power supply is grounded. The first electrode (31) and the second electrode (32) may be ones in which electrode plates are alternately arranged at equal intervals, or the second electrode (32) is formed in a lattice shape in a small space in each lattice. A needle-like first electrode (31) may be disposed.

  The adsorbing member (15) is not shown in detail, but adsorbent such as zeolite adsorbs odor components on the surface of a honeycomb-shaped substrate having a number of fine air circulation holes along the air flow direction. The fine powder is supported. The adsorbing member (15) carries fine powder of the deodorizing catalyst together with the adsorbent. This adsorbing member (15) captures the odorous substance with the adsorbent when a part of the odorous substance in the air passes through the dust collecting part (30) and deodorizes it on the surface. Decomposes by the action of the catalyst. As this deodorization catalyst, a heat catalyst or a photocatalyst that is activated by heat, light, active substances such as ozone generated by discharge of the charged portion (20), and promotes a decomposition reaction of odor components can be used.

  The air passage (13) is bent at a position after the air to be treated has passed through the charging part (20). In the air passage (13), a rectifying member (18) is disposed on the upstream side of the dust collecting portion (30). In the air passage (13), an adsorbing member (15) carrying an adsorbent and a deodorizing catalyst is disposed on the downstream side of the dust collecting section (30).

  A bell mouth (19) as an air inflow guide to the sirocco fan (17) is disposed downstream of the adsorbing member (15). The air introduced into the sirocco fan (17) by the bell mouth (19) changes the flow direction by the sirocco fan (17) and is blown out of the casing (11) from the air outlet (12b). It is like that.

-Driving action-
When the air purification device (10) according to this embodiment is activated, the sirocco fan (17) starts to rotate, and indoor air that is air to be treated is sucked into the casing (11) from the air suction port (12a). In the charged part (20), a potential difference is applied between the discharge electrode (21) and the counter electrode (25), and ions are ejected from the discharge electrode (21). Ions that have jumped out from the needle-like discharge end (23) of the discharge electrode (21) tend to travel in a direction away from the lines of electric force as shown in FIG. As a result, the ions do not reach the counter electrode (25) and are easily diffused into the air. Further, since the air passage (13) is bent, the ion diffusion effect is enhanced.

  Since most of the ions generated in the charging part (20) do not reach the counter electrode (25) and are released into the space in the casing (11), they are dispersed in the space and covered in this space. When the processing air flows, suspended particles such as dust in the processing air are charged.

  The air to be treated flows into the dust collecting part (30) in a state where the dust is charged. Since the dust collection part (30) has the 2nd electrode (32) used as a low pressure and a dust collection electrode, and the 1st electrode (31) of a high voltage | pressure, it can capture | acquire ionized dust with Coulomb force. it can.

  Most of the dust in the air to be treated has been removed by passing through the dust collection part (30), but there is also dust that is not captured by the dust collection part (30) and goes to the air outlet (12b). The dust that has passed through the dust collecting part (30) is captured by the adsorption member (15). The adsorbing member (15) also carries a deodorizing catalyst, where odor components are also decomposed.

  And the to-be-processed air from which the dust was removed and the odor component was decomposed is blown out from the air outlet (12b) to the indoor space.

-Effect of the embodiment-
According to the present embodiment, by setting the protruding direction of the needle-like discharge end (23) to three or more directions different from each other, ions jump out as compared with the case of using a conventional planar sawtooth electrode. The direction is three-dimensional. As a result, ions are easily diffused, and suspended particles such as dust contained in the surrounding air are easily charged. Therefore, by using this charging device for an air treatment device, the collection efficiency of suspended particles in the air treatment device can be increased.

  Further, the discharge electrode (21) can be easily formed with the configuration described in the present embodiment.

-Modification of the embodiment-
<Modification 1>
Modification 1 is an example in which the shape of the discharge electrode (21) is changed in the above embodiment.

  Specifically, as shown in FIG. 4, the discharge electrode (21) includes a plurality of base-connected discharge ends (23a) protruding in opposite directions from both side edges of the base (22). At least a part of the articulated discharge end portion is bent so that the protruding direction is in four directions. That is, in this example, the first group of acicular discharge ends (23) in which a part of the acicular discharge end (23) protruding from both edges of the base (22) is projected in two directions without being bent. And the remaining acicular discharge end (23) is bent up and down in the figure to form a second group of acicular discharge ends (23) projecting in two directions substantially perpendicular to the base (22). I have to.

  Even if comprised in this way, since the diffusion effect of ion can be improved, the same effect as the above-mentioned embodiment can be produced.

<Modification 2>
Modification 2 is an example in which the shape of the discharge electrode (21) is changed in the first embodiment.

  Specifically, as shown in FIG. 5, the discharge electrode (21) includes a strip-shaped or rod-shaped electrode base material (24a) and the electrode base material (24a) that are different parts and are 90 ° in different directions. A plurality of electrode plates (24b) having four acicular discharge ends (24c) protruding at intervals, and each electrode plate (24b) is substantially orthogonal to the longitudinal direction of the electrode substrate (24a) In this state, it is configured by joining at a predetermined interval.

  Even if comprised in this way, since the diffusion effect of ion can be improved, the same effect as the above-mentioned embodiment can be produced.

<< Other Embodiments >>
About the said embodiment, it is good also as the following structures.

  For example, in the above-described embodiments and modifications, the protruding directions of the acicular discharge end portions (23, 24c) are four directions, but the protruding directions may be three or more directions different from each other.

  In Modification 1 of the above embodiment, the acicular discharge end portion (23) has at least one of the base connected discharge end portion (23a) and the cut-and-raised discharge end portion (23b) in two or more directions. It only has to protrude.

  Further, the shape of the discharge electrode (21) is not limited to that described in the embodiment or the modification, and the protruding directions of the needle-like discharge end portions (23, 24c) are three or more different directions. It may be changed to any shape as long as it is present. Further, the arrangement of the counter electrode (25) with respect to the discharge electrode (21) may be appropriately changed as long as diffusion charge is likely to occur. For example, two electrodes on both sides of the needle-like discharge end portions (23, 24c). You may arrange them one by one.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a charging device having a discharge electrode and a counter electrode, and an air treatment device including the charging device.

10 Air treatment equipment
20 Charging unit (charging device)
21 Discharge electrode
22 Base
23 Needle-shaped discharge end
23a Base articulated discharge end
23b Cut-off type discharge end
24a Electrode substrate
24b electrode plate
24c discharge end
25 Counter electrode
30 Dust collector

Claims (5)

A charging device comprising a discharge electrode (21) and a counter electrode (25),
The discharge electrode (21) is a sawtooth electrode having a base (22) extending in the longitudinal direction and a plurality of acicular discharge ends (23) protruding from the base (22). 23) The charging device characterized in that the protruding directions in 3) are three or more directions different from each other. In claim 1,
The acicular discharge end portion (23) includes a plurality of base-connected discharge end portions (23a) protruding from the edge of the base portion (22) and a plurality of cut-and-raised types formed by cutting and raising the base portion (22). Including a discharge end (23b),
A charging device, wherein at least one of a base connected discharge end (23a) and a cut-and-raised discharge end (23b) protrudes in two or more directions. In claim 2,
The discharge electrode (21) includes a plurality of base-connected discharge ends (23a) protruding in opposite directions from both side edges of the base (22), and at least one of the base-connected discharge ends (23a). A charging device characterized in that the projecting direction is set to three or more directions by bending a portion. In any one of Claims 1-3,
The discharge electrode (21) has a strip-shaped or rod-shaped electrode base (24a) and three or more discharge ends (24c) that are separate parts from the electrode base (24a) and project in different directions. A plurality of electrode plates (24b), and each electrode plate (24b) is arranged at a predetermined interval in a state substantially orthogonal to the longitudinal direction of the electrode substrate (24a). A charging device. An air treatment apparatus provided with a charging unit (20) for charging suspended particles in air to be treated and a dust collecting unit (30) for collecting suspended particles charged by the charging unit (20). ,
5. The air processing apparatus according to claim 1, wherein the charging unit (20) is configured by any one charging device according to claims 1 to 4.

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