KR20170051145A - Electric Dust Collection Device and Air Conditioner comprising the same - Google Patents

Abstract

According to the present invention, an electric dust collection device includes: an electrifying part electrifying dust particles in the air; a dust collection part collecting the dust particles electrified by the electrifying part; and a dust collection case storing the dust collection part. The dust collection part includes: a plurality of films applying a conductive layer to an insulating layer; and a fixing part fixing the films to the inside of the dust collection case. The length of the films is longer than the width of the same, and the films face each other, form a gap between the films, and are arranged in a line to form an arrangement group. The fixing part includes a pair of gap keeping parts placed in both widthwise sides of the arrangement group to keep the gap. The gap keeping parts include: a base gap keeping part placed in a widthwise side of the films; and a loop gap keeping part placed in the other widthwise side of the films. The base gap keeping part includes a plurality of first vertical bars inserted from a side of the arrangement group into each gap. The loop gap keeping part includes a plurality of second vertical bars inserted from the other side of the arrangement group into each gap.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electric dust collector and an air conditioner including the electric dust collector,

The present invention relates to an electric dust collecting apparatus having a plurality of films for generating an electric field for collecting charged dust particles and a structure for maintaining an interval between the plurality of films, and an air conditioner including the same.

The air conditioner includes a radiator or a heater for controlling the temperature of the air, an air purifier for maintaining the cleanliness by removing foreign substances from the air, a humidifier for providing moisture in the air, and a dehumidifier for removing moisture in the air.

The electric dust collecting apparatus is an apparatus that is installed independently or in an air conditioner to collect dust by charging dust particles contained in the air.

The electric dust collecting apparatus mainly includes a charging section for forming an electric field and a dust collecting section for collecting dust particles charged by the charging section. While air passes through the charging section and then passes through the dust collecting section, the dust in the air is collected in the dust collecting section.

The charging section includes discharge electrodes and counter electrodes arranged in parallel with the discharge electrodes, and the dust is charged by the corona discharge between the discharge electrodes facing each other and the counter electrode.

In the prior art, a plurality of protrusion structures arranged along both ends in the width direction of the film are arranged so as to span across both widthwise ends of the film so as to maintain a gap between the films (high potential electrode and low potential electrode) There is a problem in that it is difficult to keep a certain distance from the adjacent film due to warping or the like, and the electric field is formed inefficiently due to non-uniformity. The first problem is solving this problem.

In the prior art, the plurality of protruding structures are disposed at both ends in the width direction of the films, the protruding structure at one end of the both ends is fixed to the first structure at the one end, and the protruding structure at the other end is fixed to the second There is a problem that a considerable effort or precision is required in fixing the first structure and the second structure to the protrusions at both ends of the films when assembling the first structure and the second structure with each other. The second problem is to solve this problem.

The problems of the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

An electric dust collecting apparatus according to the present invention includes a charging unit charging a dust particle in the air, a dust collecting unit collecting dust particles charged in the charging unit, and a dust collecting case accommodating the collection unit. The dust collecting portion includes a plurality of films coated with an insulating layer as a conductive layer and a fixing portion for fixing the plurality of films inside the dust collecting case.

The plurality of films are in the form of strips whose longitudinal direction is longer than the width direction and which are arranged in a line to form a group of arrangements.

The fixing portion includes a gap maintaining portion that is disposed on both sides in the width direction of the array group and holds the gap.

The gap holding portion includes a base gap holding portion disposed on one side of the film in the width direction and a loop gap holding portion disposed on the other side in the width direction of the film.

The base spacing portion includes a plurality of first vertical bars inserted into the gaps from the one side of the array group.

The loop spacing portion includes a plurality of second vertical bars inserted into the gaps from the other side of the array group.

The base gap retaining portion and the loop gap retaining portion may be disposed symmetrically with respect to the widthwise center portion of the film.

The base spacing portion and the loop spacing portion may have the same shape.

Protrusions protruding in the surface direction of the film may be formed on the first vertical bar and the second vertical bar so that the clearance of the film is reduced.

The gap holding portions may be spaced apart from each other along the longitudinal direction of the film.

The base spacing portion may include a first spacing body which surrounds both ends of the arrangement direction of the arrangement group and one side thereof and supports the first ends of the first and second vertical bars.

The loop interval maintaining unit may include a second interval maintaining body that supports both ends of the array group in the arrangement direction and the other end and supports the first end of the second vertical bar.

The first gap maintaining body may include a first amount retaining portion disposed at both ends of the arranging direction and engaged with the dust collecting case.

The second gap maintaining body may include a second quantity accommodation portion disposed at both ends of the arrangement direction and coupled with the dust collection case.

The first gap maintaining body may include a first horizontal bar extending in the arrangement direction of the array group while being in contact with the array group.

The second gap maintaining body may include a second horizontal bar extending in the array direction of the array group while being in contact with the array group.

The first gap maintaining body may include a first coupling portion for fixing the base gap holding portion to the dust collecting case.

The second gap maintaining body may include a second coupling portion for fixing the loop gap maintaining portion to the dust collecting case.

The dust collecting case may include a hook which is hooked in a state where the first fastening part and the second fastening part are in contact with each other.

The air conditioner according to the present invention includes the electric dust collector.

The details of other embodiments are included in the detailed description and drawings.

Through the fixed portion structure, the adjacent film and the gap can be kept constant not only at the edge of the film but also at the central portion of the film.

And the gap is kept constant, so that the electric field generated in the gap between the plurality of films can be made uniform.

It is possible to manufacture at a convenient, accurate and speedy production through the fixing rib, the molding part, and the gap retaining part.

The spacing structure allows the spacing of the films to be maintained stably without disturbing air flow through the outlet.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view of an air conditioner according to an embodiment of the present invention.
2 is an exploded perspective view illustrating the components of the humidification module 200 of FIG.
3 is a longitudinal sectional view of the air conditioner of FIG.
4 is an exploded perspective view showing only the body 130 of FIG.
FIG. 5 is an exploded perspective view showing the parts of the body 130 of FIG. 4 separated.
6 is a perspective view illustrating the body 130 of FIG. 1 and the removable filter assembly 10. FIG.
7 is a perspective view of the filter assembly 10 of FIG.
8 is a longitudinal sectional view of the filter assembly 10 of Fig.
9 is an exploded perspective view of the filter assembly 10 of FIG.
FIG. 10 is a perspective view showing the inside heavy charging unit 510 of the electric dust collector 500 of FIG.
11 is an internal elevational view of the charging unit 510 of FIG. 10 viewed from above.
12 is a perspective view showing the dust collecting part 540 of the electric dust collecting apparatus 500 of FIG.
13 is an exploded perspective view in which the dust-collecting case 502, the base-spacing portion 561, the plurality of films 540a, and the loop-spacing portion 566 shown in Fig. 12 are separated.
Fig. 14 is a schematic cross-sectional view showing a cross section in the arrangement direction (X) of the plurality of films 540a in Fig.
Fig. 15 is a plan view schematically showing a circuit diagram of the plurality of films 540a of Fig. 13 viewed from above.
16 is a perspective view showing the structure of the first film 541 of FIG.
17 is a perspective view showing the structure of the second film 542 of Fig.
FIG. 18 is an enlarged perspective view of a structure in which the base space retaining portion 561 and the loop space retaining portion 566 of FIG. 12 are combined with the plurality of films 540a and the dust collecting case 502. FIG.
19 is a partially enlarged perspective view of the base-spacing portion 561 of Fig.
20 is a partial cross-sectional view of the base-spacing portion 561 of Fig. 18 cut in the film arrangement direction X. Fig.
21 is a partially enlarged perspective view of the loop gap retaining portion 566 in Fig.
22 is a partial cross-sectional view of the loop gap retaining portion 566 of Fig. 18 cut in the film arrangement direction X. Fig.
23 is a partial perspective view enlarging the structure in which the plurality of films 540a of Fig. 12 are mounted on the mounting ribs 572. Fig.
24 is a sectional view of the dust collecting part 540 of Fig. 12 cut in the film length direction Y. Fig.
25 is a top view of an electric dust collector 2500 according to another embodiment of the present invention.
26 is a sectional view taken along line A-A 'in Fig.
27 is a cross-sectional view taken along line B-B 'in Fig.
Fig. 28 is an enlarged view of a portion E1 in Fig.
Fig. 29 is a perspective view of the electric dust collector 2500 of Fig. 25 with the charging section 510 removed.
Fig. 30 is an enlarged view of a portion E2 in Fig. 29;
FIG. 31 is a perspective view of gap holding portions 2561 and 2562 according to another embodiment shown in FIG.
32 is an enlarged view of a portion E3 in Fig.
Fig. 33 is an elevational view of the gap holding portions 2561 and 2562 shown in Fig.
34 is an enlarged view of a portion E4 in Fig.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

The electric dust collecting apparatus according to the present invention can be used as a partial device in an air conditioner or a vacuum cleaner capable of cooling / heating / air cleaning / humidifying, and can be used as a separate independent device for air cleaning. In the present embodiment, an electric dust collector mounted on an air conditioner is described, but the present invention is not limited thereto.

The reference direction expressed throughout the description and the drawings will be described as follows. The X-axis direction means a direction in which a plurality of films 540a of the dust collecting portion to be described later are alternately arranged, the Y-axis direction means the longitudinal direction of the plurality of films 540a, and the Z- Quot;). In the present embodiment, the X axis direction, the Y axis direction and the Z axis direction are perpendicular to each other. In the present embodiment, the Z-axis direction is referred to as a vertical direction (more specifically, the Z-axis arrow direction is upward and the Z-axis arrow opposite direction is downward), but the X-axis direction or the Y- Can be inclined at an angle other than perpendicular.

The 'potential' expressed below means the electric potential energy. The 'voltage' expressed below means a numerical value which means a difference of potential at two points.

FIG. 1 is a perspective view of an air conditioner according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view illustrating components of a humidification module 200 of FIG. Fig. 3 is an exploded perspective view of the air conditioner of Fig. 1, Fig. 4 is an exploded perspective view showing only the body 130 of Fig. 1, and Fig. 5 is an exploded perspective view to be.

1 to 5, an air conditioner according to an embodiment includes a clean module 100 and a humidification module 200 mounted on the clean module 100. [ The clean module 100 is mounted on the floor, and the humidification module 200 is mounted on the clean module 100.

The clean module 100 sucks outside air, filters the air, and provides filtered air to the humidification module 200. The clean module 100 removes foreign substances contained in the introduced outside air and discharges the purified air from which odor is removed to the humidifying module 200. The humidification module 200 receives the filtered air and humidifies the humidifying air to provide moisture, and discharges humidified air to the outside.

The humidification module 200 and the clean module 100 are separable from each other. The user can separate the humidification module 200 and the cleaning module 100 from each other and clean them. The user may remove the humidification module 200 from the cleaning module 100 and then supply water to the water tub 30 disposed therein. The user may supply water in a state where the humidification module 200 is stacked on the clean module 100.

The clean module 100 includes a suction passage 101 through which external air is sucked, and a filtering passage 102 through which the sucked air is filtered.

When the humidification module 200 stacks the clean module 100, a connection flow path 103 is formed to receive filtered air. A connection flow path formed on the side of the clean module 100 is defined as a clean connection flow path 104 and a connection flow path formed on the side of the humidification module 200 is defined as a humidification connection flow path 105.

The clean connection passage 104 or the humidification connection passage 105 may be formed to have a separate space. When the humidification module 200 is mounted on the clean module 100, the humidification module 200 and the clean module 100 may be separated from each other, (100), a connection flow path (103) is formed.

The humidification module 200 is provided with a humidification channel 106 for humidifying the filtered air passing through the clean module 100. The filtered air is humidified by receiving moisture while passing through the humidification channel 106. On the downstream side of the humidification passage 106, a discharge passage 107 is formed to guide the air handled by the cleaning module 100 and the humidification module 200 to be discharged to the outside.

In this embodiment, there is a part where the flow direction of the air is partially bent inside the clean module 100 and the humidification module 200, but the air flow direction A from the bottom to the top is maintained as a whole.

The cleaning module 100 includes a body 130 for guiding the external air sucked through the suction passage 101 to the humidification module 200 and a body 130 detachably installed on the body 130, A filter assembly 10 for filtering against outside air and an air blowing unit 20 disposed inside the body 130 and providing pressure against the air to be flowed.

The clean module 100 is installed on the base 112 and the clean module 100 is separated from the base 112 to form the suction passage 101. Since the clean module 100 is installed apart from the base 112, it is possible to suck outside air through the entire wide bottom side. The clean module 100 moves the outside air sucked from the lower side to the upper side in the vertical direction.

The body 130 forms an outer shape of the cleaning module 100.

The body 130 may be provided with a display module 160 for displaying the operating state of the humidifying / cleaning device to a user.

The body 130 has a circular cross section. A handle 129 is formed on the body 130.

A filter assembly (10) is detachably coupled to the body (130). The filter assembly 10 may be horizontally separated from the body 130. In the filter assembly 10, a plurality of filters are horizontally installed, and a plurality of filters are stacked in a vertical direction. A detailed description thereof will be described later.

A filter housing 140 is installed in the body 130 so that the filter assembly 10 is removably received. The filter housing 140 is fixedly disposed inside the body 130.

The filter housing (140) and the filter assembly (10) are combined to form a filtration channel (102). The upstream side of the filtration flow path 102 is connected to the suction flow path 101. The downstream side of the filtration flow path 102 is connected to the connection flow path 103 and specifically to the clean connection flow path 104.

A filter installation opening 133 is formed at one side of the body 130. The filter assembly (10) is inserted into the filter housing (140) through the filter installation opening (133). The filter assembly 10 includes a filter cover 413 that shields the filter installation opening 133.

A blowing housing 150 for guiding the air discharged from the blowing unit 20 to the humidifying module 200 is installed in the body 130. The blower housing 150 is positioned above the filter housing 140. The blowing housing 150 is fastened to the filter housing 140.

A blowing unit 20 is installed between the filter housing 140 and the blowing housing 150. The air blowing unit 20 provides a pressure to flow air.

And the outside air is sucked through the suction passage 101 in all directions 360 degrees. A bridge frame 115 is installed between the body 130 and the base 112 to separate the base 112 and the body 130 from each other. The bridge frame 115 joins the base 112 and the body 130 and supports the body 130.

The outside air flows through the bridge frame 115 to the inlet 111. A plurality of bridges 114 are vertically formed on the bridge frame 115. It is preferable that the number of the bridges 114 is closely arranged so that the user's fingers do not enter the inlet 111. Considering only the air resistance side, it is desirable to minimize the number of the bridges 114.

The filter assembly 10 is disposed orthogonal to the flow of air. The filter assembly 10 is installed to cross the filtration channel 102. The filtration channel 102 is formed in a vertical direction, and the filter assembly 10 is installed in a horizontal direction. When the filter assembly 10 is installed so as to cross the filtration channel 102, the filter assembly 10 sufficiently functions.

The filtration channel 102 is formed from the lower side to the upper side in the direction of gravity. The flow direction is not switched but is formed as straight as possible.

The air sucked through the suction passage (101) flows into the air blowing unit (20) through the inside of the filter housing (140). The air blowing unit 20 is disposed above the filter housing 140 and sucks air in the filtration flow path 102 and discharges the air to the humidification module 200.

The air blowing unit 20 is composed of a blowing motor 22 and a blowing fan 24. The blowing motor 22 and the blowing fan 24 are all disposed between the blowing housing 150 and the filter housing 140 and the blowing motor 22 is disposed on the upper side and the blowing fan 24 Is disposed on the lower side.

The air blowing motor 22 is installed in the air blowing housing 150 and is supported by the air blowing housing 150. The blowing fan 24 is assembled with the blowing motor 22 and is rotated by receiving the driving force of the blowing motor 22. The blowing fan 24 is disposed on the filter housing 140 side.

The ventilation motor 22 may be at least partly inserted into the ventilation housing 150 and the ventilation fan 24 may be at least partially inserted into the filter housing 140 .

The blowing fan 24 sucks the filtered air in the center, and then discharges the filtered air in the circumferential direction. In the present embodiment, the blowing motor 22 is positioned above the blowing fan 24 so as not to generate air and resistance. The air blowing motor 22 is installed out of the air flow path.

The air discharged from the air blowing fan 24 flows to the upper humidifying module 200 along the filter housing 140 and the air blowing housing 150.

A water tank 30 is disposed above the air blowing unit 20 inside the body 130. The body 130 has a water tank insertion space recessed from the upper side so that the water tank 30 can be inserted upward.

A humidifying channel inlet 123 through which air can pass is formed on the circumferential surface of the water tank insertion space, and the humidifying channel inlet 123 communicates with the inside of the water tank 30. In this embodiment, the humidifying medium 50 containing moisture is disposed inside the humidifying flow path inlet 123.

The water tank 30 is provided with an aberration unit 40 which sucks water in the water tank, sucks the sucked water upward, and discharges the pumped water outward. An aberration motor 42, which is a power source of the aberration unit 40, is installed in the lower part of the water tank 30. The aberration motor 42 is physically separated from the blowing motor 22. The air blowing motor 22 and the aberration motor 42 can be independently controlled.

The humidification module 200 includes a visual body 210 formed of a material detachably stacked and viewed on the clean module 100 and a top cover assembly 230 detachably coupled to the visual body 210 . In this embodiment, a discharge passage 107 is formed between the top cover assembly 230 and the visual body 210. The discharge passage 107 is connected to the downstream side of the humidification flow path 106. The connection passage (103) is connected to the upstream side of the humidification channel (106). The top cover assembly 230 is formed with a water supply passage 109 capable of supplying water from the outside.

6 is a perspective view illustrating the body 130 of FIG. 1 and the removable filter assembly 10. FIG. 7 is a perspective view of the filter assembly 10 of FIG. 8 is a longitudinal sectional view of the filter assembly 10 of Fig. 9 is an exploded perspective view of the filter assembly 10 of FIG.

6 to 7, a filter installation opening 133 is formed on one side of the outer circumferential surface of the body 130 so that the inner space of the filter housing 140 communicates with the outer space. The filter assembly 10 is slid in the direction in which the filter installation opening 133 is inserted and drawn out.

A stepped guide (not shown) may be formed on both sides of the inner surface of the filter housing 140 to guide the sliding of the filter assembly 10. The guide may include at least one top surface providing a friction surface that supports the filter assembly 10, or may include at least one roller or bearing.

The left and right side surfaces of the filter housing 140 (the side on which the guides are disposed) constrain the flow in the left and right directions of the filter assembly 10 and allow the filter assembly 10 to flow only in the forward and backward directions It serves as a guide.

At least one of the left and right sides of the filter housing 140 is provided with a power terminal (not shown) for supplying power to the electric dust collector 500 to be described later and a ground terminal (not shown) for providing ground. A power source terminal for supplying power to the charging unit 510 and a power source terminal for supplying power to the dust collecting unit 540 to be described later may be separately provided. A ground terminal for providing ground to the charging unit 510 to be described later and a ground terminal for providing ground to the dust collecting unit 540 to be described later may be separately provided.

Power receiving terminals 518 and 548 and ground receiving terminals 519 and 549 are provided on the left and right sides of the electric dust collector 500 at points corresponding to the power terminal and the ground terminal. That is, only when the electric dust collector 500 is completely inserted into the body 130, the power supply terminals and the ground terminals are brought into contact with the power receiving terminals 518 and 548 and the ground receiving terminals 519 and 549, And ground receiving terminals 519 and 549 are disposed.

The power receiving terminals 518 and 548 include a charging section power receiving terminal 518 for connecting the power source to the charging section 510 and a dust collecting section power receiving terminal 548 for connecting the power source to the dust collecting section 540. The ground receiving terminals 519 and 549 include a charging section ground receiving terminal 519 for connecting the ground to the charging section 510 and a dust collecting section ground receiving terminal 549 for connecting the ground to the dust collecting section 540.

The charging section power receiving terminal 518 and the dust collecting section power receiving terminal 548 may be disposed on the same horizontal plane on the electrostatic precipitator 500 in a diagonal direction. The charging ground receiving terminals 519 and the dust collecting section ground receiving terminals 549 may be disposed on the same horizontal plane on the electrostatic precipitator 500 in a diagonal direction.

A dust sensor 135 may be installed on the body 130. The dust detection sensor 135 includes at least a portion of the air which is exposed to outside air. The dust detection sensor 135 senses the dust concentration of the outside air.

The dust detecting sensor 135 is disposed on the outer circumferential surface of the body 130. The dust detection sensor 135 is disposed on the upper side of the filter installation opening 133 so that the filter assembly 10 is visually obscured by the filter cover 413 in a state where the filter assembly 10 is engaged with the body 130. In this embodiment, .

The upper portion of the filter installation opening 133 is formed with a depression 134 in which the outer circumferential surface of the body 130 is recessed by a distance corresponding to the thickness of the filter cover 413, And the filter cover 413 is engaged with the depression 134 when the filter cover 413 is coupled to the body 130.

It is possible to detect dust on the part of the filter cover 413 corresponding to the position of the dust detection sensor 135 so that the outside air is supplied to the dust detection sensor 135 even when the filter cover 413 covers the dust detection sensor 135. [ An opening 413a is formed. In this embodiment, the dust sensing opening 413a is formed as a horizontally long slit, and a plurality of the dust sensing opening 413a are spaced apart from each other by a predetermined distance.

The filter assembly 10 includes a mesh filter 300, an electrostatic precipitator 500, and a photocatalytic filter 600 that are sequentially disposed from upstream to downstream. In the mesh filter 300, air passes through the mesh-like mesh, and foreign matter in the air is filtered. The electric dust collector 500 charges the dust particles in the air and collects the charged dust particles to filter the air. The photocatalytic filter 600 physically / chemically removes odor components in the air by applying a photocatalyst having a deodorizing capability to the porous base. In this embodiment, the mesh filter 300 is disposed at the lowermost part, the electric dust collector 500 is disposed above the mesh filter 300, and the photocatalytic filter 600 is disposed at the uppermost part.

The filter assembly 10 includes a drawer 400 that supports at least a portion of the filter assembly 10 and slides along the guide of the filter housing 140. The drawer 400 includes the filter cover 413 disposed on the front surface thereof.

A filter cover knob 413b is formed in the center of the front surface of the filter cover 413 so that the drawer 400 can be pulled. The filter cover knob 413b is formed by being recessed rearward from the front surface of the filter cover 413, and the lower surface of the right and left upper and lower surfaces exposed by being recessed backward is formed to be depressed downward.

In this embodiment, the electrostatic precipitator 500 supports the photocatalytic filter 600, and the drawer 400 supports the electrostatic precipitator 500. The mesh filter 300 is disposed below the drawer 400 and is inserted or withdrawn independently of the drawer 400.

The mesh filter 300 includes a mesh filter cover 313 which forms a continuous surface appearance with the front surface of the filter cover 413 in a state in which both the body 130 and the filter cover 413 are combined. A mesh filter cover knob 313a which is downwardly recessed is formed on the upper surface forming the thickness of the mesh filter cover 313.

At least a part of the lower end of the filter cover 413 is exposed to the outside so that the mesh filter cover knob 313a is exposed to the outside in a state where the mesh filter 300, the body 130, A depressed handle exposed portion 413c is formed. The front and bottom sides of the handle exposed portion 413c are opened. The handle exposed portion 413c can be recessed from the front surface of the filter cover 413 to the rear end of the mesh filter cover handle 313a. The user can put his / her hand into the handle exposing portion 413c and put his hand on the mesh filter cover handle 313a.

The mesh filter 300 includes a mesh frame 315 arranged around the filtration channel 102 on the horizontal plane behind the mesh filter cover 313 and a filter frame 315 provided on the inner periphery provided by the mesh frame 315, 102, and a mesh sub-frame 316 that divides the horizontal cross-section of the frame. The mesh auxiliary frame 316 divides the horizontal cross section of the filtration channel 102 into a plurality of channels.

The mesh filter 300 includes a mesh 318 that filters and collects foreign matter in the passing air. The mesh 318 is supported by the mesh frame 315 and the mesh assistance frame 316. The mesh 318 is disposed on the same plane as the mesh frame 315 and the mesh auxiliary frame 316. The foreign matter collected by the mesh 318 can be removed by separating and cleaning the mesh filter 300 from the body 130.

The left and right side surfaces of the drawer 400 are provided with a slider 414 which is supported by the guide of the filter housing 140 and is slidably guided. The slider 414 may include rails or rollers.

Drawer 400 includes an electrostatic precipitator seat 415 that provides an upper surface for supporting electrostatic precipitator 500. The electrostatic precipitator mounting portion 415 may be formed on the left and right sides of the drawer 400. A part of the lower surface of the electrostatic precipitator 500 comes into contact with the upper surface of the stepped portion 415 to support the electrostatic precipitator 500. [

The electric dust collector 500 includes a case 501, 502 that forms an appearance. An electric dust collecting apparatus handle 503 is formed in the cases 501 and 502 so that the electric dust collecting apparatus 500 can be separated from the drawer 400 and lifted. The electric dust collecting apparatus handle 503 may be formed as a pair on the left and right sides of the case 501, 502. The handle 503 of the electric dust collector may be formed by sinking the surfaces of the cases 501 and 502.

The electric dust collector 500 includes a charging unit 510 for charging dust particles in the air and a dust collecting unit 540 for collecting the charged dust particles in the charging unit 510. The charging unit 510 is disposed on the lower side and the dust collecting unit 540 is disposed on the upper side.

The cases 501 and 502 include a charging case 501 for accommodating the charging unit 510 therein and a dust collecting case 502 for accommodating the dust collecting unit 540 therein. The charging case 501 is disposed on the lower side, and the dust collecting case 502 is disposed on the upper side. The space for accommodating the charging unit 510 and the space for accommodating the dust collecting unit 540 are formed to be connected to each other.

A charging case inlet 506 is formed on the lower side of the charging case 501 so as to allow air to flow into the inside of the electrostatic precipitator 500. A dust-collecting case outlet 507 is formed on the upper surface of the dust-collecting case 502 so as to allow air to flow out from the inside of the electrostatic precipitator 500.

The photocatalytic filter 600 includes a photocatalytic filter frame 603 forming a periphery on the horizontal end surface of the filtration channel 102 and a photocatalytic action portion 605 supported by the photocatalytic filter frame 603. The photocatalyst operating unit 605 may be manufactured by applying a known photocatalyst having a deodorizing capability to a base member having a cavity forming a part of the filtration channel 102 or by forming a gap in a member having photocatalytic properties It is possible.

In this embodiment, the photocatalyst includes activated carbon. The activated carbon can cause odor particles to be collected in the photocatalyst operating portion 605 by the physical adhesive force. Activated carbon or other photocatalyst can be used to collect the odor particles in the photocatalyst operating portion 605 through the pyrometallurgical coupling. The photocatalyst filter 600 may be separated from the body 130 and the filter assembly 10 and exposed to sunlight or the like to remove the odor particles collected in the photocatalyst operating portion 605.

The overall air flow direction (A) is as follows. Air introduced into the air conditioner from the outside through the case suction flow path (101) flows into the filtration flow path (102). The air that has flowed into the filtration flow path 102 passes through the mesh 318 and then flows into the charging case 501 through the charging case inlet 506. The air that has flowed into the internal space of the charging case 501 sequentially flows through the charging unit 510 and the dust collecting unit 540 and then flows upward through the dust case outlet 507. [ The air that has flowed upward flows through the photocatalyst operating portion 605.

In another embodiment, the arrangement of each component may be changed and each component may be arranged laterally. In this case as well, the air is set so as to be in the direction from the charging section 510 to the dust collecting section 540.

FIG. 10 is a perspective view showing the inside heavy charging unit 510 of the electric dust collector 500 of FIG. 9, and FIG. 11 is an internal elevational view of the charging unit 510 of FIG. 10 viewed from above.

The charging unit 510 according to the present embodiment will be described with reference to FIGS. 10 and 11. FIG. The charging unit 510 includes a wire discharge electrode 521 to which a high voltage is applied and an opposite electrode plate 523 to be spaced apart from the wire discharge electrode 521. The high voltage is a numerical value such that a discharge is generated in the wire discharge electrode 521 because the voltage between the wire discharge electrode 521 and the counter electrode plate 523 is very high.

When a voltage is applied to the wire discharge electrode 521, a corona discharge is generated between the wire discharge electrode 521 and the counter electrode plate 523. It can be discharged to ionize molecules in the air, and anions such as OH-, O-, and cations such as H + can be generated. The generated ions charge the dust particles in the air. Anions can charge the dust particles to the cathode by providing electrons to the dust particles. Cations can attract electrons from dust particles and charge the dust particles to the anode.

The counter electrode plates 523 may be arranged in a plurality. The counter electrode plate 523 may be disposed to face each other with the wire discharge electrode 521 therebetween.

Both ends of the plurality of counter electrode plates 523 are connected to each other by an electrode plate connecting portion 524. The electrode plate connecting portions 524 are disposed on a horizontal plane, and the plurality of counter electrode plates 523 are disposed on a plane perpendicular to the electrode plate connecting portions 524.

The electrode plate connecting portion 524 and the plurality of counter electrode plates 523 can be integrally formed by cutting the center of the plate-shaped metal and bending it at 90 degrees. In other words, the both ends of the plate-shaped metal are left to be the electrode plate connecting portion 524, the central portion of the plate-shaped metal is cut into a length corresponding to one long side of the counter electrode plate 523, The incision was made by cutting 90 degrees at both ends of the portion cut by the length of one side of the long side at a length corresponding to both sides of the short side of the one side, and then incised (cut at 90 degrees at each end and a portion cut by one long side) Shaped metal portion is bent at 90 degrees, the folded portion becomes the counter electrode plate 523. [

The plurality of wire discharge electrodes 521 may be arranged. A plurality of wire discharge electrodes 521 may be arranged so as to be spaced apart from each other. The counter electrode plate 523 may be disposed between the plurality of wire discharge electrodes 521 in parallel with the wire discharge electrode 521. [

The plurality of wire discharge electrodes 521 may be connected in series with each other. That is, one wire member can constitute a plurality of wire discharge electrodes 521 continuously. In this embodiment, the wire discharge electrode 521 is formed such that one wire member extends from one wire support portion 522a to the other wire support portion 522b to form one wire discharge electrode 521, The wire member bent at the support portion 522b extends to the wire support portion 522b adjacent to the wire support portion 522b at the other side to form a wire serial connection portion (not shown), and the adjacent wire support portion 522b extend to the adjacent wire support portion 522a on the same side as the one wire support portion 522a to constitute another wire discharge electrode 521. [ In this way, the wire discharge electrode 521 and the wire series connection unit are alternately connected to each other with the wire support portions 522a disposed at predetermined intervals on both sides thereof as supporting points.

The wire support portion 522 includes an elongated vertical member in the air flow direction, and the wire member is supported on the side of the vertical member and can be folded.

In the present embodiment, a plurality of wire discharge electrodes 551 and a plurality of counter electrode plates 523 are alternately arranged in a direction perpendicular to the air flow direction A. A plurality of wire discharge electrodes 551 and a plurality of counter electrode plates 523 are disposed on the downstream side of the charging case inlet 506.

The electrode plate connection portion 524 is disposed at both ends of the plurality of counter electrode plates 523 so as to extend in a direction perpendicular to the plurality of counter electrode plates 523. The wire series connection portion is disposed at both ends of the plurality of wire discharge electrodes 521 so as to extend in a direction perpendicular to the plurality of wire discharge electrodes 521.

It is preferable that the plurality of wire discharge electrodes 521 are disposed at positions near the upstream side among the spaces between the plurality of counter electrode plates 523. The wire series connection portion is disposed on the same plane as the plurality of wire discharge electrodes 521. The electrode plate connecting portion 524 is preferably disposed on the plane of the downstream end of the plurality of counter electrode plates 523 so that the wire series connecting portion and the electrode plate connecting portion 524 are further separated from each other. This is because a high voltage is applied to the wire series connection portion and the electrode plate connection portion 524 is also made of a metal material electrically connected to the plurality of counter electrode plates 523 so that a spark occurs between the wire series connection portion and the electrode plate connection portion 524 In order to reduce the probability.

The wire discharge electrode 521 and the counter electrode plate 523 are fixed to the charging case 501. Both ends of one wire member are fixedly connected to the charging case 501 at both ends of the wire discharge electrode 521, and a high voltage is applied to the wire member through the fixed connection point.

The charging section 510 includes a spark preventing section 525 which supports a plurality of counter electrode plates 523 and is fixed to the charging case 501. The spark preventing portion 525 fixes the electrode plate connecting portion 524.

The spark preventing portion 525 is disposed at each end of each of the plurality of counter electrode plates 523. The spark preventing portion 525 includes an electrode plate connecting portion 524 disposed up and down and a shielding member (not shown) interposed between the wire connecting portions. The shielding member may be a plate-shaped plate member. The shielding member is preferably made of an insulating material. The shielding member serves to reduce the probability of sparking between the wire series connection part and the electrode plate connection part 524.

The spark preventing portion 525 is formed with a groove into which the electrode plate connecting portion 524 is inserted. The depression direction of the groove into which the electrode plate connection portion 524 is inserted is the longitudinal direction of the plurality of counter electrode plates 523. The members forming the grooves into which the electrode plate connection portions 524 are inserted cover the upper and lower surfaces of the electrode plate connection portions 524. The member that surrounds the lower surface of the electrode plate connecting portion 524 may be constituted by the shielding member.

The charging section according to another embodiment includes at least one ion generator (not shown) for generating ions. The ion generators may be disposed apart from each other in a direction perpendicular to the air flow direction A. The ion generator can charge dust particles in the air. The ion generator includes a carbon fiber electrode (not shown) for corona discharge. The carbon fiber electrode may be formed in a brush shape. The carbon fiber electrode may be formed by bundling a plurality of ultra fine carbon fibers into a bundle of brushes.

12 is a perspective view showing the dust collecting part 540 of the electric dust collecting apparatus 500 of FIG. 13 is an exploded perspective view in which the dust-collecting case 502, the base-spacing portion 561, the plurality of films 540a, and the loop-spacing portion 566 shown in Fig. 12 are separated. Fig. 14 is a schematic cross-sectional view showing the arrangement direction X of the plurality of films 540a in Fig. 13, Fig. 15 is a plan view showing a further schematic view of the plurality of films 540a in Fig. to be. FIG. 16 is a perspective view showing the structure of the first film 541 in FIG. 12, and FIG. 17 is a perspective view showing the structure of the second film 542 in FIG.

The dust collecting unit 540 includes a film 540a coated with an insulating layer as a conductive layer and a fixing unit 540b fixing the film 540a inside the dust collecting case 502.

The films 540a may be arranged in a plurality. The fixing portion 540b fixes the plurality of films 540a inside the dust-collecting case 502. [

The films 540a may be arranged in plural to face each other to form a gap S therebetween. The plurality of films 540a are in the form of strips each having a length in the film longitudinal direction Y longer than the film width direction Z and arranged in a line to form a group of arrangements.

The fixing portion 540b includes spacing portions 561 and 566 that are disposed on at least one of the widthwise sides of the arrangement group to hold the gap S therebetween.

The gap holding portions 561 and 566 are fixed inside the cases 501 and 502. In this embodiment, the gap holding portions 561 and 566 are fixed only to the dust collecting case 502. [ The gap holding portions 561 and 566 can support a plurality of films 540a.

The gap maintaining portion may include a loop gap maintaining portion 566 disposed on a side farther from the inner side of the dust collecting case 502 than the width direction Z of the array group. The gap holding portions 561 and 566 include a base gap holding portion 561 disposed on one side of the width direction Z and a loop gap holding portion 566 disposed on the other side in the width direction Z of the film can do.

In the present embodiment, when defining one direction of the film width direction Z as an air flow direction, a dust case outlet 507 through which air passes is formed on one side of the dust case 502, 540a are arranged such that one side of the film in the width direction Z is facing the outlet 507. [

The fixing portion 540b includes a molding portion 578 for fixing the plurality of films 540a by curing the predetermined paste while a part of the plurality of films is locked in a predetermined paste.

The plurality of films 540a include a plurality of first films 541 to which a high potential is applied to the conductive layer 551a and a plurality of second films 541 to which a low potential is applied to the conductive layer 551a 542). That is, the plurality of films 540a are provided by coating the conductive layer with two insulating layers on both sides with the conductive layers disposed therebetween.

The plurality of first films 541 and the plurality of second films 542 are alternately arranged. The plurality of first films 541 and the plurality of second films 542 are alternately arranged to face each other to form a gap S therebetween.

 The plurality of films 540a are arranged so that the width direction Z is the vertical direction, but the present invention is not limited thereto. The plurality of films 540a may be arranged in parallel so that the longitudinal directions Y coincide with each other. A plurality of films 540a are arranged to form a gap S in a film width direction Z and a direction X perpendicular to the film longitudinal direction Y. [ In the present embodiment, about 20 to 30 first films 541 and second films 542 are alternately arranged.

The dust collecting unit 540 includes a voltage source 581 for generating a high potential and a second conductor 583 for connecting the conductive layer 551b of the second film 542 and the negative electrode of the voltage source 581, And a first conductor 584 for connecting the positive electrode of the voltage source 581 to the conductive layer 551a of the second electrode 541. The second conductor 583 may be connected to the ground 582.

The conductive layer 551a of the first film 541 may be provided so as to be connected to the first conductive line 584 and have a relatively high electric potential relative to the conductive layer 551a of the first film 541. [ The conductive layer 551b of the first film 542 may be connected to the second conductive line 583 to have a relatively low potential relative to the conductive layer 551a of the first film 541. [ The voltage source 581 may be provided so that the voltage between the conductive layer 551a of the first film 541 and the conductive layer 551b of the second film 542 is about 7 to 9 kV.

Referring to Figs. 16 and 17, the first film 541 and the second film 542 are elongated in a strip shape. The strip-shaped length of the first film 541 and the second film 542 may be about 200 to 250 mm. The entirety of the first film 541 and the second film 542 may be formed into a flat plate shape. The first film 541 and the second film 542 may be formed so as to be at least partially bent in the both-side direction X. [

The conductive layer of the plurality of films 540a may be made of a carbon material. The conductive layer may have a thickness of 10-100 μm. The conductive layer 551a of the first film 541 constitutes a high potential electrode and the conductive layer 551b of the second film 542 constitutes a low potential electrode.

The pair of insulating layers apply the remaining portion except the part of the conductive layer with the conductive layer interposed therebetween. The insulating layer may be made of a material such as PP, PET, PEN, PU or the like and may include a nanofiller such as TiO 2, Al 2 O 3, SiO 2, etc., and the thickness may be 100-1500 μm.

Wherein the conductive layer is provided in a carbon pattern screen-printed on one surface of one of the pair of insulating layers, and the other of the pair of insulating layers covers the other except for a part of the carbon pattern, It can be adhered to the insulating layer.

That is, the conductive layer of the film 540a is partially exposed to the outside, and the remainder of the conductive layer of the film 540a is exposed to the outside by the insulating layer 557. The film 540a includes exposed portions 557 and 558, It is enclosed.

The predetermined paste may be a conductive paste having electrical conductivity, and the molding portion 578 may be an electrode connection portion 578 having electrical conductivity. In this case, the molding part 578 functions not only as a fixing function of the film 540a, but also as an electric line for applying power to the conductive layer of the film 540a. The molding part 578, Is referred to as an electrode connection portion 578 hereinafter.

The electrode connection portion 578 hardens the conductive paste to fix the film 540a while the exposed portions 557 and 558 are locked in the conductive paste. The electrode connection part 578 is connected to a voltage source 581 to apply a voltage to the conductive layer of the film 540a.

The electrode connection portion 578 includes a first electrode connection portion 578a that constitutes a portion of the first lead wire 584 which contacts the plurality of films 540a and a plurality of films 540a And a second electrode connection portion 578b constituting a portion contacting the first electrode connection portion 578b.

The exposed portions 557 and 558 are respectively formed at one end in the longitudinal direction Y of the plurality of first films 541 and at the other end in the longitudinal direction Y of the plurality of second films 542. The first electrode connection portion 578a extends in the film arrangement direction X at one end of the first film 541 in the longitudinal direction Y and the second electrode connection portion 578b extends in the film arrangement direction X, And extends in the film arrangement direction X at the other end in the longitudinal direction Y of the film 542. [

The exposed portion 557 of the conductive film 551a of the first film 541 without being surrounded by the insulating layer 552a constitutes a high potential connection portion 557. [ The high potential connection 557 contacts the first lead 584. That is, the high potential connection portion 557 contacts the first electrode connection portion 578a constituting a part of the first conductive line 584. A high potential is applied to the conductive layer 551a of the first film 541 through the high potential connection portion 557. [

The exposed portion 558 of the conductive film 551b of the second film 542 without being surrounded by the insulating layer 552b constitutes a low potential connecting portion 558. [ The low potential connection 558 contacts the second lead 583. That is, the low potential connection part 558 contacts the second electrode connection part 578b constituting a part of the second conductive line 583. A low electric potential is applied to the conductive layer 551b of the second film 542 through the low potential connection portion 558. [

A relatively high potential is applied to the conductive layer 551a of the first film 541 and a relatively low potential is applied to the conductive layer 551b of the second film 542, An electric field is generated. The dust particles charged in the charging section 510 receive electrical force in the electric field in accordance with the charged polarity and are applied to the insulating layer 552a of the first film 541 or the insulating layer 552b of the second film 542 Respectively.

The film 540a includes hooking hooks 555 extending in at least one end portion of the longitudinal direction Y and bent in the width direction Z. [

In the present embodiment, the plurality of films 540a include hooking hooks 555 extending in the film width direction (Z) at both ends in the longitudinal direction (Y) and bent in the film width direction (Z). The hooking hook 555 may be formed at both ends of the first film 541 and the second film 542 in the longitudinal direction Y. [

The exposed portions 557 and 558 are formed in the hook. The hooking hook 555 is separated from the hooking hook 555a to which the conductive layer is exposed and the hooking hook 555b to which the conductive layer is not exposed. The exposed portion 557 of the plurality of first films 541 is formed in the hooking hook 555a at one end in the longitudinal direction Y and the exposed portion 558 of the plurality of second films 542 is formed in the length And is formed in the hooking hook 555a at the other end in the Y direction.

The plurality of first films 541 are provided such that the conductive layer 551a is exposed only at the hooks 555a at one end of the both ends and the plurality of second films 542 are provided at the other end So that the conductive layer 551b is exposed only in the hooking hook 555a. That is, the high-potential connecting portions 557 provided on the plurality of first films 541 are formed only on the hooks 555a formed on one of the two ends of the first films 541, (558) are formed only on the hooks (555a) formed on the other of the two ends.

The film 540a is formed with an engaging groove 556 which is depressed in the width direction Z at at least one end of both ends in the longitudinal direction Y. [ In this embodiment, the latching grooves 556 are formed at both ends in the longitudinal direction Y of the plurality of films 540a.

One side of the latching hook 555 can form one side of the latching groove 556. The engaging groove 556 may have a slit shape with one side opened.

The fixing portion 540b includes a mounting rib 572 coupled to the dust-collecting case 502 and inserted into the locking groove 556. [ The latching groove 556 and the latching rib 572 are formed to be engaged with each other. The mounting ribs 572 are ribs protruding from the dust-collecting case 502 in the direction in which the latching grooves 556 are formed. Details of this will be described later.

FIG. 18 is an enlarged perspective view of a structure in which the base space retaining portion 561 and the loop space retaining portion 566 of FIG. 12 are combined with the plurality of films 540a and the dust collecting case 502. FIG. 19 is a partially enlarged perspective view of the base-spacing portion 561 of Fig. 20 is a partial cross-sectional view of the base-spacing portion 561 of Fig. 18 cut in the film arrangement direction X. Fig. 21 is a partially enlarged perspective view of the loop gap retaining portion 566 in Fig. 22 is a partial cross-sectional view of the loop gap retaining portion 566 of Fig. 18 cut in the film arrangement direction X. Fig.

18 to 22, the gap maintaining portions 561 and 566 may be formed of a plurality of vertical portions (not shown) inserted into the gaps S from the side where the gap holding portions 561 and 566 of the arrangement group are disposed, Bars 564 and 568. [ The plurality of vertical bars 564 and 568 are elongated in a bar insertion direction. A plurality of vertical bars 564 and 568 separate the plurality of films 540a from each other to maintain the gap S therebetween.

The plurality of vertical bars 564 and 568 may be inserted into the gap S so as to extend beyond the center of the width of the film 540a. Thereby, the adjacent film 540a and the gap S can be kept constant not only at the edge of the film 540a but also at the center of the film 540a.

The base spacing portion 561 includes a plurality of base vertical bars 564 inserted into the gap S from one side in the width direction Z and the loop spacing portion 566 has a width And a plurality of loop vertical bars 568 inserted into the gaps S from the other side of the direction Z. [ That is, the plurality of vertical bars 564 and 568 may include a plurality of base vertical bars 564 and a plurality of loop vertical bars 568.

The vertical bars 564 and 568 may be formed with protrusions 565 and 569 projecting in the plane direction of the film 540a so that the clearance of the film 540a may be reduced. This narrows the gap through which the film 540a can be disposed between the plurality of vertical bars 564 and 568 so that the clearance of the film 540a after the film 540a is disposed can be significantly reduced .

At least one of the base spacing portion 561 and the loop spacing portion 566 is plural. The base spacing portion 561 and the loop spacing portion 566 may be alternately spaced along the longitudinal direction Y of the film. When the plurality of base vertical bars 564 and the plurality of loop vertical bars 568 are inserted into the gap S so as to extend beyond the center of the width of the film 540a, A plurality of base vertical bars 564 and a plurality of loop vertical bars 568 alternately extending from one side and the other side in the width direction Z are disposed in superposition with each other, The adjacent film 540a and the gap S can be uniformly maintained even in the central portion of the film 540a.

The base spacing portion 561 includes a base bar 562 disposed on one side of the array of film groups in the film width direction Z and extending in the arrangement direction X of the array group, A plurality of base vertical bars 564 inserted into the gap S from the one side of the base Z and a fastening portion 563 for fixing the base spacing portion 561 to the dust case 502, . In the present embodiment, the one side in the film width direction Z is the upward direction, and the base bar 562 is disposed on the upper side of the plurality of films 540a.

The base bar 562 supports the beginning of the plurality of base vertical bars 564.

The base bar 562 may be disposed to divide the dust-collecting case outlet 507. One side of the base bar 562 in the film width direction Z looks at the direction in which the air flows out from the gap S and the other side of the base bar 562 in the film width direction Z ).

The base bar 562 may be formed of a bar-shaped member. The base bar 562 is a member extending along the film arrangement direction X.

A groove can be formed at one side of the film 540a in the width direction Z to allow the base bar 562 to be partially inserted therein. In this case, the base bar 562 directly functions to fix the film 540a.

In this embodiment, fastening portions 563 are formed at both ends of the base bar 562 in the film arrangement direction X, respectively.

At least one of the coupling part 563 and the dust-collecting case 502 has a fastening structure and the other has a structure corresponding to the fastening structure. In the present embodiment, a base hook 503a is formed on the inner side in the direction in which the outlet 507 of the dust-collecting case 502 is formed.

The fastening portion 563 is provided with a fastening hole 563a in which the base hook 503a is inserted and fastened to the fastening plate 563b. The fastening plate 563b is disposed on the horizontal plane and closely contacts the inner surface of the dust-collecting case 502. [ The fastening plate 563b and the base bar 562 can be disposed on the same plane.

The base ends of the plurality of base vertical bars 564 are coupled to the base bars 562, respectively. The ends of the plurality of base vertical bars 564 are formed as free ends.

The plurality of base vertical bars 564 may be formed to have the same length. The horizontal cross section of the base vertical bar 564 may be a rectangular shape having a longer film length direction Y than the film arrangement direction X, respectively.

The plurality of base vertical bars 564 are inserted into the gap S beyond the center of the width of the plurality of films 540a. That is, the length of the plurality of base vertical bars 564 is greater than half the length of the width of the plurality of films 540a. The length of the plurality of base vertical bars 564 may be less than or equal to the width of the plurality of films 540a.

Each base vertical bar 564 is disposed alternately with each film 540a. One film 540a is disposed between two adjacent base vertical bars 564 formed in one base gap retaining portion 561. [ However, the film 540a at both ends of the film arrangement direction X among the plurality of films 540a has the base vertical bar 564 positioned only in one lateral direction and the base vertical bar 564 positioned in the other lateral direction . ≪ / RTI >

The plurality of base vertical bars 564 may be formed with protrusions 565 protruding in the plane direction of the film so that the clearance of the film is reduced.

In this embodiment, the projection 565 may be a hemispherically protruding shape, but it need not be limited thereto.

The protrusions 565 may protrude from only one of both side surfaces of the plurality of base vertical bars 564 in the film arrangement direction X and may be formed on both sides of the film arrangement direction X of the plurality of base vertical bars 564 As shown in FIG. In the latter case, the film 540a is disposed between the projections 565 projecting in one direction from one of the base vertical bars 564 and the projections 565 projecting in the other direction from the adjacent base vertical bars 564 .

A protrusion 565 formed to be disposed at the center of the width direction Z of the film 540a may be provided. The projections 565 may be arranged on the plurality of base vertical bars 564 so as to be spaced along the width direction Z of the film.

In Fig. 20, a part of the plurality of projections 565 is shown. In this embodiment, the protrusions 565a, 565b, and 565c protruding from one side of the both sides of the film arrangement direction X of the plurality of base vertical bars 564 and the protrusions 565d, 565e, . The protrusions 565c and 565d formed at the front end of the plurality of base vertical bars 564 and the protrusions 565b and 565e formed at the center and the protrusions 565a and 565f formed at the end of the base perpendicular bar 564 extend in the width direction Z of the film, Are spaced apart from each other.

The loop gap retaining portion 566 may include a loop body 567 which surrounds both sides of the arrangement direction X of the arrangement group and the other side of the film width direction Z in a C shape. Alternatively, the loop gap retaining portion 566 may include a loop body 567 that surrounds both ends of the arrangement group X in the array direction and the inner side and the far side of the dust collection case in a C-shape. In the present embodiment, the other side or the far side is the downward direction, and the loop body 567 is disposed below the plurality of films 540a.

A group of arrangements of the films 540a is arranged in a space between the loop body 567 and the dust collecting case 502. The loop bodies 567 on the outer side of the array group are arranged such that the overall shape of the array group is maintained, .

The loop gap retainer 566 includes a plurality of loop vertical bars 568 that are inserted into the gaps S from the loop body 567, respectively.

The loop body 567 supports the beginning of the plurality of loop vertical bars 568.

The loop body 567 includes a loop bar 5671 extending in the array direction X of the array group while being in contact with the array group. Loop bar 5671 supports the beginning of a plurality of loop vertical bars 568.

A loop bar 5671 is disposed between the plurality of films 540a and the plurality of counter electrode plates 523. One side of the loop bar 5671 is in contact with the plurality of films 540a and the other side of the loop bar 5671 in the film width direction Z is in contact with the plurality of opposing electrode plates 523 have. The array of the plurality of films 540a and the array of the plurality of counter electrode plates 523 are spaced apart from each other by a distance corresponding to the thickness of the loop bars 5671 in the film width direction (Z). The loop bar 5671 is disposed between the plurality of films 540a and the counter electrode plate 523 to hold the plurality of films 540a and the counter electrode plate 523 at a predetermined distance.

A groove may be formed in the other side of the film 540a in the width direction Z so that the loop bar 5671 can be partially inserted and hooked. In this case, the loop bar 5671 directly functions to fix the film 540a.

The loop bar 5671 may be formed of a bar-shaped member. The loop bar 5671 is a member extending along the film arrangement direction X.

The loop bar 5671 may include at least one section enlarging section 5671a which is larger than the other sections of thickness. The cross-sectional enlargement portion 5671a may be provided one by one at equal points of the loop bars 5671. The section enlarging portion 5671a increases the moment rigidity of the loop bar 5671. [

The thickness in the film width direction Z is substantially equal to the thickness in the other partial film width direction Z of the loop bar 5671 and the thickness in the film length direction Y is equal to the thickness of the loop bar 5671. [ (Y) thickness of the other portion of the film. A plurality of opposing electrode plates 523 are brought into contact with the loop bars 5671 with respect to the film width direction Z moment of the loop bars 5671 in the film width direction Z, Deformation of the loop bar 5671 can be reduced. The deformation of the loop bar 5671 can be reduced by increasing the length of the section extending portion 5671a in the film longitudinal direction Y with respect to the film longitudinal direction (Y) moment force of the loop bar 5671.

The end surface enlarging portion 5671a may be a connection portion connecting the separated parts of the loop bar 5671, but it is not necessarily limited thereto. For the convenience of the assembly process, the loop spacing portion 566 may be divided into a plurality of segments and the segment portions of the loop bars 5671 may be assembled and assembled together during assembly. In this case, The projection of one part can be inserted into the groove of the other part and assembled. In this case, in the state where the loop gap retaining portion 566 is fully assembled, the end face of the engagement portion of the projecting portion and the groove is relatively larger than the other end face portion of the loop bar 5671 so that the end face expanding portion 5671a .

The loop body 567 includes an opposite housing portion 5672 disposed at both ends of the film array direction X and coupled with the dust collecting case 502. The positive displacement portion 5672 functions to restrain both ends of the arrangement group X in the arrangement direction X and at the same time to fix the loop spacing portion 566 to the dust collection case 502.

The opposite end portion 5672 is coupled to the dust collecting case 502 to support the loop bar 5671.

Each of the pair of rest parts 5672 is disposed at each end of the loop bar 5671 on both sides of the film arrangement direction X. [ The both end portions 5672 are joined at both ends of the film arrangement direction X of the loop bar 5671 and extend in the film width direction Z to be contacted at both ends in the arrangement direction X of the array of films 540a have.

The opposite end portion 5672 may include a first support portion (not shown) coupled to one end of the loop bar 5671 and a second support portion (not shown) coupled to the other end of the loop bar 5671. The first support portion and the second support portion may be rod members extending in the film width direction Z, respectively.

The cross section of the first support portion and the second support portion cut in the horizontal direction may be a shape in which the film longitudinal direction Y is longer than the film arrangement direction X, and may be substantially rectangular. The length of the cross section of the first support portion and the second support portion in the horizontal direction is longer than the thickness of the loop bar 5671 in the film longitudinal direction Y and the length of the loop vertical bar 568 Direction (Y) thickness.

The one end of the opposite end portion 5672 in the film width direction Z is engaged with the dust-collecting case 502. And a fastening portion 5673 is provided at the one end of the positive displacement portion 5672 in the film width direction Z. [

At least one of the coupling portion 5673 and the dust-collecting case 502 has a fastening structure and the other has a structure corresponding to the fastening structure. In the present embodiment, a loop hook 503b is formed on the inner side in the direction in which the outlet 507 of the dust collecting case 502 is formed.

The fastening portion 5673 is formed in the fastening plate 5673b with a fastening hole 5673a through which the base hook 503b is inserted. The fastening plate 5673b is disposed on the horizontal plane and closely contacts the inner surface of the dust-collecting case 502.

The start ends of the plurality of loop vertical bars 568 are formed by being coupled to the loop bars 5671, respectively. The ends of the plurality of loop vertical bars 568 are formed as free ends.

The plurality of loop vertical bars 568 may be formed to have the same length. The horizontal cross section of the plurality of loop vertical bars 568 may be a rectangular shape having a longer film length direction Y than the film arrangement direction X, respectively.

A plurality of loop vertical bars 568 are inserted into the gap S beyond the center of the width of the plurality of films 540a. That is, the length of the plurality of loop vertical bars 568 is greater than half the length of the width of the plurality of films 540a. Also, the length of the plurality of loop vertical bars 568 may be less than or equal to the width of the plurality of films 540a.

Each of the plurality of loop vertical bars 568 is disposed alternately with each film 540a. One film 540a is disposed between adjacent two loop vertical bars 568 formed in one loop gap retaining portion 566. [ However, the loop vertical bars 568 disposed at both ends of the film array direction X of the plurality of loop vertical bars 568 form a gap with the adjacent both of the opposite ends 5672, (540a) can be disposed.

The plurality of loop vertical bars 568 may be formed with protrusions 569 protruding in the plane direction of the film so that the clearance of the film is reduced.

In this embodiment, the projection 569 may be a hemispherically protruding shape, but it need not be limited thereto.

The protrusions 569 may protrude from only one of both side surfaces of the plurality of loop vertical bars 568 in the film arrangement direction X and may be formed on both sides of the film arrangement direction X of the plurality of loop vertical bars 568 As shown in FIG. In the latter case, the film 540a is disposed between the projections 569 projecting in one direction from one of the loop vertical bars 568 and the projections 569 projecting in the other direction from the adjacent loop vertical bars 568 .

A projection 569 formed to be disposed at the center of the length of the film 540a in the width direction Z may be provided. The projections 569 may be arranged on the plurality of loop vertical bars 568 so as to be spaced along the width direction Z of the film.

Fig. 22 shows a part of the plurality of projections 569. Fig. In this embodiment, the protrusions 569a, 569b, and 569c protruding from either side of the film arrangement direction X of the plurality of loop vertical bars 568 and the protrusions 569d, 569e, . The protrusions 569a and 569f formed at the start end of the plurality of loop vertical bars 568 and the protrusions 569b and 565e formed at the center and the protrusions 569c and 569d formed at the end of the loop vertical bars 568 are disposed in the width direction Z of the film, Are spaced apart from each other.

The base hooks 503a and the loop hooks 503b are arranged so that a plurality of the hooks 503a and the loop hooks 503b are alternately spaced from each other in the longitudinal direction Y of the film in the film arrangement direction X of the outlet 507. [

23 is a partial perspective view enlarging the structure in which the plurality of films 540a of Fig. 12 are mounted on the mounting ribs 572. Fig. 24 is a sectional view of the dust collecting part 540 of Fig. 12 cut in the film length direction Y. Fig.

The fixing portion 540b includes a mounting rib 572 coupled to the dust-collecting case 502 and inserted into the latching groove 556. [

The fixing ribs 572 are formed extending in the arrangement direction X of the film. That is, the fixing ribs 572 extend in a direction perpendicular to the film 540a.

The fixing ribs 572 may include two ribs formed at both ends of the longitudinal direction Y of the film so as to extend in the arrangement direction X of the film. The fixing rib 572 includes a first fixing rib 572a disposed at one end of the longitudinal direction Y of the film and a second fixing rib 572b disposed at the other end of the longitudinal direction Y of the film, ).

The fixing portion 540b includes a conductor receiving portion 571 forming a receiving space 576 for containing the predetermined paste. The ends of the plurality of hooking hooks 555 arranged in line with the film arrangement direction X are inserted into the accommodating space 576 along both ends of the longitudinal direction Y of the arrangement group.

The conductor receiving portion 571 is formed to extend in the arrangement direction X of the film. The conductor accommodating portion 571 forms two accommodating spaces 576 formed at both ends of the longitudinal direction Y of the film in such a manner as to extend in the arrangement direction X of the film. The conductor receiving portion 571 includes a first conductor receiving portion 571a forming a receiving space 576 for containing the first electrode connecting portion 578a and a receiving space 576a for containing the second electrode connecting portion 578a And a second conductor receiving portion 571b that forms the first conductor receiving portion 571b.

The hooking hook 55 is formed by bending in the film width direction Z and is inserted into the receiving space 576 and fixed by the molding part 578. [ The fixing ribs 572 may be inserted into the latching grooves 556 to support the plurality of films 540a to achieve a stable overall structure. The gap holding portion 560 does not support the weight of the plurality of films 540a through the molding portion 578 or the mounting ribs 572 and the engagement grooves 556, , The structure of the gap holding portion 60 can be reduced or minimized.

An opening may be formed in the conductor receiving portion 571 to allow the predetermined paste to be injected into the accommodating space 576 and an opening may be formed to allow the exposed portions 557 and 558 to be inserted into the accommodating space 576. [ These two types of openings may be formed separately from each other, or one opening may serve two functions at the same time. This embodiment is the latter case.

The opening formed in the conductor accommodating portion 571 may be formed at one side of the film width direction Z of the conductor accommodating portion 571 and is formed by looking at the direction in which the opposed portion 510 is positioned in this embodiment. One side of the conductor receiving portion 571 is opened and recessed to form the receiving space 576.

The conductor accommodating portion 571 includes a bottom surface 573 constituting a lower side surface of the accommodating space 576 and two side surfaces (not shown) constituting both sides of the accommodating space 576 in the film arranging direction X, And two longitudinal side surfaces 572 and 574 constituting both side surfaces of the accommodating space 576 in the longitudinal direction Y of the film.

The accommodation rib 572 may form one surface defining the accommodation space 576. That is, the mounting ribs 572 can constitute a part of the conductor receiving portion 571. In this embodiment, the longitudinal side surface 572 in which the engaging groove 556 of the two longitudinal side surfaces is fitted is the fixing rib 572. The first fixing rib 572a constitutes a part of the first conductor receiving portion 571a and the second fixing rib 572b constitutes a part of the second conductor receiving portion 571b.

The opposite side surface 574 of the stationary rib 572 of the two longitudinal sides is inclined in the film width direction Z so that the size of the accommodating space 576 becomes larger toward the other side in the film width direction Z .

The molding unit 578 is fixed in the two accommodating spaces 576 in a predetermined paste form, and fixes the plurality of hooking hooks 55 while being hardened. The hooking hook 555 protruding with an area or width smaller than the entire area or width of the film 540a is structured to be easy to be immersed in the molding portion 578 and the molding portion 578 can efficiently move the film 540a There is an effect that can be fixed.

Hereinafter, in the present embodiment, the molding part 578 is limited to the electrode connection part 578, but it is needless to say that the molding part may be made of a material having no electrical conductivity.

The electrode connection portion 578 may be formed by stacking the exposed portions 557 and 558 formed on a plurality of films of any one of the plurality of first films 541 and the plurality of second films 542 It is preferable to be provided for connection. The first electrode connection portion 578a is provided to connect the exposed portions 557 formed in the plurality of first films 541 to each other and the second electrode connection portion 578b is provided to connect the plurality of second films 542 And the exposed portions 558 formed in the respective exposed portions 558, respectively. That is, the first electrode connection part 578a electrically connects all of the plurality of high potential connection parts 557, and the second electrode connection part 578b electrically connects all of the plurality of low potential connection parts 558 do.

The electrode connection part 578 fixes the hook 555.

The first electrode connection portion 578a is integrally formed by fixing the plurality of first films 541 and the hooks 555 formed at one end in the longitudinal direction Y of the plurality of second films 542. The second electrode connection portion 578b is integrally formed by fixing the plurality of first films 541 and the engagement hooks 555 formed at the other end in the longitudinal direction Y of the plurality of second films 542.

The first electrode connection part 578a is provided with a hooking hook 555a provided with a high potential connection part 557 of the plurality of first films 541 and a low potential connection part 558 of the plurality of second films 542 Thereby fixing the hooking hook 555b. The second electrode connection part 578b is formed by the engagement hook 555b of the plurality of first films 541 without the high potential connection part 557 and the low potential connection part 558 of the plurality of second films 542 Thereby fixing the hooking hook 555a. The first electrode connection portion 578a applies a relatively high electric potential to only the conductive layer 551a of the first film and the second electrode connection portion 578b applies a relatively low electric potential only to the conductive layer 551b of the second film .

The electrode connection portion 578 is formed by curing the conductor paste. The contact resistance can be minimized by firmly fixing the hooking hook 555 and the electrode connecting portion 578 in close contact with the high potential connecting portion 557 and the low potential connecting portion 558, 557 and the low-potential connecting portion 558, thereby preventing the occurrence of sparks at the contact point.

The conductor paste may be prepared by mixing a conductor powder, an organic solvent, and a macromolecule resin. The conductor paste is in a semi-solid state having fluidity before curing and in a solid state after curing.

The conductive powder means that a solid having conductivity is finely crushed to reduce the particle size. The conductive solid is preferably a metal component such as carbon, copper, or silver. In this embodiment, the conductor powder is carbon black powder.

The organic solvent is in a liquid state at room temperature. The organic paste mixed in the conductor paste is evaporated according to the drying condition, and the conductive paste is solidified into a solid.

The polymer resin is in powder form. The conductor powder and the polymer resin remain as components remaining after the conductor paste is cured. The conductor powder and the polymer resin are mixed and not chemically bonded. After the conductor paste is cured, the particles of the conductor powder are connected to each other, and the cured conductor paste can be electrically conductive.

The composition ratio of the conductor paste may be about 30% of the conductor powder, about 50% of the organic solvent, and about 20% of the polymer resin, but the present invention is not limited thereto.

The electrode connection portion 578 is arranged to be surrounded by water. In one embodiment, the waterproofing material 579 may be applied to the surface of the electrode connection portion 578 exposed to the outside air. The waterproof material 579 may include a material such as an epoxy resin or a urethane resin, but it is not necessarily limited thereto and may be any material which can be applied and cured.

In this embodiment, the waterproofing material is composed of a mixture of a base and a hardener, and the base material includes a bisphenol A type EPOXY resin, a flame retardant filler and other additives, and the hardener is an aliphatic modified amine hardener.

The waterproof material 579 is applied to a surface of the electrode connection part 578 exposed by the opening of the electrical conductor receiving part 571. The waterproofing material 579 is disposed so as to cover the surface on which the conductive paste is exposed to the outside air in a state where the conductive paste is contained in the accommodation space 576. The electrode connection portion 578 is surrounded by the conductor receiving portion 571 and the waterproof material 579.

In another embodiment, the surface of the electrode connection 578 that is exposed to the outside air may be arranged as a cap member (not shown). The cap member may be disposed to cover the upper surface of the accommodation space 576. The electrode connection portion 578 is surrounded by the conductor receiving portion 571 and the cap member.

Referring to FIG. 13, a method of manufacturing the electric dust collector using the conductive paste will be described. The predetermined paste may be classified into the conductive paste having electrical conductivity and the predetermined paste having no electrical conductivity. In the latter case, it may be understood as 'the predetermined paste' instead of 'the conductive paste' in the following description .

(A) placing the film (540a) at a predetermined position, (b) injecting the conductor paste so that the exposed portions (557, 558) are locked, (D) applying a waterproofing material to a surface of the conductive paste which is cured and exposed to the outside air, and curing the applied waterproofing material according to a predetermined drying condition (e ).

In the step (a), first, the surface on which the outlet 507 of the dust-collecting case 502 is formed is placed so as to be in contact with the floor so that the inner space of the dust-collecting case 502 is looked up, .

Thereafter, the base spacing portion 561 is disposed in the dust collecting case 502 at a predetermined position such that the base vertical bar 564 protrudes upward. The base spacing portion 561 is fixed to the dust collecting case 502 while the coupling portion 563 of the base spacing portion 561 is engaged with the base hook 503a at the corresponding position.

The mounting ribs 572 are then inserted into the engagement grooves 556 of the plurality of films 540a and the plurality of films 540a are inserted into the plurality of base vertical bars 564 , The film inserting step in which the plurality of films 540a are disposed at the predetermined positions is performed. When the plurality of films 540a are disposed at the predetermined positions, the ends of the plurality of hooking hooks 555 are all inserted into the accommodating space 576.

The loop gap retaining portion 566 is inserted into the inner space of the dust case 502 so that a plurality of films 540a are inserted between the loop vertical bars 568 of the loop gap retaining portion 566, And proceeds to a step of arranging a loop gap maintaining unit to be arranged at a predetermined position. The fastening portion 5673 of the loop gap maintaining portion 566 is engaged with the loop hook 503b at the corresponding position and the loop gap maintaining portion 566 is fixed to the dust collecting case 502. [

In the case where the loop gap retaining portions 566 are separated by the connecting portion (section enlarged portion) of the loop bar 5671 in the loop spacing retaining portion disposing step, After each of the segment portions of the loop spacing portion 566 are temporarily arranged such that a plurality of films 540a are inserted between the loop vertical bars 568 of the segment portions, The entire loop gap retaining part 566 is disposed at the predetermined position while assembling the parts. Careful attention should be paid to the process of inserting a plurality of films 540a between the loop vertical bars 568 of the entire loop gap retaining portion 566, thereby making this process easier and more convenient.

The step of arranging the loop spacers may be performed during or after step (b) or step (c), but proceeding before step (b) It is preferable in that it can be disposed accurately.

Thereafter, the step (b) is performed. In the step (b), the conductor paste is injected into the accommodation space 576 so that the ends of the plurality of hooking hooks 555 are all immersed in the conductor paste. That is, the conductor paste is injected so that the exposed portions 557 and 558 are all immersed in the conductor paste.

Thereafter, the step (c) proceeds. In the step (c), the injected conductive paste is cured according to a paste drying temperature and a paste drying time, which are predetermined drying conditions. The paste drying temperature and the paste drying time may vary depending on the specific composition and mixing ratio of the conductive paste and the paste drying temperature is not more than 75 degrees Celsius and the paste drying time is not more than 180 minutes, It is preferable for preventing deformation.

Thereafter, the step (d) proceeds. And the waterproofing material is applied to the open surface of the accommodation space 576, which is the surface exposed to the outside air, among the conductive paste that is cured.

Then, the step (e) is performed. In the step (e), the coated waterproofing material is cured according to the drying condition of the waterproofing material and the drying time of the waterproofing material. The drying temperature of the waterproofing material and the drying time of the waterproofing material may vary depending on the specific composition and mixing ratio of the waterproofing material. In this embodiment, the drying temperature of the waterproofing material is 60 ° C or less and the paste drying time is 180 minutes or less.

Hereinafter, an electric dust collector 2500 according to another embodiment will be described with reference to FIGS. 25 to 34. FIG. The same components as those of the electric dust collector 500 according to the embodiment are denoted by the same reference numerals, and a duplicate description will be omitted

The electric dust collector 2500 according to another embodiment includes a charging unit 510 for charging dust particles in the air, a dust collecting unit 540 for collecting the charged dust particles in the charging unit, and a dust collecting unit 540 And a dust-collecting case 2502 which houses the dust-collecting case 2502 therein.

The dust collecting unit 540 includes a plurality of films 540a coated with conductive layers 551a and 551b with insulating layers 552a and 552b and a plurality of films 540a fixed to the inside of the dust collecting case 2502 And a fixing unit 540b. The hooks 2555a and 2555b of the film 540a according to another embodiment may be formed to protrude with a width smaller than the width of the film 540a in the longitudinal direction Y of the film 540a.

The plurality of films 540a are in the form of strips whose longitudinal direction Y is longer than the width direction Z and which are arranged in a line to form a group of arrangements.

The fixing portion 540b includes a gap holding portion 2560 according to another embodiment that is disposed on both sides in the width direction Z of the array group to hold the gap.

The gap maintaining portion 2560 includes a base spacing portion 2561 disposed on one side in the width direction Z of the film 540a and a base spacing portion 2561 disposed on the other side in the width direction Z of the film 540a And a loop gap maintaining unit 2566.

The spacing retaining portion 2560 includes a plurality of vertical bars 2568 inserted into the apertures S from either side of the array. The base spacing portion 2561 includes a plurality of first vertical bars 2568-1 inserted into the apertures S from one side of the array group. The loop gap retaining portion 2566 includes a plurality of first vertical bars 2568-2 inserted into the gaps S from the other side of the array group.

The vertical bar 2568 can be inserted up to the middle of the width direction Z of the film 540a. The plurality of first vertical bars 2568-1 can be inserted up to the center of the width direction Z of the film 540a and the plurality of first vertical bars 2568-2 can be inserted in the width direction of the film 540a (Z).

The base spacing portion 2561 and the loop spacing portion 2566 may be disposed symmetrically with respect to the widthwise center portion of the film 540a. 28, the first film 2541 and the second film 2542 according to another embodiment have a base gap holding portion 2561 and a loop gap holding portion 2561 at both ends in the width direction Z on the same cross- ). ≪ / RTI >

The base spacing portion 2561 and the loop spacing portion 2566 may have the same shape. FIGS. 31 to 34 illustrate the case where the base spacing portion 2561 and the loop spacing portion 2566 have the same shape. FIGS. 31 to 34 illustrate the base spacing portion 2561 and the loop spacing portion 2566, But the present invention is not limited thereto.

The vertical bar 2568 may be formed with a protrusion 2569 protruding in the plane direction of the film 540a so that the clearance of the film 540a may be reduced. The first vertical bar 2568-1 and the first vertical bar 2568-2 are formed with protrusions 2569 protruding in the surface direction of the film 540a so that the clearance of the film 540a is reduced . A first projection 2569-1 is formed on the first vertical bar 2568-1 and a second projection 2569-2 is formed on the first vertical bar 2568-2.

In one vertical bar 2568, a plurality of protrusions 2569a and 2569b protruding in one direction may be spaced apart from each other, and a plurality of protrusions 2569c and 2569d protruding in the other direction may be spaced apart from each other . In one vertical bar 2568, the two protrusions 2569a and 2569d (2569b and 2569c) protruding in mutually opposite directions can be arranged to be offset from each other.

The gap holding portions 2560 may be spaced apart from each other along the longitudinal direction Y of the film 540a.

The interval maintaining unit 2560 includes a gap maintaining body 2567 which surrounds both ends of the arrangement direction X of the arrangement group and the one side and supports the starting end of the vertical bar 2568.

The base gap retaining portion 2561 includes a first gap maintaining body 2567 which surrounds both ends of the arrangement direction X of the arrangement group and one side thereof and supports a starting end of the first vertical bar 2568-1 can do. The loop interval maintaining portion 2566 includes a second gap maintaining body 2567 which surrounds both ends of the arrangement direction X of the array group and the other end and supports the first stage of the first vertical bar 2568-2 can do.

The gap maintaining body 2567 is provided with a pair of opposing walls 2567b disposed at both ends of the arranging direction X to be engaged with the dust collecting case and extending in the arranging direction X of the arranging group A horizontal bar 2567a and a fastening part 2567c for fixing the gap holding part 2560 to the dust collecting case 2502. [

28, the first gap maintaining body 2567 includes: a first quantity restricting portion 2567b-1 disposed at both ends of the arrangement direction X to be engaged with the dust collecting case; A first horizontal bar 2567a-1 extending in the arrangement direction X of the arrangement group and a first connection portion 2567c-1 for fixing the base spacing portion 2561 to the dust collection case 2502 ).

28, the second gap maintaining body 2567 includes a second quantity restricting portion 2567b-2 disposed at both ends of the arrangement direction X and engaged with the dust collecting case, A second horizontal bar 2567a-2 extending in the arrangement direction X of the array group and a second coupling part 2567c-2 for fixing the loop space retaining part 2566 to the dust collecting case 2502, 2).

The dust collecting case 2502 includes a hook 2503 which is engaged in a state where the first fastening part 2567c-1 and the second fastening part 2567c-2 are in contact with each other. The first fastening part 2567c-1 and the second fastening part 2567c-2 are engaged with one hook 2503 in a state of being in contact with each other.

The fastening part 2567c includes a fastening plate 2567c1 that forms a plate in contact with the other fastening part 2567c and a hook groove 2567c2 in which the hook 2503 is inserted into the fastening plate 2567c1, .

The first fastening part 2567c-1 includes a first fastening plate 2567c1-1 that forms a plate in contact with the second fastening part 2567c-2, and the first fastening plate 2567c- A hook groove 2567c2-1 is formed in which the hook 2503 is inserted and hooked.

The second fastening portion 2567c-2 includes a second fastening plate 2567c1-2 that forms a plate in contact with the first fastening portion 2567c-1, and the second fastening plate 2567c- A hook groove 2567c2-2 is formed in which the hook 2503 is inserted and hooked.

The dust collecting case 2502 includes a hook fixing table 2504 for supporting and fixing the hook 2503. One end of the hook fixing base 2504 is fixed to the dust collecting case 2502 and the other side end of the hook fixing base 2504 protrudes up to the center of the width direction Z of the film 540a and is connected to the hook 2503.

The dust collecting case 2502 includes a fixing plate 2503 that supports the coupling portion 2567c between the hook 2503 and the hook fixing table 2504 and forms a step to be contacted. In this embodiment, referring to Fig. 28, the fixing plate 2503 forms a step that makes contact with the first engagement portion 2567c-1.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

10: filter assembly 100: clean module
130: Body 135: Dust sensor
200: Humidification module
300: mesh filter 400: drawer
500: electric dust collector 600: photocatalyst filter
501: charging case 502, 2502: dust collecting case
510: charging part 521: wire discharge electrode
523: counter electrode plate 524: electrode plate connection portion
525: spark preventing portion 540: dust collecting portion
540a: Film 540b:
541: first film 542: second film
551a, 551b: conductive layers 552a, 552b: insulating layer
555: Retaining hook 556: Retaining groove
557: exposed portion, high potential connection portion 558: exposed portion, low potential connection portion
560, 2560: spacing retaining portions 561, 2561: base spacing retaining portions
562: base bar 563: fastening part of base spacer
564: base vertical bar 565: projection of the base vertical bar
566, 2566: Loop interval maintaining unit 567: Loop body
5671: Loop bar 5671a:
5672: both ends of the loop gap maintaining part 5673: the fastening part of the loop gap maintaining part
568: Loop vertical bar 569: Loop of the vertical bar
2567: space maintaining body 2567a: horizontal bar
2567b: amount of clearance retaining body 2567c: fastening part of clearance retaining body
2568: vertical bar 2569: vertical bar projection
571: Conductor receiving portion 578: Electrode connection portion
579: Waterproof material 581: Voltage source
582: ground 584: first conductor
583: Second conductor
X: Direction of film arrangement Y: Film length direction
Z: film width direction S: gap between plural films

Claims (10)

A charging unit charging the dust particles in the air;
A dust collecting part for collecting the charged dust particles in the charging part; And
And a dust collecting case for accommodating the collection unit therein,
Wherein the dust collecting portion includes a plurality of films formed by applying a conductive layer to an insulating layer and a fixing portion for fixing the plurality of films inside the dust collecting case,
Wherein the plurality of films are in the form of strips having a longitudinal direction longer than the width direction and are arranged in a line to form a group of arrangements,
Wherein the fixing portion includes a gap holding portion that is disposed on both sides in the width direction of the array group and holds the gap,
Wherein the gap holding portion includes a base gap holding portion disposed on one side of the width of the film and a loop gap holding portion disposed on the other side in the width direction of the film,
Wherein the base spacing portion includes a plurality of first vertical bars inserted into the gaps from the one side of the array group,
Wherein the loop space retaining portion includes a plurality of second vertical bars inserted into the gaps from the other side of the array group. The method according to claim 1,
Wherein the base gap retaining portion and the loop gap retaining portion are disposed symmetrically with respect to each other with respect to the widthwise central portion of the film. The method according to claim 1,
Wherein the base gap retaining portion and the loop gap retaining portion have the same shape. The method according to claim 1,
Wherein protrusions protruding in the direction of the surface of the film are formed on the first vertical bar and the second vertical bar such that the clearance of the film is reduced. The method according to claim 1,
Wherein the gap holding portions are spaced apart from each other along the longitudinal direction of the film. The method according to claim 1,
Wherein the base spacing portion includes a first spacing body which surrounds both ends of the arranging direction of the array group and one side thereof and supports a starting end of the first vertical bar,
Wherein the loop space retaining portion includes a second space maintaining body which surrounds both ends of the array group in the arranging direction and the other end and supports a starting end of the second vertical bar. The method according to claim 6,
Wherein the first gap maintaining body includes a first amount retaining portion disposed at both ends of the arrangement direction and engaged with the dust collecting case,
And the second gap maintaining body includes a second quantity limiting portion disposed at both ends in the arrangement direction and coupled with the dust collecting case. The method according to claim 6,
Wherein the first gap maintaining body includes a first horizontal bar extending in the array direction of the array group while being in contact with the array group,
Wherein the second interval maintaining body includes a second horizontal bar extending in the array direction of the array group while being in contact with the array group. The method according to claim 6,
Wherein the first gap maintaining body includes a first coupling portion for fixing the base gap maintaining portion to the dust collecting case,
Wherein the second gap maintaining body includes a second coupling portion for fixing the loop gap maintaining portion to the dust collection case,
Wherein the dust collecting case includes a hook which is hooked in a state where the first fastening part and the second fastening part are in contact with each other. An air conditioner comprising an electric dust collector according to any one of claims 1 to 9.

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