KR102826187B1 - Air Conditioner - Google Patents

Abstract

The present invention relates to an air conditioner.
The air conditioner of the present invention comprises a supply path, a case having a first inlet formed on one side of the supply path, and a first outlet formed on the other side of the supply path, a first fan disposed on the supply path and forming air flow from the first inlet to the first outlet, and an electric precipitator disposed on the supply path and removing foreign substances in air flowing in the supply path. The above-described electric precipitator includes a charging unit that charges foreign substances in flowing air, a dust collecting unit that captures foreign substances in the flowing air through the charging unit, and a high-voltage generating unit that generates a high voltage and applies the voltage to the charging unit or the dust collecting unit, wherein the charging unit includes an electrode unit that is connected to the high-voltage generating unit and includes a plurality of electrodes that generate ions in the air through the high voltage, and a grounding unit that is arranged on one side of the electrode unit and includes a grounding plate arranged around each of the plurality of electrodes, wherein the grounding plate forms a charging path through which air flows around each of the plurality of electrodes.

Description

Air Conditioner

The present invention relates to an air conditioner, and more particularly, to an air conditioner including an electric precipitator.

An air conditioner can supply heat-exchanged air to an indoor space. However, since an air conditioner continuously supplies air to an indoor space, the air supplied must be kept free of foreign substances so that the users of the indoor space can feel comfortable.

Therefore, air conditioners can be equipped with filters or electrostatic precipitators to remove particulate matter from the air supplied to indoor spaces.

An electrostatic precipitator can remove foreign substances by charging foreign substances in the air in a charging section and capturing the charged foreign substances in a dust collecting section.

Publication number KR 10-2016-0001203 discloses an electric precipitator for removing foreign substances in the air.

However, in the case of air conditioners with a dedicated outdoor air system structure that draws in outside air and supplies it to indoor spaces, there is a problem in that it is difficult to effectively remove foreign substances using an electric precipitator because a large amount of outside air is drawn in.

In a structure where outside air is introduced, there is a problem that the charging performance of foreign substances may be reduced in areas where the air flow rate is large because a large amount of foreign substances are included and the area where the charge is applied is limited.

In addition, the entire structure must be separated in order to manage the dust collection section and the grounding plate of the charging section where foreign substances are mainly collected, which causes inconvenience in management.

The problem to be solved by the present invention is to provide an air conditioner that improves the electrostatic precipitator's electrostatic performance.

Another object of the present invention is to provide an air conditioner that improves the dust collection performance of an electric precipitator.

Another object of the present invention is to provide an air conditioner that improves the convenience of management of an electric precipitator.

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

In order to achieve the above object, an air conditioner according to an embodiment of the present invention includes a supply path, a case having a first inlet formed on one side of the supply path, and a first outlet formed on the other side of the supply path, a first fan disposed on the supply path and forming air flow from the first inlet to the first outlet, and an electric precipitator disposed on the supply path and removing foreign substances in air flowing in the supply path. The above-described electric dust collector includes a charging unit that charges foreign substances in flowing air, a dust collecting unit that captures foreign substances in the flowing air through the charging unit, and a high-voltage generating unit that generates a high voltage and applies the voltage to the charging unit or the dust collecting unit, wherein the charging unit includes an electrode unit that is connected to the high-voltage generating unit and includes a plurality of electrodes that generate ions in the air through the high voltage, and a grounding unit that is arranged on one side of the electrode unit and includes a grounding plate that is arranged around each of the plurality of electrodes, and the grounding plate forms a charging path through which air flows around each of the plurality of electrodes. Since the grounding plate forms a charging path around the electrodes, charging of foreign substances in the air flowing around the electrodes can occur actively.

The above grounding plate forms a peripheral wall spaced apart from the electrode in a direction perpendicular to the direction of air flow, so that a charging path can be individually formed for each electrode.

The above grounding plate includes a plurality of first grounding plates extending in a first direction perpendicular to the direction in which the air is introduced and arranged to be spaced apart in a second direction perpendicular to the first direction, and a plurality of second grounding plates extending in the second direction and arranged to be spaced apart in the first direction, and each of the plurality of first grounding plates and the plurality of second grounding plates forms a plurality of charge paths around which the plurality of electrodes are arranged, so that a charge path in a rectangular frame shape can be formed.

The above grounding plate can secure the length of the charging path by forming a length spaced apart from the electrode at a certain interval forward and backward in the direction in which the air flows.

The above electrodes are arranged at a certain interval in the direction of air flow from the inlet end of the charging channel, and are arranged at a certain interval in the direction of air flow from the outlet end of the charging channel, so as to secure a range in which charging occurs in the charging channel.

The electrode part further includes an electrode part cover forming an outer appearance, and the electrode part cover includes a peripheral wall forming a space through which air flows inward, and a plurality of first ribs extending in a first direction from the inner side of the peripheral wall and arranged to be spaced apart in a second direction perpendicular to the first direction, and the plurality of electrodes can be arranged to be spaced apart in the first direction on each of the plurality of first ribs.

The first rib includes an inwardly convex bending portion in which the charging path is formed, and the electrode is arranged in the bending portion so that the electrode can be arranged on the charging path formed by the grounding plate.

The above electrode may be positioned so as to protrude in the direction in which air flows into the banding portion.

The electrode portion includes a plurality of second ribs extending in a second direction perpendicular to the first rib and arranged to be spaced apart in the first direction, and the ground portion is mounted on one side of the second rib, so that the ground portion can be mounted on one side of the electrode portion.

Conductive microfibers are exposed and arranged at the ends of the electrodes, and the distance between the ends of the conductive microfibers and the inlet end of the charging channel is formed to be smaller than or equal to the distance between the ends of the conductive microfibers and the outlet end of the charging channel, so that the conductive microfibers can be arranged on the charging channel.

Conductive microfibers are exposed and arranged at the end of the electrode, and the distance between the end of the conductive microfibers and the inlet end of the charging channel is formed at a distance of 1/4 to 1/8 of the distance between the ground plate to which the conductive microfibers are arranged adjacent, so that the charging performance of the electrode arranged on the charging channel can be improved.

The above-mentioned electric dust collector includes a frame on which the charging unit and the dust collecting unit are mounted, the charging unit is detachably arranged in one direction with respect to the frame, and the dust collecting unit is detachably arranged in a direction different from the direction in which the charging unit is detached with respect to the frame, so that the dust collecting unit and the charging unit can be managed separately.

The above grounding part is detachably arranged from the electrode part, so that the grounding part can be managed separately from the electrode part.

The above grounding portion can be separated from the electrode portion in a direction away from the dust collecting portion.

In a state where the above-mentioned charging unit and the above-mentioned dust collection unit are each mounted on a frame, the charging unit can be placed at a certain distance from the dust collection unit.

The above grounding portion further includes a grounding housing that forms a space in which the grounding plate is placed, and the grounding housing can be arranged to be fixed to the electrode portion.

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

According to the air conditioner of the present invention, one or more of the following effects are achieved.

First, a grounding plate is arranged around the electrode to form a charging path, so that charging of foreign substances in the air can be actively carried out due to the potential difference between the electrode and the grounding plate. Therefore, there is an advantage of improved charging performance.

Second, since grounding plates are placed on all sides of the electrode, charged foreign substances can also be captured by the grounding plates, which also has the advantage of improving dust collection performance.

Third, the charging unit and the dust collector are separated individually based on the frame, and the configuration of the charging unit can be separated from the electrode unit and the grounding unit separately, so there is an advantage in that individual management of the configuration is easy. In other words, there is also an advantage in that the dust collector and the grounding unit, where foreign substances are mainly collected, can be easily separated and managed separately.

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

FIG. 1 is a drawing for explaining a structure in which an air conditioner according to one embodiment of the present invention is connected to an outdoor unit.
FIG. 2 is a cross-sectional view illustrating the internal structure of an air conditioner according to one embodiment of the present invention.
Figure 3 is a perspective view of an electric dust collector according to one embodiment of the present invention.
Figure 4 is a front view of Figure 3.
Figure 5 is an exploded perspective view of Figure 3.
Figure 6 is a cross-sectional view taken along line VI-VI' of Figure 4.
Figure 7 is a perspective view of a grounding portion according to one embodiment of the present invention.
Figure 8 is an exploded perspective view of Figure 7.
Figure 9 is a perspective view of an electrode portion according to one embodiment of the present invention.
Figure 10 is a front view of Figure 9.
Fig. 11 is a cross-sectional view taken along ⅩⅠ-ⅩⅠ' of Fig. 10.

The advantages and features of the present invention, and the methods for achieving them, will become clearer with reference to the embodiments described in detail below together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and the present embodiments are provided only to make the disclosure of the present invention complete and to fully inform those skilled in the art of the scope of the invention, and the present invention is defined only by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, an air conditioner according to an embodiment of the present invention will be described with reference to the drawings.

First, referring to FIG. 1 and FIG. 2, the configuration of the air conditioner and the electric dust collector mounted on the air conditioner are described.

The air conditioner (10) of the present invention may be a ventilation device that exchanges heat with outdoor air and supplies it to indoors. The air conditioner (10) may have a structure in which an outdoor unit (1) including a compressor (not shown) and an outdoor heat exchanger (not shown) that exchanges heat between refrigerant and outdoor air is connected to a plurality of refrigerant pipes (2, 3).

The air conditioner (10) can also be an indoor unit that is placed in an indoor space and supplies heat-exchanged air while circulating indoor air.

The air conditioner (10) may be a ventilation device that discharges indoor air to an outdoor space and supplies outdoor air to an indoor space. The air conditioner (10) may heat or cool outdoor air supplied to an indoor space by arranging a plurality of heat exchangers inside. The air conditioner (10) may exchange heat between outdoor air and indoor air. The air conditioner (10) may heat-exchange indoor air discharged to an outdoor space and discharge it.

A plurality of heat exchangers (40, 42, 44) may be arranged inside the air conditioner (10). At least one of the plurality of heat exchangers (40, 42, 44) may cool or heat air using the flow of refrigerant supplied from the outdoor unit (1).

Each of the multiple heat exchangers arranged inside the air conditioner (10) can heat the flowing air and cool the flowing air at the same time.

The air conditioner (10) of the present invention is installed between an indoor space and an outdoor space, and can cause indoor air to flow to the outdoors and cause outdoor air to flow to the indoors. The air conditioner (10) of the present invention can be a ventilation device that causes outdoor air to flow into the indoors and sends indoor air to the outdoors.

The air conditioner (10) of the present invention comprises a case (12) forming a supply path (22) through which outside air flows and a discharge path (24) through which inside air flows, a partition wall (26) arranged inside the case (12) and dividing the supply path (22) and the discharge path (24), a heat exchanger (30) arranged inside the case (12) and exchanging heat between outside air flowing in the supply path (22) and inside air flowing in the discharge path (24), and a plurality of heat exchangers (40, 42, 44) arranged on the supply path (22) or the discharge path (24) and exchanging heat between the flowing air and a refrigerant.

The air conditioner (10) further includes a first blower fan (32) rotatably arranged on a supply path (22), a first blower motor (34) that rotates the first blower fan (32), a second blower fan (36) rotatably arranged on a discharge path (24), and a second blower motor (386) that rotates the second blower fan (36). The first blower fan (32) and the second blower fan (36) may use cross-flow fans in which a suction area and a discharge area are formed vertically. The first blower fan (32) and the second blower fan (36) may have a suction area formed in a direction parallel to a rotation axis, and a discharge area formed in a radial direction perpendicular to the rotation axis.

The plurality of heat exchangers include a first heat exchanger (40) arranged on the supply path (22) for heat exchange with the refrigerant and the flowing outside air, a second heat exchanger (42) arranged on the exhaust path (24) for heat exchange with the refrigerant and the flowing inside air, and a third heat exchanger (44) arranged on the supply path for heat exchange with the refrigerant and the outside air that has passed through the first heat exchanger (40).

The case (12) forms a supply path (22) and a discharge path (24) inside.

In the case (12), an outside air intake port (18) is formed on one side of the supply path (22) through which the inside of the case (12) and the outside are connected, and an outside air supply port (20) is formed on the other side of the supply path (22) through which the inside of the case (12) and the inside are connected. In the case (12), an inside exhaust port (16) is formed on one side of the exhaust path (24) through which the inside of the case (12) and the outside are connected, and an inside intake port (14) is formed on the other side of the exhaust path (24) through which the inside of the case (12) and the inside are connected.

The outside air intake port (18) and the outside air supply port (20) can be arranged in a vertical direction. The inside air intake port (14) and the inside air discharge port (16) can be arranged in a vertical direction.

On the supply path (22), a heat exchanger (30), a first heat exchanger (40), and a third heat exchanger (44) are sequentially arranged.

The air conditioner (10) of the present invention is placed on the supply path (22), and an electric dust collector (50) for removing foreign substances in the flowing air can be placed. The electric dust collector (50) is placed on one side of the first heat exchanger (40). The electric dust collector (50) is placed upstream of the first heat exchanger (40). The electric dust collector (50) can be placed between the first heat exchanger (40) and the total heat exchanger (30). The specific configuration of the electric dust collector (50) will be described in detail below.

The area of the supply path (22) can be expanded as it goes from the heat exchanger (30) to the first heat exchanger (40).

Among the supply paths (22), the path expands from the area where the heat exchanger (30) is placed to the area where the first heat exchanger (40) is placed, so that heat exchange of a large amount of air can occur in the first heat exchanger (40). In addition, since the electric dust collector (50) is placed on one side of the first heat exchanger (40), a large amount of air can flow.

Condensate may be temporarily stored at the bottom of the first heat exchanger (40), and a drain pan (28) may be placed to discharge the condensate to the outside.

A heat exchanger (30) and a second heat exchanger (42) are sequentially arranged on the exhaust path (24). Therefore, air flowing through the exhaust path (24) can be discharged to the outside through the heat exchanger (30) and the second heat exchanger (42) sequentially.

The exhaust path (24) can be arranged below the supply path (22). A second blower fan (36) is arranged above the exhaust path (24) to cause the air flowing through the exhaust path (24) to flow into the exhaust outlet (16).

Inside the case (12), a partition (26) is arranged to separate the supply path (22) and the discharge path (24).

The heat exchanger (30) is a device that recovers sensible heat and latent heat by utilizing the temperature difference and humidity difference between the outside air and the return air while rotating at a low speed. The heat exchanger (30) is formed in a cylindrical body shape, and the inside is formed in a honeycomb structure so that air can pass through.

The heat exchanger (30) can recover sensible heat and latent heat by utilizing the temperature difference and humidity difference between the outside air and the return air while rotating at low speed. The heat exchanger (30) is composed of aluminum as a base material and can recover sensible heat by the heat transfer characteristics of aluminum. In addition, the aluminum is impregnated with a desiccant so that latent heat can be recovered by the water vapor adsorption principle.

The heat exchanger (30) is arranged across both the supply path (22) and the exhaust path (24).

Each of the plurality of heat exchangers (40, 42, 44) can exchange heat through the refrigerant flowing from the outdoor unit (1). In addition, it is also possible to use an electric heater operated by electricity for at least one of the plurality of heat exchangers (40, 42, 44).

Hereinafter, the electric dust collector (50) of the present invention will be described with reference to FIGS. 3 to 11.

The electric dust collector (50) may include a charging unit (52) and a dust collecting unit (80). Referring to FIG. 5, the electric dust collector (50) includes a frame (92) on which the charging unit (52) and the dust collecting unit (80) are mounted, and a high voltage generating unit (90) mounted on one side of the frame (92) and which applies a high voltage to the charging unit (52) or the dust collecting unit (80).

The frame (92) may have a rectangular frame shape. A charging unit (52) may be mounted on one side of the frame (92), and a dust collecting unit (80) may be mounted on the other side of the frame (92). Therefore,

The charging unit (52) charges foreign substances such as dust particles in the air. The dust collecting unit (80) can capture dust particles, etc. charged by the charging unit (52) and remove them from the air. Dust particles, etc. in the air passing through the electric dust collector (50) are charged by combining with ions generated by the charging unit (52), and the charged dust particles, etc. can be captured by the charging unit (52) or the dust collecting unit (80).

The electric dust collector (50) is equipped with a charging unit (52) and a dust collecting unit (80) as separate devices. Each of the charging unit (52) and the dust collecting unit (80) can be fixedly arranged on a frame (92).

The charging unit (52) and the dust collection unit (80) are each separately connected to the frame (92). Therefore, it is possible to separate only the dust collection unit (80) from the frame (92) or to separate only the charging unit (52).

The electrode part (52) may include an electrode part (54) to which a high voltage is applied and a ground part (70) to which a relatively low voltage is applied compared to the high voltage applied from the electrode part (54). The electrode part (54) generates ions in the air with the voltage applied from the high voltage generator (90) and forms an electric field. The end of the electrode part (54) may have a structure in which conductive microfibers (68) are exposed. The conductive microfibers (68) may be arranged to protrude in the opposite direction to the air flow direction from the end of the electrode part (54).

The grounding portion (70) can be applied with a ground electrode. The grounding portion (70) can be arranged spaced apart from the end of the electrode portion (54) to form a path through which air flows.

The charging unit (52) generates ions into the air and forms an electric field. At this time, the grounding unit (70) generates a potential difference with the electrode unit (54) to form an electric field. Particles charged in the grounding unit (70) can be captured.

Referring to FIGS. 9 and 10, the electrode part (54) includes an electrode part cover (56) forming an exterior, and a plurality of electrodes (66) arranged on the electrode part cover (56).

The electrode cover (56) includes a peripheral wall (58) forming a space through which air flows inward, a plurality of first ribs (60) extending in a first direction from the inner side of the peripheral wall (58) and arranged to be spaced apart in a second direction (d2-, d2+) perpendicular to the first direction (d1-, d1+), and a plurality of second ribs (64) extending in a second direction (d2-, d2+) from the inner side of the peripheral wall (58) and arranged to be spaced apart in the first direction (d1-, d1+).

On one side of the electrode cover (56), a high voltage generator mounting part (59) on which a high voltage generator (90) is mounted is placed.

A plurality of electrodes (66) are arranged on each of the plurality of first ribs (60). A plurality of electrodes (66) may be arranged spaced apart from each other in the first direction (d1-, d1+) on each of the plurality of first ribs (60).

Each of the first ribs (60) may include a banding portion (62) that extends in the first direction (d1-, d1+) and protrudes in the direction in which air is introduced. A plurality of banding portions (62) may be formed spaced apart from each other in the first direction (d1-, d1+). A plurality of electrodes (66) may be arranged on each of the plurality of banding portions (62).

The perimeter wall (58) may have a rectangular frame shape. A grounding portion (70) may be arranged on the inside of the perimeter wall (58). A grounding housing (72) of the grounding portion (70) to be described below is arranged on the inside of the perimeter wall (58).

The first rib (60) extends in the first direction (d1-, d1+) perpendicular to the direction of air flow. The first rib (60) may be formed at different intervals from the grounding portion (70) depending on the location. That is, the interval from the grounding portion (70) may be formed to be maximum in the area where the electrode (66) is placed. In addition, the interval from the grounding portion (70) may be formed to be minimum in the area where it intersects with the second rib (64).

The distance between the first rib (60) and the dust collector (80) in the area where the electrode (66) is placed can be formed to be greater than the distance between the first rib (60) and the dust collector (80) in the area where the second rib (64) is placed.

The electrode (66) can ionize foreign substances in the air by receiving a high voltage from a high voltage generator (90). The end of the electrode (66) can be positioned so that the conductive microfibers (68) are exposed. The conductive microfibers (68) are formed to protrude in the direction in which air flows in from the first rib (60). The conductive microfibers (68) can have a structure that protrudes in a direction away from the dust collecting unit (80).

The distance (d1) at which the end (68a) of the conductive microfiber (68) is spaced from the inlet end (78a) of the charging channel (78) is formed to be smaller than or equal to the distance (d2) at which the end (68a) of the conductive microfiber (68) is spaced from the outlet end (78b) of the charging channel (78).

The distance (d1) between the end (68a) of the conductive microfiber (68) and the inlet end (78a) of the charging path (78) is formed at a distance of 1/4 to 1/8 of the distance (d3) between the conductive microfiber (68) and the grounding plate (74, 76) adjacently arranged.

Conductive microfibers (68) can ionize molecules in the air by discharging with a high voltage. By the high voltage applied to the conductive microfibers (68), negative ions such as OH- and O- or positive ions such as H+ can be generated in the air.

The conductive microfibers (68) can be connected to a high voltage generating unit (90) by a wire. The conductive microfibers (68) include carbon fibers. Carbon fibers are formed as ultrafine fibers having a diameter in the micrometer range. When a high voltage is applied to the carbon fibers, ions can be generated in the air by corona discharge.

The conductive microfibers (68) may have a carbon brush shape in which hundreds or thousands of carbon fibers form a bundle.

A plurality of second ribs (64) are arranged to intersect with a plurality of first ribs (60). A grounding plate (74, 76) of a grounding portion (70) to be described below can be placed on each of the plurality of second ribs (64).

The grounding portion (70) is arranged so as to be detachable from the electrode portion (54). The grounding portion (70) can be pulled out from the electrode portion (54) in a direction away from the frame (92). Therefore, only the grounding portion (70) can be detached while the charging portion (52) is mounted on the frame (92).

Referring to FIGS. 7 and 8, the grounding portion (70) includes a grounding plate (74, 76) arranged around the electrode (66), and a grounding housing (72) forming a space in which the grounding plates (74, 76) are arranged. The grounding housing (72) includes a first grounding housing (72a) arranged on one side of the grounding plate (74, 76), and a second grounding housing (72b) arranged on the other side of the grounding plate (74, 76).

The first ground housing (72a) and the second ground housing (72b) form a space in which ground plates (74, 76) are arranged inside when combined. The first ground housing (72a) and the second ground housing (72b) can fix the arrangement of the ground plates (74, 76) when combined.

The grounding plates (74, 76) include a plurality of first grounding plates (74) extending in a first direction (d1-, d1+) and arranged to be spaced apart from each other in a second direction (d2-, d2+), and a plurality of second grounding plates (76) extending in a second direction (d2-, d2+) and arranged to be spaced apart from each other in the first direction (d1-, d1+).

A plurality of first grounding plates (74) and a plurality of second grounding plates (76) are arranged to intersect each other. A plurality of first grounding plates (74) and a plurality of second grounding plates (76) are arranged perpendicular to each other. A plurality of second grounding plates (76) can be arranged to contact the second rib (64) of the electrode portion (54).

The grounding plate (74, 76) can form a peripheral wall spaced apart from the electrode (66) in a direction perpendicular to the direction of air flow. Accordingly, a charge path (78) can be formed within the space formed by the peripheral wall.

The grounding plates (74, 76) are arranged at a predetermined distance from the electrode (66) in the direction in which the air flows. That is, the end of the electrode (66) is arranged at a predetermined distance from the inflow end (78a) formed by the charging channel (78). Specifically, the end of the conductive microfiber (68) of the electrode (66) can be arranged at a predetermined distance from the inflow end (78a) formed by the charging channel (78).

In addition, the end of the electrode (66) is placed at a certain distance from the outlet (78b) formed by the electric current path (78).

Each of the plurality of first grounding plates (74) and the plurality of second grounding plates (76) can form a plurality of charge channels (78). An electrode (66) is arranged in each of the plurality of charge channels (78). Conductive microfibers (68) can be arranged in the charge channels (78).

The ground plate (74, 76) can form an electric field with the conductive microfiber (68). A ground wire to which a ground electrode is applied can be connected to the ground plate (74, 76). A potential difference is generated between the ground plate (74, 76) and the conductive microfiber (68), and an electric field can be formed.

The grounding plate (74, 76) may be formed of a conductive material such as metal. The grounding plate (74, 76) may be formed of a metal plate having a predetermined thickness.

The first grounding plate (74) is arranged to be spaced apart from the first rib (60) in the second direction (d2-, d2+). The first grounding plate (74) is arranged between the first ribs (60) that are spaced apart from each other in the second direction (d2-, d2+).

A plurality of first grounding plates (74) and a plurality of second grounding plates (76) may be combined with each other to have a rectangular columnar shape. A plurality of first grounding plates (74) and a plurality of second grounding plates (76) may form a rectangular frame shape around a plurality of electrodes (66). A plurality of first grounding plates (74) and a plurality of second grounding plates (76) may cause air to flow to the electrodes (66).

A plurality of first grounding plates (74) and a plurality of second grounding plates (76) can form an air flow path around the electrode (66). The electrode (66) can be placed at the center of the flow path formed by the plurality of first grounding plates (74) and the plurality of second grounding plates (76).

In a state where the grounding portion (70) is mounted on the electrode portion (54), the conductive microfibers (68) arranged at the end of the electrode (66) can be arranged so that the grounding plates (74, 76) pass through the center of the height (78h) forming the charging path (78). The end (68a) of the conductive microfibers (68) can be arranged to be spaced apart from the inflow end (78a) of the charging path (78) formed by the grounding plates (74, 76). That is, the conductive microfibers (68) can be arranged to be spaced inward from each of the inflow end (78a) and the outflow end (78b) of the charging path (78) formed by the grounding plates (74, 76).

The dust collecting unit (80) may be provided with various materials that capture particles charged by the charging unit (52). For example, the dust collecting unit (80) may be provided with a porous fiber filter such as a non-woven fabric. In addition, a conductive material may be applied, coated, or attached to the surface of the dust collecting unit (80). Then, a predetermined current may be applied to the dust collecting unit (80), so that charged dust particles, etc. may be captured.

The dust collection unit (80) may include a dust collection unit cover (82) and a plurality of dust collection films (84) arranged inside the dust collection unit cover (82). The plurality of dust collection films (84) may be arranged such that a first dust collection film to which a high voltage is applied and a second dust collection film to which a relatively low voltage is applied intersect each other. Accordingly, foreign substances moving due to a potential difference formed between the plurality of first dust collection films and the plurality of second dust collection films may be captured.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and various modifications may be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. Furthermore, such modifications should not be understood individually from the technical idea or prospect of the present invention.

10: Air conditioner 12: Case
40: 1st heat exchanger 42: 2nd heat exchanger
44: 3rd heat exchanger 50: Electric dust collector
52: Daejeon Department 54: Electrode Department
56: Electrode cover 60: First rib
62: Banding section 64: Second rib
66: Electrode 68: Conductive microfiber
70: Grounding part 72: Grounding housing
74: First ground plate 76: Second ground plate
78: Daejeon Euro 80: Dust collection unit
90: High voltage generator 92: Frame

Claims (16)

A case having a supply path, a first inlet formed on one side of the supply path, and a first outlet formed on the other side of the supply path;
A first fan disposed on the above supply path and forming an air flow from the first inlet to the first outlet;
It includes an electric dust collector that is placed on the supply path and removes foreign substances in the air flowing through the supply path.
The above electric precipitator,
A charging unit that charges foreign substances in the flowing air;
A dust collecting unit that captures foreign substances in the air flowing through the above-mentioned main body; and
It includes a high voltage generating unit that generates a high voltage and applies the voltage to the charging unit or the dust collecting unit,
The above-mentioned Daejeon Department,
An electrode unit including a plurality of electrodes connected to the high voltage generator and generating ions in the air through high voltage;
A grounding part is provided on one side of the electrode part and includes a grounding plate arranged around each of the plurality of electrodes.
The above grounding plate forms an electrical path through which air flows around each of the plurality of electrodes,
The above electrode part further includes an electrode part cover forming an exterior,
The above electrode cover,
A perimeter wall that forms a space through which air flows inward,
It includes a plurality of first ribs extending in a first direction from the inner side of the above-mentioned peripheral wall and arranged spaced apart in a second direction perpendicular to the first direction,
An air conditioner in which the plurality of electrodes are arranged spaced apart from each other in the first direction on each of the plurality of first ribs. In paragraph 1,
An air conditioner in which the above grounding plate forms a peripheral wall spaced apart from the electrode in a direction perpendicular to the direction of air flow. In paragraph 1,
The above grounding plate includes a plurality of first grounding plates extending in a first direction perpendicular to the direction in which the air is introduced and arranged to be spaced apart in a second direction perpendicular to the first direction, and a plurality of second grounding plates extending in the second direction and arranged to be spaced apart in the first direction.
An air conditioner in which each of the plurality of first grounding plates and the plurality of second grounding plates forms a plurality of charge paths around which the plurality of electrodes are arranged. In paragraph 1,
An air conditioner in which the above grounding plate forms a length spaced apart from the electrode at a certain interval in the direction in which air flows. In paragraph 1,
An air conditioner in which the electrodes are arranged at a constant interval in the direction of air flow from the inlet end of the charging channel and are arranged at a constant interval in the direction of air flow from the outlet end of the charging channel. delete In paragraph 1,
The above first rib includes an inwardly convex banding portion in which the electric current path is formed,
An air conditioner in which the above electrode is placed in the above banding section. In paragraph 7,
An air conditioner in which the above electrode is positioned so as to protrude in the direction in which air flows into the banding portion. In paragraph 7,
The electrode portion includes a plurality of second ribs extending in a second direction perpendicular to the first rib and arranged spaced apart from each other in the first direction,
The above grounding part is an air conditioner that is installed on one side of the second rib. In paragraph 1,
At the end of the above electrode, conductive microfibers are placed so as to be exposed,
An air conditioner in which the distance between the ends of the conductive microfibers and the inlet end of the charging channel is formed to be smaller than or equal to the distance between the ends of the conductive microfibers and the outlet end of the charging channel. In paragraph 1,
At the end of the above electrode, conductive microfibers are placed so as to be exposed,
An air conditioner in which the distance between the ends of the conductive microfibers and the inlet end of the charging path is formed at a distance of 1/4 to 1/8 of the distance between the conductive microfibers and the ground plate to which they are adjacently arranged. In paragraph 1,
The above electric precipitator,
Including a frame on which the above-mentioned main body and the above-mentioned dust collection unit are mounted,
The above-mentioned main body is arranged so as to be detachable in one direction based on the above-mentioned frame,
An air conditioner in which the above dust collection unit is arranged to be separated in a direction different from the direction in which the charging unit is separated based on the frame. In Article 12,
An air conditioner in which the grounding part is detachably arranged relative to the electrode part. In Article 13,
An air conditioner in which the grounding part is separated from the electrode part in a direction away from the dust collecting part. In Article 12,
An air conditioner in which the charging unit and the dust collecting unit are each mounted on a frame, and the charging unit is positioned at a certain distance from the dust collecting unit. In Article 11,
The above grounding part further includes a grounding housing that forms a space in which the grounding plate is placed,
An air conditioner in which the above grounding housing is fixedly positioned on the above electrode section.

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