JP5464178B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner.

  In recent years, an air conditioner that has a discharge function and can clean air taken in from a room has been used. The discharge function is realized by generating a discharge between a needle or linear ionization electrode and a counter electrode, and is used for electrostatic dust collection, generation of negative ions, active species that are strong oxides, and the like. For example, an air conditioner described in Patent Document 1 (Japanese Utility Model Publication No. 63-63129) includes an intake grill part, a filter body, a guide plate body that separates these two spaces into two layers, and an electric dust collection function. The ionization part is arranged in a two-layer space ventilation path formed between the end part of the guide plate body and the main body. Hereinafter, the part for exhibiting a discharge function like the said ionization part is made into a discharge unit.

  By the way, since the discharge unit is disposed in the flow path of the sucked air, dirt in the air adheres to the discharge unit. If dirt adheres to the terminal which is a contact for connecting to the power supply of the discharge unit, it causes a problem such as poor contact, which is not preferable. In the air conditioner described in Patent Document 1, the contact terminals are temporarily positioned on the back surface of the mounting case. However, after the entire case is sucked from the intake port, it is located at the place where the air that has been guided by the guide plate and flows separately on the left and right sides collides, so the air wraps around the case and there is a contact terminal It will flow into the space. For this reason, the configuration is insufficient from the viewpoint of preventing contamination of the contact terminals.

  Then, the subject of this invention is providing the air conditioner provided with the structure with which the contact of a discharge unit is hard to get dirty.

An air conditioner according to a first aspect of the present invention includes a discharge unit , a main body side contact, a flange portion, a main body, and a front panel . The discharge unit has two positive and negative electrodes having a potential difference, a discharge part that holds the electrode, and a contact part that connects the electrode to a power source, and discharges between the electrodes. The main body side contact has an insertion hole into which the contact portion is inserted. The flange portion covers a gap between the contact portion and the insertion hole in a state where the contact portion is inserted into the insertion hole. The main body houses the discharge unit. The front panel is plate-shaped and covers the front of the main body. Moreover, the discharge part of the discharge unit is disposed in the air flow path, and the contact part is disposed outside the flow path. The front panel presses the flange portion. Here, the air flow path is guided by a member that forms a space in the air conditioner and sucks air into the air conditioner from an opening such as a suction port. It is the air path that tries to flow through the shortest path as much as possible.

In this air conditioner, the contact portion of the discharge unit is disposed outside the air flow path. Therefore, it is possible to provide an air conditioner having a configuration in which the contacts of the discharge unit are hardly contaminated.

  Further, by covering the gap between the contact portion and the insertion hole in a state where the contact portion is inserted into the insertion hole of the main body side contact, the sucked air can be prevented from touching the contact as much as possible.

  Furthermore, when the flange portion is pressed by the front panel, the sucked air can be prevented from touching the contact as much as possible.

The air conditioner which concerns on the 2nd viewpoint of this invention is an air conditioner which concerns on a 1st viewpoint, Comprising: A contact part and a flange part are integrated.

In this air conditioner, the sucked air can be prevented from touching the contact as much as possible.

An air conditioner according to a third aspect of the present invention is the air conditioner according to the first aspect or the second aspect , and the discharge unit further includes a grip portion for gripping the discharge unit by hand. The grip portion is between the discharge portion and the contact portion.

In this air conditioner, the discharge unit can be grasped by hand by having a grip portion between the discharge portion and the contact portion. Thereby, the discharge unit can be easily handled.

An air conditioner according to a fourth aspect of the present invention is the air conditioner according to any one of the first aspect to the third aspect , and the discharge unit further includes a casing that covers the discharge part. A drain hole is formed in the casing.

In this air conditioner, since the drain hole is formed in the casing that covers the discharge part, it is possible to make it difficult for water to collect in the discharge unit.

In the air conditioner according to the first aspect or the second aspect of the present invention, an air conditioner having a configuration in which the contacts of the discharge unit are hardly contaminated can be provided. Further, the sucked air can be prevented from touching the contact as much as possible.

In the air conditioner according to the third aspect of the present invention, the discharge unit can be easily handled.

In the air conditioner according to the fourth aspect of the present invention, it is possible to make it difficult for water to collect in the discharge unit.

The front perspective view of the air cleaner concerning one embodiment of the present invention. The side view of the air cleaner which concerns on one Embodiment of this invention The conceptual diagram which shows the path | route of the ventilation in the air cleaner which concerns on one Embodiment of this invention. The exploded view of the air cleaner concerning one embodiment of the present invention. External view of discharge unit Casing spread view of the discharge unit VII-VII sectional view of the discharge unit of FIG. VIII-VIII sectional view of the discharge unit of FIG. Front perspective view of contact unit XX sectional drawing of the air cleaner of FIG. XI-XI sectional drawing of the air cleaner of FIG. The conceptual diagram which shows the flow path of the air in the air cleaner which concerns on one Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The following embodiments are specific examples of the present invention and do not limit the technical scope of the present invention.

(1) General Configuration of Air Conditioner An air conditioner according to an embodiment of the present invention is an air purifier 100. The air cleaner 100 includes a main body 100a and a plurality of casing members that cover the main body 100a. The main body 100a houses a discharge unit 200, a filter unit 310, a humidification unit 320, a sirocco fan 350, a streamer discharge unit 340, and the like, which will be described later.

(1-1) Appearance FIG. 1 is an external front perspective view of the air cleaner 100 in a front perspective view. The front surface of the air cleaner 100 is covered with a synthetic resin front panel 102 which is one of the casing members. There is a portion not covered by the front panel 102 below the front, and a lower suction port 113 is provided in the portion. FIG. 2 is an external side view of the air cleaner 100 in a side view. In FIG. 2, a part of the side surface of the air purifier 100 is covered with a synthetic resin side suction port forming member 103 which is one of the casing members. The side suction port forming member 103 is formed with a first side suction port 111 that takes in air so as to extend in the vertical direction. That is, as for the 1st side suction inlet 111, the vertical dimension is larger than the horizontal dimension. Although not shown, a part of the side surface on the opposite side of the air cleaner 100 is similarly covered with the side suction port forming member 103. The side suction port forming member 103 is formed with a second side suction port 112 extending in the vertical direction at a position facing the first side suction port 111. The vertical and horizontal dimensions of the second side suction port 112 are the same as the dimensions of the first side suction port 111. Hereinafter, when referring to the first side suction port 111 and the second side suction port 112, it is referred to as the side suction port 110, and when referring to all of the side suction port 110 and the lower suction port 113, it is simply referred to as the suction port. To do.

  The air outlet 114 through which the air sucked into the air purifier 100 is blown out is provided on the upper surface of the air purifier 100 as shown in FIGS.

  The lower suction port 113 may be formed in the front panel 102, and the front panel 102 and the side suction port forming member 103 may be a single integrated casing member.

(1-2) Air Flow FIG. 3 is a conceptual diagram for explaining the concept of dust removal and decomposition in the air cleaner 100. In FIG. 3, the sirocco fan 350 generates an air flow 501 from the inlet to the outlet 114. Dust and odorous components are removed from the indoor air sucked from the suction port by the filter unit 310, and clean air is blown out from the sirocco fan 350.

(2) Detailed Configuration (2-1) Discharge Unit FIG. 4 is an exploded view in which a part of the casing member such as the front panel 102 is removed from the air cleaner 100. As shown in this figure, the discharge unit 200 has a cylindrical shape whose length is longer than the width, and one discharge unit 200 is provided in the vicinity of the first side suction port 111 and the second side suction port 112. Each is detachably installed in a state where it stands along each side suction port 110. The vertical and horizontal dimensions of the discharge unit 200 are larger than the vertical and horizontal dimensions of the side suction port 110, and the discharge unit 200 is in contact with the side suction port forming member 103 so that there is no gap between them. All of the air sucked from the side suction port 110 is configured to pass through the discharge unit 200. The discharge unit 200 charges relatively small dust floating in the sucked air.

  Hereinafter, the upper or upper end refers to the upper or upper end in a state where the discharge unit 200 is vertically mounted on the air cleaner 100, and the lower or lower end means that the discharge unit 200 is similarly mounted vertically on the air cleaner 100. It shall refer to the lower or lower end in the state. Further, the discharge unit 200 disposed in the vicinity of the first side suction port 111 is referred to as a first discharge unit 201, and the discharge unit 200 disposed in the vicinity of the second side suction port 112 is referred to as a second discharge unit 202. . Since the first discharge unit 201 and the second discharge unit 202 have basically the same configuration, the first discharge unit 201 will be described below, and the description of the second discharge unit 202 will be omitted.

<Discharge part>
The first discharge unit 201 will be described with reference to FIGS. In the following description, “upper” refers to the upper side when the first discharge unit 201 is mounted on the air cleaner 100, and “lower” refers to the lower side when the first discharge unit 201 is mounted.

  FIG. 5 is an external view of the first discharge unit 201. The first discharge unit 201 includes a synthetic resin casing 210 having a vertically long cylindrical shape. As shown in FIG. 6, the casing 210 is vertically divided into a casing first part 211 and a casing second part 212, and the casing first part 211 and the casing second part 212 are hinged. 213 is connected.

  The casing first portion 211 holds a tungsten ionization wire 231 that is a positive electrode of the two positive and negative electrodes. The negative electrode is held by the casing second part 212. The negative electrode is a stainless steel plate-like electrode (electrode plate 232).

  FIG. 7 is a cross-sectional view of the first discharge unit 201 with the hinge 213 opened. The casing first part 211 has a shape that is long in the vertical direction and whose cross section is close to a semicircle. Here, the substantially semicircular concave curved surface is defined as the inside of the casing first portion 211, and the substantially semicircular convex curved surface is defined as the outside of the casing first portion 211. Further, the left and right when viewed from the outside are the left and right of the casing first portion 211. A bridge 217 is provided inside the vicinity of the lower end of the casing first portion 211. As shown in FIG. 7, the bridge 217 is a member that protrudes outward from the space formed by the casing first portion 211, and the ionization wire 231 is fitted on both sides near the tip thereof. A depression is formed. One end of an ionization wire 231 is attached to the upper end of the casing first portion 211. The ionization line 231 extends from the upper end of the casing first part 211 to the bridge 217 in the vicinity of the lower end. The ionization line 231 fits into the depressions on both sides near the tip of the bridge 217, wraps around the tip, and folds toward the upper end of the casing first part 211. The ionization line 231 extends to the upper end of the casing first part 211, and the end of the ionization line 231 that has returned to the upper end of the casing first part 211 is attached to the upper end of the casing first part 211. That is, the ionization line 231 is installed in a U shape.

  The casing second portion 212 is long in the vertical direction, and has a concave cross section as shown in FIG. Here, the concave surface of the concave shape is the inside of the casing second portion 212, and the surface opposite to the concave surface of the concave shape is the outside of the casing second portion 212. The left and right sides when viewed from the outside are the left and right sides of the casing second portion 212. An electrode plate 232 that is a negative electrode is attached to the inside of the casing second part 212. The electrode plate 232 is shaped to form three opposing walls parallel to the longitudinal direction of the casing second portion 212. Here, for convenience of explanation, of the three walls, the middle wall is referred to as a middle wall 232b, and the left and right walls of the middle wall 232b are referred to as a left wall 232c and a right wall 232a, respectively. The left wall 232c and the right wall 232a are accommodated in a space formed by the casing second portion 212. On the other hand, the middle wall 232b protrudes about several millimeters from the space. In addition, as shown in FIG. 6, a drain hole 218 is provided at the lower end of the casing second portion 212 so that water does not collect in the casing.

  As shown in FIG. 6, the hinge 213 connects the left side of the casing first part 211 and the right side of the casing second part 212. Here, the right or left is the right or left when viewed from the outside of the casing first part and the casing second part (the same applies hereinafter). When the hinge 213 connecting the casing first part 211 and the casing second part 212 is closed, the edge of the casing first part 211 and the edge of the casing second part 212 are in contact with each other as shown in FIG. . In a state where the hinge 213 is closed, the ionization line 231 is located in a space formed by the casing second portion 212 and surrounds the middle wall 232b in a U shape. Further, the U-shaped ionization line 231 is surrounded by the left wall 232c and the right wall 232a from the outside. That is, the ionization line 231 is located between the left wall 232c and the middle wall 232b, and between the middle wall 232b and the right wall 232a, and in a state parallel to each wall, the ionization line 231 is appropriate for the wall and the discharge. Keep the distance of.

  When a high voltage is applied to the ionization line 231, a potential difference is generated between the two electrodes, and one kind of corona discharge is generated between the two electrodes at a portion where the ionization line 231 and the electrode plate 232 face each other. The part where the discharge of the discharge unit 200 occurs is called a discharge part 200a.

  In the part covering the discharge part 200a, the casing first part 211 and the casing second part 212 are in a lattice shape as shown in FIG. Further, the outer side of the lattice-shaped portion of the first casing portion 211 is covered with a prefilter (not shown). The sucked air enters the casing 210 from the latticed portion and passes through the discharge part 200a. The dust in the air that passes through is charged by electric discharge.

<Grip part>
The part located on the part which covers the discharge part 200a among the casing 1st part 211 and the casing 2nd part 212 is called the holding part 200b. In the holding part 200b, the casing first part 211 and the casing second part 212 are not in a lattice shape, and the casing first part 211 is slightly recessed so as to be easily grasped by hand. That is, the casing first portion 211 has a semicircular cross-sectional radius in the grip portion 200b that is smaller than a portion covering the discharge portion 200a. When viewed from the outside of the side suction port forming member 103, the gripping part 200 b is positioned so as to overlap the rear of the side suction port forming member 103, and is directly applied to the air flowing in from the first side suction port 111. Absent. For this reason, it is difficult for dust to adhere to the gripping part 200b, and it is difficult to get dirty. Therefore, the user can attach and detach the first discharge unit 201 without getting his hands dirty by grasping the grip portion 200b.

<Contact part>
Next, referring to FIG. 6, a description will be given of a contact point between an electrode including the ionization line 231 and the electrode plate 232 and a circuit having a high voltage power source.

From the upper end of the casing first portion 211, a synthetic resin contact member (hereinafter referred to as a first contact member 214) having a cross-sectional shape close to a T-shape protrudes. The first contact member 214 is attached to the right from the vertical center line of the upper end of the casing first portion 211. The first contact member 214 includes a first contact member main body 214a and a flange portion 216a. As shown in FIG. 6, two plate-like protrusions are provided on the left side of the first contact member main body 214a. The two protrusions are positive contact terminals (hereinafter referred to as first contact terminals 233), and the harness extends from both ends of the ionization wire 231 that is the positive electrode to one of the different protrusions. ing. The right side of the first contact member main body 214a is joined to the plate-like flange portion 216a. The plane of the flange portion 216a is configured to be substantially perpendicular to the plane of the first contact member main body 214a. That is, the cross section of the portion where the first contact member main body 214a and the flange portion 216a are joined has a shape close to a T-shape.

Further, a synthetic resin contact member (hereinafter referred to as a second contact member 215) having a cross-sectional shape close to a T-shape protrudes from the upper end of the casing second portion 212. The second contact member 215 is attached to the left from the vertical center line of the upper end of the casing second portion 212. The second contact member 215 includes a second contact member main body 215a and a flange portion 216b. A part of the negative electrode plate 232 extends in a plate shape along the right end of the second contact member main body 215a to form a negative contact terminal (hereinafter referred to as a second contact terminal 234). The left side of the second contact member main body 215a is joined to the plate-like flange portion 216b. The plane of the flange portion 216b is configured to be substantially perpendicular to the plane of the second contact member main body 215a. That is, the cross section of the portion where the second contact member main body 215a and the flange portion 216b are joined has a shape close to a T-shape.

  When the hinge 213 connecting the casing first part 211 and the casing second part 212 is closed, the flange part 216a of the first contact member 214 and the flange part 216b of the second contact member 215 form one flange 216. To do.

  The first contact terminal 233 and the second contact terminal 234 are collectively referred to as a contact portion.

<Second discharge unit>
The second discharge unit 202 has the same configuration as the first discharge unit 201 except for the following points. That is, the casing first part 211 and the casing second part 212 are in the second discharge unit 202 opposite to the first discharge unit 201 (the right side of the casing first part 211 and the left side of the casing second part 212). They are connected by a hinge 213. Further, the position where the first contact member 214 and the second contact member 215 are attached is also on the opposite side of the first discharge unit 201 (on the left side of the longitudinal center line of the casing first portion 211, the casing second portion 212). The right side of the vertical center line). The first contact terminal 233 protrudes to the right side of the first contact member main body 214a. The flange portions 216a and 216b of the first contact member 214 and the second contact member 215 are also provided on the left side of the first contact member main body 214a and the right side of the second contact member main body 215a, respectively.

<Installation of discharge unit>
Returning to FIG. 4 again, a contact unit 301 is disposed at the upper part of the front surface of the main body of the air cleaner 100. FIG. 9 is a front perspective view of the contact unit 301 with the cover covering the top removed. The contact unit 301 houses a harness that constitutes a circuit that connects the discharge unit 200 to a high-voltage power supply. A total of four vertical slits 302 are provided on the front surface of the contact unit 301, two on each of the left and right sides of the front surface. The discharge unit 200 is attached by inserting the first contact terminal 233 and the second contact terminal 234 into each vertical slit 302 provided on the front surface of the contact unit 301. A clip-shaped harness terminal 303 is provided in the vertical slit 302. When the first contact terminal 233 and the second contact terminal 234 are inserted into the vertical slit 302, they are sandwiched between the harness terminals 303. Thereby, the electrode of the discharge unit 200, that is, the ionization line 231 and the electrode plate 232 are connected to the circuit including the high voltage power source.

<Preventing contact contamination>
FIG. 11 is a front sectional view of a portion where the contact unit 301 of the air cleaner 100 is installed in a state where the discharge unit 200 is mounted on the air cleaner 100. When the first contact terminal 233 and the second contact terminal 234 are inserted into the vertical slit 302 provided on the front surface of the contact unit 301 and the discharge unit 200 is attached to the contact unit 301, the vertical slit 302 and the discharge unit 200. The gap between the first contact terminal 233 and the second contact terminal 234 is covered with the flange 216 of the discharge unit 200 as shown in FIG. As a result, the first contact terminal 233 and the second contact terminal 234 are almost sealed in the vertical slit 302 and are less likely to get dirty.

  The front panel 102 is provided with four protrusions 102 a that protrude inside the front panel 102. When the front panel 102 is attached to the front surface of the air cleaner 100, two protrusions 102a are provided at positions facing the flanges 216 of the two discharge units 200 that are mounted. Therefore, in a state where the front panel 102 is attached to the front surface of the air purifier 100, as shown in FIG. 11, the flanges 216 of the two discharge units 200 are each provided with two protrusions provided on the front panel 102. The portion 102a is pressed against the front surface of the contact unit 301. Thereby, the space in the vertical slit 302 into which the first contact terminal 233 and the second contact terminal 234 are inserted is more reliably sealed, and the dirt is less likely to be attached.

  FIG. 10 is a cross-sectional view of the air cleaner 100 cut laterally at a position below the contact unit 301. As can be seen by comparing FIG. 11 which is a cross-sectional view of the air purifier 100 cut laterally at the position where the contact unit 301 is installed, and FIG. 10, the front of the air cleaner 100 is placed at the position where the contact unit 301 is installed. While there is almost no gap between the front panel 102 to be covered, a relatively large space exists below the contact unit 301. Here, the space means that no structure exists. The plane of the space is surrounded by the front panel 102, the prefilter 311, and the two discharge units 200, and the top and bottom are positioned slightly above the bottom inside the air cleaner 100 main body 100 a and the prefilter 311. The contact unit 301 is surrounded by the bottom. The distance between the front panel 102 and the prefilter 311 is preferably at least 4 cm, and in this embodiment, the distance is about 4 cm. The distance between the two discharge units 200 is about 24 cm. The height of the space is not less than the vertical dimension of the pre-filter 311. The space is a flow path of air that is sucked from the suction port and flows toward the sirocco fan 350 provided behind the filter unit 310. Here, the air flow path is guided by a member that forms a space in the air conditioner, and passes through the shortest path from an opening such as a suction port to a fan that sucks air such as the sirocco fan 350 into the air conditioner. It is the path of the air that tries to flow.

  The flow of air in the air cleaner 100 is illustrated in FIG. Reference numeral 500 in the drawing indicates an air flow, that is, an air flow path 500. That is, the air sucked from the lower suction port 113 provided below the front surface of the air cleaner 100 flows into the space and flows straight toward the prefilter 311. The air sucked from the left and right side suction ports 110 is guided by the side suction port forming member 103, passes through one of the discharge portions 200 a of the two discharge units 200, flows into the space, and is prefiltered. Bent toward the 311 and flow.

  The discharge part 200a of the discharge unit 200 is disposed in an air flow path 500 as shown in FIG. On the other hand, as shown in FIG. 12, the flange 216 covering the first contact terminal 233 and the second contact terminal 234 is disengaged upward from the air flow path 500. That is, the first contact terminal 233 and the second contact terminal 234 that are contact portions of the discharge unit 200 are outside the air flow path 500. This is because the vertical slit 302 on the front surface of the contact unit 301 into which the first contact terminal 233 and the second contact terminal 234 are inserted is located above the space. Since the contact unit 301 is not positioned to block the flow of air that tries to pass through the shortest path as far as possible to the sirocco fan 350, the air hardly circulates in front of the contact unit 301. Further, as described above, the vertical slit 302 is covered with the flange 216. Accordingly, the air sucked from the suction port hardly flows into the vertical slit 302 on the front surface of the contact unit 301 into which the first contact terminal 233 and the second contact terminal 234 are inserted. Dirt is difficult to adhere to the second contact terminal 234.

(2-2) Other component The other component of the air cleaner 100 is demonstrated below.

(2-2-1) Filter Unit As shown in FIG. 3, the filter unit 310 includes a pre-filter 311, a HEPA (High Efficiency Particulate Air Filter) filter 312, and a deodorizing element 313. First, large dust is removed by the pre-filter 311. Next, finer dust is removed by the HEPA filter 312. Further, the air that has passed through the HEPA filter 312 is decomposed or adsorbed by formaldehyde, odor components, and the like by a deodorizing element 313 containing activated carbon or the like.

(2-2-2) Streamer Discharge Unit A part of the air blown out from the sirocco fan 350 is attached to the streamer discharge unit (the contact unit 301 in FIGS. 4 and 9) as a tributary 502 shown in FIG. 340). When this tributary 502 passes through the streamer discharge unit 340, the active species is supplied by the streamer discharge. The tributaries 502 supplied with the active species are blown out from the discharge port 331 to the front of the pre-filter 311 as a plurality of divided flows.

  The plurality of branch flows join the indoor air sucked from the pre-filter 311 and reach the HEPA filter 312 and the deodorizing element 313. The deodorizing effect is enhanced by the active species reaching the deodorizing element 313.

  The streamer discharge unit 340 includes a needle-like electrode made of tungsten, which is a positive electrode, and a plate-like electrode (counter electrode) that is located in the vicinity of the needle-like electrode and faces the electrode. By applying a high voltage to the needle-like electrode, streamer discharge, which is a kind of plasma discharge, is generated. Active species with high oxidative decomposition power are generated when the discharge is generated.

Air containing the generated active species flows into the two vertical air passage member 330 as shown in FIG. First lateral suction opening 111 and the second side inlet 112 of the air cleaner 100 is a long aperture in the vertical direction as described above, the two vertical air passage member 330 and the first side suction port 111 It is arranged along the second side suction port 112. Each vertical ventilation passage member 330, a plurality of discharge ports 331 are formed along the vertical direction of the first side suction port 111 and the second side inlet 112. Air containing the active species flows into the vertical air passage member 330 is blown out forwardly from the outlet 331 of the pre-filter 311 of the filter portion 310.

(2-2-3) Humidification unit 320
The humidification unit 320 includes a humidification rotor 321 and a water tray 322. The air that has passed through the deodorizing element 313 passes through the humidification rotor 321 of the humidification unit 320. When air passes through the humidification rotor 321, moisture is released from the humidification rotor 321 into the air. The humidification rotor 321 is supplied with water from the water tray 322 in order to compensate for moisture that is reduced by being discharged. Air containing active species is introduced into the water tray 322 from one of the discharge ports 331 provided in the vertical ventilation path member 330.

(3) Air cleaning operation | movement The air cleaning effect | action by the air cleaner 100 is demonstrated, referring FIG. The air sucked from the first side suction port 111 and the second side suction port 112 reaches the discharge unit 200. Therefore, relatively large dust and dust are removed from the air by the prefilter provided outside the casing first portion 211 of the discharge unit 200. Next, the air passes through the discharge part of the discharge unit 200. At that time, dust or the like contained in the air is positively charged. Then, the air reaches the filter unit 310. On the other hand, the air sucked from the lower suction port 113 reaches the filter unit 310.

  In the filter unit 310, the air first passes through the prefilter 311. At that time, relatively large dust and dust are removed from the air by the pre-filter 311. In addition, the action of the photocatalyst contained in the prefilter 311 and catechin suppresses the growth of fungi and viruses such as fungi and bacteria contained in the dust attached to the fibers of the prefilter 311 and inactivates the virus. Is done.

  The air that has passed through the prefilter 311 passes through the HEPA filter 312. The charged dust in the air is adsorbed by the HEPA filter 312.

  The air that has passed through the HEPA filter 312 passes through the deodorizing element 313 and is deodorized at this time.

  Thereafter, the air reaches the humidification rotor 321 of the humidification unit 320. The air passes through the humidification rotor 321 and is humidified.

  The air that has passed through the filter unit 310 and the humidification rotor 321 and has been purified is blown into the room from the air outlet 114. A part of the purified air is introduced into the streamer discharge unit 340 as a tributary 502 without being blown into the room.

  Active species are generated by the streamer discharge in the streamer discharge unit 340. The air containing the active species passes through the two vertical ventilation path members 330 and is discharged from the plurality of discharge ports 331 formed in each vertical ventilation path member 330 in front of the prefilter 311. The air containing the active species is mixed with the intake air and sucked into the prefilter 311 and the HEPA filter 312. Air containing these active species inactivates or kills viruses, fungi, bacteria, and the like.

(4) Features (4-1)
In the above embodiment, the first contact terminal 233 and the second contact terminal 234 of the discharge unit 200 are inserted into the vertical slit 302 provided on the front surface of the contact unit 301, and are located outside the air flow path 500. ing. Therefore, it is possible to provide the air cleaner 100 having a configuration in which the contacts of the discharge unit 200 are not easily contaminated.

(4-2)
In the above embodiment, when the first contact terminal 233 and the second contact terminal 234 are inserted into the vertical slit 302 of the contact unit 301 and the discharge unit 200 is mounted, the vertical slit 302 and the first contact terminal 233 or second A gap between the contact terminal 234 and the contact terminal 234 is covered with a flange 216. The flange 216 is integrated with the first contact terminal 233 and the second contact terminal 234. This prevents the sucked air from touching the contacts as much as possible.

(4-3)
In the above embodiment, the flange 216 is pressed by the protrusion 102 a provided on the inner side of the front panel 102. As a result, the sucked air is prevented from touching the contacts as much as possible.

(4-4)
In the above-described embodiment, the discharge unit 200 includes the grip portion 200b that is slightly recessed so as to be easily gripped by hand. The gripping part 200b is located at a position that does not directly contact the air flowing in from the side suction port 110, and is difficult for dust to adhere to and dirt. Accordingly, the discharge unit can be grasped by the hand by having the gripping portion 200b, and the discharge unit can be easily handled.

(4-5)
In the embodiment, the drainage hole 218 is formed in the bottom of the casing second part 212 that covers the discharge part. Thereby, it is difficult for water to collect in the discharge unit 200.

(5) Modification (5-1) Modification 1A
In the above embodiment, the air conditioner is the air purifier 100. However, in other embodiments, the air conditioner may be any air conditioner such as a room air conditioner or a commercial air conditioner.

(5-2) Modification 1B
In the above embodiment, the discharge unit 200 exhibits an electric dust collection function. However, other embodiments may exhibit other functions. For example, the discharge unit 200 may generate a streamer discharge like the streamer discharge unit 340 to generate an active species that is a strong oxide. Moreover, what produces | generates a negative ion may be used.

  The present invention is applicable to an air conditioner equipped with a discharge function.

100 Air purifier (air conditioner)
100a body 102 front panel 200 discharge unit 200a discharge part 200b gripping part 210 casing 211 casing first part 212 casing second part 216 flange (flange part)
218 Drain hole 231 Ionization wire (electrode)
232 Electrode plate (electrode)
233 First contact terminal (contact part)
234 Second contact terminal (contact part)
301 Contact unit (Main unit contact)
302 Vertical slit (insertion hole)
500 Air flow path

Japanese Utility Model Publication No. 63-63129

Claims (4)

Two positive and negative electrodes (231 , 232) having a potential difference, a discharge part (200a) for holding the electrodes (231, 232), and contact parts (233, 234) for connecting the electrodes (231, 232) to a power source are provided. a discharge unit to discharge between the electrodes (231, 232) and (200),
A main body side contact (301) having an insertion hole (302) into which the contact portions (233, 234) are inserted;
A flange portion (216) that covers a gap between the contact portion (233, 234) and the insertion hole (302) in a state where the contact portion (233, 234) is inserted into the insertion hole (302);
A main body (100a) for housing the discharge unit (200);
A plate-like front panel (102) covering the front of the main body (100a);
With
Among the discharge unit (200), said discharge portion (200a) is disposed in the flow path of air (500), the contact portion (233, 234) is disposed outside of the channel (500),
The front panel (102) presses the flange (216);
Air conditioner (100). The contact portions (233, 234) and the flange portion (216) are integrated.
The air conditioner (100) according to claim 1 . The discharge unit (200) further includes a grip part (200b) for gripping the discharge unit (200) by hand between the discharge part (200a) and the contact part (233, 234).
The air conditioner (100) according to claim 1 or 2 . The discharge unit (200) further includes a casing (210) covering the discharge part (200a),
The casing (210) is formed with a drain hole (218),
The air conditioner (100) according to any one of claims 1 to 3 .

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