JP2002102327A - Air cleaner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve the sterilization in air and efficiently to ensure the smooth mixing of ions into the air by generating the plus ions and the minus ions. SOLUTION: The interior air circulated by a fan 30 in subjected to dust removal by a filter unit 20 and is partly supplied to an ion generator 40. The ion generator 40 simultaneously generates the plus ions and the minus ions by impressing AC voltage to a high-tension electrode 42 and grounding electrode 43 facing each other across a glass tube 41 (dielectric substance). The generated plus ions and the minus ions form hydrogen peroxide and/or hydroxyl radicals which remove the bacterial suspended in the air. The ion-containing air joins with the air paste the filter unit 20. As a result, the ions diffuse into the room.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an air purifier used for purifying indoor air.

[0002]

2. Description of the Related Art Indoor air is contaminated with various substances such as dust, cigarette smoke, and carbon dioxide discharged with breathing. In recent years, housing has become more airtight,
Active ventilation is necessary because pollutants are likely to remain indoors, but open houses and offices that have hay fever members in open air areas and hay fever members often open windows for ventilation. There are many things you can't leave out of your mind. Therefore, an air purifier or an air conditioner with an air purifying function is used. As a method for purifying indoor air, a method of sucking indoor air to collect dust with a filter and adsorbing contaminants with activated carbon are common.

[0003] However, dust is collected by a filter,
The method of adsorbing contaminants with activated carbon had a sense that the effect on reforming indoor air was just one step away from the labor of cleaning and replacing them. This is because the amount of ions in the air is not subject to adjustment.

[0004] There are ions in the air. Among them, negative ions have been found to have the effect of relaxing people. However, negative ions decrease when associated with a particular substance. For example, if there is cigarette smoke,
In some cases, the negative ion was reduced to about 1/2 to 1/5 of the normal value. In order to artificially increase the amount of negative ions in the air, an ion generator was developed.
It is commercially available. Meanwhile, the conventional ion generator generates only negative ions by a DC high voltage method.

[0005]

By using the above-mentioned ion generator, the amount of negative ions in the distribution of ions in the air increases, and the air is reformed to relax the air. However, negative ions have little effect on positively removing bacteria floating in the air.

[0006] In this regard, the present inventors have conducted intensive studies and as a result, have found that floating bacteria in the air can be removed by simultaneously generating both negative ions and positive ions and sending them to the air. .

Therefore, according to the present invention, an air purifier having a blower for circulating indoor air is equipped with an ion generator for simultaneously generating negative ions and positive ions, thereby enabling removal of airborne bacteria in the air. It is another object of the present invention to provide an air cleaner having a structure in which ions are efficiently and smoothly mixed into air.

Another object of the present invention is to provide a structure in which an ion generator can be easily installed in an air purifier. Further, it is another object of the present invention to form a structure in which filters used together for removing dust in the air can be combined in a good shape, the ability of the filter can be sufficiently exhibited, and the filter can be easily cleaned and replaced. It is another object of the present invention to provide a structure in which a base supporting an air purifier body can be easily combined. Still another object of the present invention is to provide a structure which can easily recognize the driving state of the ion generator and can easily install means for making the recognition.

[0009]

In order to achieve the above object, according to the present invention, there is provided a blower for circulating room air, a filter for removing dust in sucked air, and a filter between electrodes facing each other with a dielectric material interposed therebetween. In an air purifier provided with an ion generator that simultaneously generates positive ions and negative ions by applying an AC voltage, a part of the air that has passed through the filter is supplied to the ion generator, and generated by the ion generator. The air containing ions was combined with the air that passed through the filter and circulated.

[0010] When an AC voltage is applied between electrodes facing each other with a dielectric material interposed therebetween, an ionization phenomenon such as discharge occurs in the air, and positive ions and negative ions are simultaneously generated.

At this time, the positive ion is H⁺(H_Two
O)_n, O as a negative ion_Two ^-(H_TwoO)_mIs the most
It occurs stably. These plus and minus ions
Has a special sterilizing effect on airborne bacteria by itself.
There is no. However, when these ions are generated simultaneously,
Hydrogen peroxide H active species by chemical reaction_TwoO_TwoOr
A hydroxyl radical (.OH) is generated. This H_TwoO_TwoAlso
Because (.OH) shows extremely strong activity,
The airborne bacteria can be removed by sending them into the air.

In order to release the positive ions and negative ions generated as described above, a part of the air passing through the filter is supplied to the ion generator.
As a result, the air containing ions is merged with the air that has passed through the filter, so that the ions can be quickly spread throughout the room.

Further, in the present invention, the ion-containing air and the air having passed through the filter are combined outside the air purifier main body, so that the ion-containing air is different from the case where the ion-containing air is merged inside the air purifier main body. Does not come out of the ion generator due to the wind pressure of the air that has passed through the filter, and the air containing ions can be efficiently and smoothly mixed with the main flow of air that has passed through the filter.

Further, in the present invention, a wind direction setting means is provided at an air outlet of the air passing through the ion generator. Thereby, the air containing ions can be surely combined with the main flow of the air that has passed through the filter.

Further, in the present invention, the dielectric of the ion generator is formed in a cylindrical shape, caps made of an elastic material are attached to both ends thereof, and one of the caps is attached to the air purifier from a direction perpendicular to the axial direction of the dielectric. The other cap is fitted to the main body, and the other cap is brought into contact with the air cleaner main body so that a pressing force is generated on the dielectric from the axial direction. This makes it possible to easily and reliably mount the ion generator.

According to the present invention, a filter housing is provided at the center of the front of the air cleaner body, and a front panel larger than the filter housing is provided on the front of the filter housing with a fixed size relative to the air cleaner body. We attached at intervals. If the front panel is removed, the filter storage portion is exposed, so that the filter can be easily mounted, or the filter can be easily cleaned or replaced. In addition, the filter is covered by the front panel and does not impair the aesthetics of the air purifier.

Further, in the present invention, the gap between the front panel and the air purifier body is used as a suction port for room air, and the front panel itself is provided with a suction port, so that the former suction port area is larger than the latter suction port area. And As a result, the air passage capacity of the suction port can always be made to be spacious,
Sufficient air can be supplied to the filter.

According to the present invention, on the upper part of the front panel,
An engaging projection that engages with a panel receiver protruding from the air cleaner body to support the weight of the panel is formed, and a movable engaging piece that engages with the air cleaner body is provided at a lower portion of the front panel or at the front panel. The movable engagement piece which engages with the lower part was arranged in the air purifier. This facilitates attachment and detachment of the front panel, and facilitates cleaning and replacement of the filter.

In the present invention, a separate base for supporting the air purifier main body is provided, and the base and the air purifier main body are engaged with each other by sliding the two together, and the opposite of the two. An engaging means is provided for keeping the engagement of the engaging portion by preventing the sliding in the direction. This allows
The air purifier main body and a base for stably supporting the air purifier on the floor can be easily assembled.

According to the present invention, a viewing window through which the ion generator can be visually recognized is provided in the air cleaner body, and the ion generator is mounted on a circuit board disposed inside the air cleaner body in conjunction with driving of the ion generator. A luminous body to be illuminated was attached. Thereby, the driving condition of the ion generator can be easily visually recognized, and the luminous body for achieving this can be easily arranged.

In the present invention, a reflection cover is provided for reflecting light emitted from the light emitter toward the ion generator. Thereby, the light emitted from the light emitter is collected by the ion generator, and the ion generator can be efficiently illuminated even if the luminance of the light emitter is low.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. The air purifier 1 includes a main body 10 shaped like a flat box standing upright and a base 1 supporting the main body 10.
1 and one side (in this case, the front) of the main body 10, the main body 1
0 and a front panel 12 mounted at a distance. The front panel 12, as shown in FIG.
It is gently curved along the curvature of the front face of the main body 10, and has a suction port 13 in the center where a plurality of vertically long slits are arranged side by side. Although not shown in the figure, the horizontal rails reinforcing the vertical rails between the slits are formed by the front panel 12.
It is provided in various places on the back. Air is not only sucked from the suction port 13, but also from four sides of the front panel 12 through side suction ports 14 formed in a gap between the front panel 12 and the main body 10. The suction port area of the side suction port 14 (the area of the opening through which air passes) is larger than the suction port area of the suction port 13.

As shown in FIG. 2, a main air outlet 15 and a sub air outlet 16 are formed in the upper portion of the rear surface of the main body 10.
Each of the main outlet 15 and the sub outlet 16 has a plurality of vertically long slits arranged side by side. Reference numeral 17 denotes a handle, and reference numeral 18 denotes a wall hanging hole for hanging the main body 10 on a wall using a separate wall mounting bracket (not shown) or the like. When the main body 10 is hung on the wall using the wall hanging hole 18 on the lower rear portion of the main body 10,
A wall pad 18a for keeping the main body 10 vertical is provided. These are formed in a rear shell 75 (described later) of the main body 10.

FIG. 4 schematically shows an arrangement of main components in the main body 10 and an outline of an air flow. 20 is a filter unit, 30 is a blower, and 40 is an ion generator. When the blower 30 is driven, air is sucked from the suction port 13 and the side suction port 14, and is sucked into the blower 30 through the filter unit 20. Downstream of the blower 30, the air passage branches into two. One branch is a main passage 55 leading to the main outlet 15, and the other is a bypass passage 56 leading to the sub outlet 16.

Most of the air that has exited the blower 30 is blown out from the main outlet 15, and the remaining part is blown out from the sub-outlet 16. Bypass passage 56 leading to sub-outlet 16
There is an ion generator 40 in the middle of
The positive ions and negative ions generated at 0 are released into the air.

Branch 5 of main passage 55 and bypass passage 56
7 is provided with a means for adjusting the flow rate of air. The air flow rate adjusting means is constituted by, for example, a plate-shaped damper 58. The damper 58 allows the degree of opening and closing to be adjusted manually or electrically. A single damper 58 is provided for the main passage 55.
And the bypass passage 56 may be configured such that if one of the passages has a large opening, the other has a small opening.
Alternatively, independent dampers may be provided in both the main passage 55 and the bypass passage 56. With such an air flow adjusting means, the amount of air flow as a whole can be adjusted or the main passage 55 and the bypass passage 56 can be adjusted.
It is possible to adjust the flow rate distribution, such as how to adjust the flow rate ratio, so that the ion generation from the ion generator 40 can always have a substantially constant concentration regardless of the air volume.

The outer shell of the main body 10 is composed of four synthetic resin parts shown in FIG. Central frame 7
At 4, the front shell 71 and the rear shell 75 sandwich this from front and rear. The front shell 71 and the rear shell 75 are fixed to the middle frame 74 by screws (not shown). The front cover 19, which is another component, is arranged exactly on the front of the front shell 71, and is fixed to the four corners of the front shell 71 with special screws that cannot be removed with a screwdriver. Such a special screw prevents the user from removing the front cover 19 and touching the control board or the like on the back side.
Used for security purposes.

On the front side of the middle frame 74, on the side facing the front shell 71, a filter housing portion 24 is formed at the center (see FIG. 5). The filter accommodating portion 24 is a rectangular recess having a front shape, and the front shell 71 and the front cover 19 are hollowed out. Thereby, the filter storage section 24
It is exposed on the front side surface of the main body 10.

The filter unit 20 is fitted into the filter housing 24. Filter unit 20 is 3
It consists of different types of filters. That is, the pre-filter 21, the deodorizing filter 2
2. Dust collection filter 23. The pre-filter 21 is made of polypropylene and collects large dust from the sucked air. The deodorizing filter 22 has a three-layer structure in which a nonwoven fabric made of polyester is attached to a rectangular frame, activated carbon is uniformly dispersed and disposed thereon, and a nonwoven fabric made of polyester is further covered thereover. Adsorbs certain acetaldehyde, ammonia, acetic acid, etc. The dust collecting filter 23 is a so-called HEPA filter, and a melt-blown non-woven fabric (trade name “Tremicron”: manufactured by Toray Industries, Inc.) that has been processed with an electric stone is added to an aggregate made of a polyester / vinylon-based non-woven fabric. Above and below, an antimicrobial sheet made of non-woven fabric processed with hydroxyapatite is placed on top and bottom, and thermocompression-bonded,
Welded frame made of nonwoven fabric with hot melt,
Collects fine dust.

[0030] As shown in FIG.
A seal member 24a is mounted around the corner of the back wall. The seal member 24 a is in close contact with the dust filter 23, and prevents air from entering through a gap between the outer periphery of the filter unit 20 and the inner periphery of the filter housing 24. That is, it is to ensure that all the air sucked into the blower 30 has passed through the filter unit 20. The seal member 24a also has a role of floating the back surface of the dust collection filter 23 from the inner wall of the filter housing portion 24 to form a gap through which air flows.

The prefilter 21 is attached to a synthetic resin grid 21a as shown in FIG. From the left and right side surfaces of the grid 21a, a total of four engaging pieces 21b project, two per side surface. Correspondingly, the engaging piece 2 is provided on the vertical wall inside the filter housing 24.
Similarly, a total of four holes 24b for receiving 1b are formed. After putting the dust collecting filter 23 and the deodorizing filter 22 into the filter storage part 24, the pre-filter 21 is placed on the front surface of the deodorizing filter 22, and the engaging piece 21b is engaged with the hole 24b so as to bend the grid 21a. Then, the filter unit 20 is held in the filter storage section 24 without falling off.

The grid 21a has a pre-filter 21
In order to pull out the filter from the filter housing 24, knobs 21c are provided in some places. Since it is not easy for the filter unit 20 to fall off easily, the tip of the engagement piece 21b is formed in the shape of a forward-facing hook as seen in the enlarged view of FIG. It requires a moderate amount of power.

[0033] As shown in FIG.
A ventilation port 25 leading to the blower 30 is formed in a vertical wall at the back of the vehicle. The ventilation port 25 is configured by providing a large number of holes in the middle frame 74 in a radial manner. As shown in FIG. 3, the ventilation port 25 has a central portion slightly projecting toward the front side of the main body 10, and this portion supports the central portion of the dust filter 23. Accordingly, an air passage is secured on the back surface of the dust filter 23 in combination with the presence of the seal member 24a.

The structure of the blower 30 will be described with reference to FIG. Reference numeral 31 denotes a fan that rotates around a horizontal axis, and 32 denotes a motor that rotates the fan 31. The motor 32 has the middle frame 7
4 is fixed to a position corresponding to the center of the ventilation port 25 with a screw or the like. Although a turbo fan is used as the fan 31 in the figure, the type of the fan is not limited to this. It is possible to employ a propeller fan or a cross flow fan. In the case of the turbo fan shown in the drawing, the thickness is made larger than the fan diameter, and the number of revolutions is reduced to reduce the noise level. A guide wall 33 formed on a middle frame 74 surrounds the periphery of the fan 31.
The guide wall 33 is formed so as to form an involute curve, and guides the air sent from the fan 31 to the discharge portion, in this case, to the branch portion 57 of the air passage. The motor 32 is a DC motor, with emphasis on controllability.

The air leaving the fan 31 proceeds to the upper air passage, and most of the air is discharged from the main outlet 15 through the main passage 55, but the remaining part flows into the bypass passage 56. The bypass passage 56 is formed in the middle frame 74, and the terminal end is connected to the sub outlet 16. The ion generator 40 is arranged in the bypass passage 56. Next, the structure of the ion generator 40 will be described with reference to FIG.

The ion generator 40 has a pillar composed of a dielectric, a high voltage electrode and a ground electrode opposed to each other with the dielectric interposed therebetween. In the embodiment shown in the figures, a cylindrical glass tube (neoceram: outer diameter 20 mm) 41 having both open ends is used as a dielectric. The material of the dielectric is not limited to this, and any material having an insulating property may be used. There is no limitation on the shape. When the dielectric is cylindrical as in this embodiment, the larger the outer diameter and the thinner the thickness, the larger the capacitance of the dielectric, and the easier it is to generate ions, but at the same time, the more ozone is generated As the size increases, the dimensions must be determined in consideration of the balance between ions and ozone. According to the results of the experiment, the outer diameter of the glass tube was 20
It is recommended that the thickness be less than 1.6 mm and the thickness be less than 1.6 mm.

Inside and outside the glass tube 41, a high-voltage electrode 42 and a ground electrode 43 each having a stainless steel plain woven wire mesh rounded into a cylindrical shape are arranged. The high voltage electrode 42 has SUS31
6 or 4 SUS304 stainless steel wire plain woven
A 0 mesh wire mesh is used. For the ground electrode 43, a 16-mesh wire mesh made of SUS316 or SUS304 stainless steel wire is used. In order to increase the ion generation efficiency, the high voltage electrode 42 and the ground electrode 43
Is brought into close contact with the glass tube 41.

Both ends of the glass tube 41 are provided with insulating caps 4.
Close at 4, 45. The caps 44 and 45 are formed of an elastic material such as rubber. From the standpoint of resistance to ozone, the use of EPDM is preferred. At the center of each of the caps 44 and 45, there is a hole covered with a thin film-like portion so that an object can be inserted through the film-like portion when necessary. In this embodiment, a lead wire 46 is passed through a hole of the cap 44, and a high-voltage electrode 42 is inserted inside the glass tube 41.
Connected to

The lead wire 47 is connected to the ground electrode 43 in the same manner as the high voltage electrode 42. As the lead wires 46 and 47,
There is no particular limitation, and generally commercially available ones can be used, but from the viewpoint of resistance to ozone, a stainless steel wire coated with a polyfluoroethylene-based resin is preferable.

The caps 44 and 45 made of an elastic material are
It is also used to fix the glass tube 41 to the middle frame 74. That is, the caps 44 and 45 have the groove 48 on the outer peripheral portion, and the groove 48 of one of the caps 44 is provided in the rib 74 a of the middle frame 74 which is one of the components of the bypass passage 56. Fit into the notch 74b (FIGS. 11, 1)
3). This fitting is performed by pressing the groove 48 of the cap 44 against the notch 74b from a direction perpendicular to the axial direction of the glass tube 41. The other cap 45
Is formed in the middle frame 74 so as to face the rib 74a,
This also engages with a rib 74c that forms a part of the bypass passage 56. A groove 74d having a width substantially equal to the thickness of the cap 45 is formed in the rib 74c. The distance between the bottom of the groove 74d and the rib 74a is determined by the outer end face of the cap 45 and the groove 48 of the cap 44. Is slightly narrower than
When the cap 45 is pushed into the groove 74d, the outer end surface of the cap 45 is pushed by the bottom of the groove 74d (which is a vertical surface in the figure), and a pressing force is generated on the glass tube 41 in the axial direction. Therefore, the caps 44 and 45 come into close contact with the ribs 74a and 74b with a repulsive force due to their own elasticity, and the glass tube 41 is firmly fixed to the middle frame 74.

A part of the bypass passage 56 has ribs 74a,
FIG. 13 shows a state in which the ion generator storage chamber 56a is defined by 74c. 56b is an ion generator storage room 5
An air inlet 56a is provided for the ion generator storage chamber 56c.
Air outlet from a. In the drawing, reference numeral 74e denotes a pair of elastic pieces provided at the bottom of the groove 74d along the direction in which the groove 74d extends in order to increase the elasticity of the bottom of the groove 74d. The elastic piece 74e has a slit 74g at the bottom of the groove 74d.
12 are provided in parallel with each other, and a portion corresponding to the center portion of the cap 45 is
As shown in FIG. 7, the projection 74 is bent or curved and protrudes into the groove 74d. 74f is a long hole 74e and 74
The cutouts provided between e, through which the lead wires 46 pass.

In FIG. 8, reference numeral 50 denotes an ion generator 40.
Is an ozone suppression device disposed downstream of the device. this is,
When ions are generated by applying an AC voltage to the electrodes, it is for removing ozone generated inevitably. Ozone is usually gradually decomposed into oxygen, but decomposition is further promoted when an ozone decomposition catalyst is present. Thus, an ozone decomposing catalyst attached to the surface of a wire mesh is prepared as an ozone suppressing device 50. Known catalysts such as manganese dioxide, platinum, lead dioxide, copper (II) oxide, and nickel can be used as the ozone decomposition catalyst.

In order to carry the ozone decomposition catalyst on the wire mesh,
The ozone decomposition catalyst may be dispersed in the binder substance, and may be attached to the surface of the wire mesh by coating means such as dip, spin, and spray. The amount of the ozone decomposition catalyst to be carried is appropriately determined based on the amount of ozone generated.

Instead of preparing an independent ozone suppressing device, it is also possible to add an ozone suppressing function to the ion generator 40 itself. In this case, the glass tube 4
1. At least one of the high-voltage electrode 42 and the ground electrode 43 carries an ozone decomposition catalyst.

The air that has passed through the ozone suppressor 50 is blown out from the sub-outlet 16, but at this time, instead of being blown out in parallel with the airflow blown out from the main outlet 15, The direction is set by the wind direction setting means. Due to the presence of the wind direction setting means, the ion-containing air blown out from the sub-outlet 16 is discharged from the main outlet 15.
The airflow that flows out of the main body 10 and merges with the remaining airflow that has not passed through the ion generator 40.

Various types of wind direction setting means can be considered, one example of which is shown in FIG. The wind direction setting means 130 shown here has a hollow casing 131, an air inlet 132 communicating with the sub outlet 16 is formed on the bottom surface, and an air outlet 133 is formed on the side surface. Air outlet 13
The gear portion 134 is projected from the opposite side surface of the gear 3, and the casing 131 performs a swinging motion in a horizontal plane around a shaft 135 of the gear portion 134. Gear 134
Oscillating gear 136 connected to a motor and a reduction gear (not shown) is meshed with.

The swing gear 136 performs a reciprocating rotation at a predetermined angle. This movement is slow and can be changed as needed. As the swing gear 136 moves,
The casing 131 performs a swing motion. The direction of the ion-containing air blown out from the sub outlet 16 is changed by the casing 131 and is blown out from the air outlet 133 in the horizontal direction. The ion-containing air that has flowed out of the air outlet 133 joins the air that is blown out from the main outlet 15 in a manner as if sprayed, and the air containing ions is sent to every corner of the room.

In FIG. 9, the vertical blowout angle of the air blown out from the air outlet 133 is not particularly considered, but a louver for adjusting the wind direction as seen in the indoor unit of the air conditioner is provided in the air outlet 133. It may be provided so that the vertical blowing angle can be adjusted.

As another form of the wind direction setting means, the above-mentioned louver may be provided in the sub-outlet 16 so that the air blown out from the sub-outlet 16 is directed toward the air blown out from the main outlet 15. . In this case, it is preferable to provide two types of louvers, one for adjusting the wind direction in the horizontal plane and one for setting the wind direction in the vertical plane.

A nozzle may be provided in the sub-outlet 16 and the outlet of the nozzle may be directed toward the airflow blown out from the main outlet 15.

As a modification of the above embodiment, the tip of the nozzle may be extended to reach the air flow blown out from the main outlet 15 so that the ion-containing air is sucked out from the tip of the nozzle. .

In FIG. 11, reference numeral 60 denotes the ion generator 4.
It is a luminous body provided near 0. The light emitter 60 is configured by a device with low power consumption such as a light emitting diode, and emits light in conjunction with the driving of the ion generator 40. That is, when the ion generator 40 is driven, the ion generator 40 is illuminated with light of a color such as blue or green emitted from the light emitter 60, and the operation state is clarified, so that the usability is improved.

The luminous body 60 is a circuit board 61 of the air purifier 1.
Attached to. The circuit board 61 mounts a CPU, a memory, and other electronic circuit elements that are the core of control. The circuit board 61 is disposed in a space adjacent to the ion generator storage chamber 56a, and is fixed to the middle frame 74 with a screw (not shown), and only the light emitter 60 protrudes into the ion generator storage chamber 56a. . A notch 62 is formed in the circuit board 61 so that light emitted from the light emitter 60 reaches the ion generator 40. 63 is a reflection cover fixed to the circuit board 61. The reflection cover 63 is a luminous body 60
Is completely covered except for the direction in which the head is directed and the direction in which the notch 62 exists. The reflection cover 63 is for reflecting the light emitted from the light emitter 60 toward the ion generator 40, and is formed of a material having a high light reflectance such as a light-colored synthetic resin or metal. To increase the reflectance,
It is good to apply plating on the inner surface. The luminous body 60 is supported in the reflection cover 63 in such a manner that the head is slightly retracted from the end of the reflection cover 63.

A visual window 70 for visually recognizing the ion generator 40 from outside the main body 10 is provided on the upper right side of the front of the main body 10. The viewing window 70 is provided as follows (see FIG. 11). That is, the front portion of the main body 10 in this portion has a double structure of the front shell 71 and the front cover 19. The front shell 71 is formed of an opaque synthetic resin, and has an oval hole 72. The front cover 19 outside the front shell 71 is formed of a transparent synthetic resin, and a film 73 formed by painting or silk screen printing is formed on the back surface thereof. And it remains transparent, which constitutes the viewing window 70. From this transparent viewing window 70, the ion generator 40 can be confirmed. Since the hole 72 is covered with the front cover 19, a finger does not enter the hole 72 and touches the ion generator 40, and the hole 72 is safe. Through this viewing window 70, various inspections relating to the ion generator 40, such as an inspection of dust accumulation status, can be performed.

The film 73 on the rear surface of the front cover 19 is finished in a clear color tone. Thereby, the image of the air purifier 1 as a health product is emphasized. The color tone of the paint is silver metallic to emphasize the clarity.

The mounting of the front panel 12 will be described. The front panel 12 has a rectangular shape similar to the filter storage section 24 in front view, is dimensionally larger than the filter storage section 24, and completely covers and hides the filter unit 20. When the front panel 12 is viewed from above, the center has a curved shape protruding outward.

The front panel 12 is attached to the main body 10 as follows. First, a pair of left and right panel receivers 9 are provided on the front shell 71 from immediately above the filter storage unit 24.
Make 0 protrude. As can be seen in FIG. 14, the upper surface of the panel receiver 90 is recessed in an inverted trapezoidal shape when viewed from the front, and a recess 91 is provided at the bottom of the recess. Front panel 1
An engaging projection 92 corresponding to the panel receiver 90 is formed on the back surface of the panel 2 (see FIG. 17). The engagement projection 92 has a downward hook shape. If the tip of the engaging projection 92 is engaged with the concave portion 91 of the panel receiver 90 as shown in FIG. 21, the front panel 12 is placed on the front surface of the main body 10 with its weight supported by the engaging projection 92. Supported.

At the lower part of the front panel 12, a movable engaging piece 100 which is engaged with and disengaged from the main body 10 is arranged (FIGS. 18, 19,
20, 22). The movable engagement piece 100 is molded as a single component from a synthetic resin having a high elasticity, and has the following structure. The center is a plate-shaped main body 101, one end of which is a slightly narrow push button portion 102,
A spring portion 103 having a U-shaped cross section is formed at the other end. The hook portion 104 rises from near the center of the main body 101. On both sides of the main body 101, legs 105 each having an L-shaped cross section and having a tip bent outward in a hook shape are provided on each side.
It is formed one by one. Similarly, on both sides of the main body 101, three projecting pieces 10 on each side are provided so as not to overlap the leg 105.
6 is formed.

In order to mount the movable engagement piece 100, the following process is performed on the lower portion of the front panel 12.
First, a hole 12b through which the push button portion 102 passes is provided in the bent edge portion 12a on the side surface of the front panel 12. A spring receiver 12c rises from the rear surface of the panel so as to face the hole 12b. Hole 12b and spring receiver 12
c is arranged along a horizontal line, between which a pair of slide guides 107 is formed. Slide guide 107, 1
07 has guide grooves 108 extending in the horizontal direction on surfaces facing each other.

In mounting the movable engagement piece 100, first, the push button 102 is passed through the hole 12b from the inside, and the end of the spring 103 is engaged with the side surface of the spring receiver 12c. After hitting the edge, slide the main body 101 to the slide guide 107.
Press against Then, the leg 105 is fitted into the guide groove 108 while being bent by elasticity. The portion of the slide guide 107 projecting above the guide groove 108 in FIG. 19 is sandwiched between the hook-shaped bent portion at the tip of the leg 105 and the overhanging piece 106. Accordingly, the movable engagement piece 100 is slidably attached to the slide guide 107, and is urged by the spring portion 103 in a direction in which the push button portion 102 projects from the hole 12b.

As shown in FIGS. 15 and 22, a hook portion 110 protrudes from the front shell 71 so as to face the hook portion 104. When the engaging projection 92 is hooked on the panel receiver 90, the tips of the hook portion 104 and the hook portion 110 come into contact with each other. The contact points are inclined with respect to each other, and when the lower part of the front panel 12 is pressed against the main body 10 in this state,
The movable engagement piece 100 slides against the biasing force of the spring portion 103 due to the slope action between the hook portions 104 and 110. Eventually, the hooks 104 and 110 are engaged as shown in FIG. 22, and the front panel 12 does not separate from the main body 10 even if the lower part of the front panel 12 is pulled forward. Further, since the hook portion 110 has a barrier 111 on the upper side as shown in FIG.
Does not escape from the hook portion 110. To release the hook 104 from the hook 110, the push button 102 is pressed.

The movable engagement pieces 100 are arranged symmetrically on both sides of the front panel 12. Instead of disposing the movable engagement piece 100 on the front panel 12 side, the movable engagement piece 100 may be disposed on the main body 10 side and the hook portion 110 may be provided on the front panel 12 side.

The attachment of the base 11 will be described. The base 11 is also a synthetic resin molded product, and the main body mounting surface 1 on the upper surface.
1a is a slope that gradually rises backward (see FIG. 23). The bottom surface of the main body 10 is also inclined accordingly. A hook-shaped engaging portion 11b bent forward is formed at the rear end of the main body mounting surface 11a. Body 1
A concave engaging portion 75a for receiving the engaging portion 11b is formed on the bottom surface of the rear shell 75. Main body mounting surface 11
A fastening means 120 is provided at the front part of a. Fastening means 1
Reference numeral 20 denotes an engagement recess 121 formed on the main body mounting surface 11a.
An engagement projection 122 that projects from the bottom surface of the front shell 71 of the main body 10 and fits into the engagement recess 121;
And a thumbscrew 124 that is screwed into the engaging projection 122 through the hole 123 at the bottom.

The main body mounting surface 11a of the base 11 is
When the base 11 and the main body 10 are slid with each other, the engaging portion 11b is engaged with the engaging portion 75a at the end of the sliding stroke, and the engaging projection 122 is engaged with the engaging concave portion 121.
(See FIG. 24). The engagement of the engagement protrusion 122 with the engagement recess 121 prevents the base 11 and the main body 10 from sliding in opposite directions. This is the engagement portion 11
b means that the engagement portion 75a remains engaged. Here, if the thumb screw 124 is screwed into the engaging projection 122 and the front part of the main body mounting surface 11a is fixed to the front shell 71, the base 11 is firmly fixed to the main body 10.

The structure of the engaging means 120 is not limited to the above. For example, the engaging recess 121 is connected to the front shell 71.
And the engaging projection 122 may be arranged on the base 11. The engagement recess and the engagement protrusion may be eliminated, and the slide of the base 11 and the main body 12 may be stopped only by the thumb screw 124. In addition, various modifications are possible.

Reference numeral 80 denotes an operation panel provided beside the viewing window 70. As shown in FIG. 25, a switch for switching the operation on / off and the operation mode is provided. A remote control 81 shown in FIG.
A remote control light receiving unit 82 for receiving a control signal from the remote controller is provided.

Next, the operation and function of the air purifier 1 will be described. When the air purifier 1 is operated, the fan 31 is rotated by the motor 32, and the room air is sucked through the suction port 13 and the side suction port 14 of the front panel 12. The sucked-in air collects large dust by the pre-filter 21 and then adsorbs odor components such as acetaldehyde, ammonia and acetic acid by the deodorizing filter 22. Deodorizing filter 2
The air that has passed through 2 is collected by the dust collection filter 23 to finer dust, becomes clean air free of odor and dust, and is discharged from the main outlet 15 into the room.

All the air leaving the fan 31 is the main outlet.
15 does not exit, and a part enters the bypass passage 56.
And supplied to the ion generator 40. Ion generation
In the device 40, between the high voltage electrode 42 and the ground electrode 43
AC voltage of about 1.75 Kv is applied to the
Positive ions and negative ions outside a certain glass tube 41
Occur simultaneously. Positive ion at this time, minus
The ion concentration is about 20,000 / CC and the ozone concentration is 0.0
1 PPM or less. H as a positive ion ⁺(H
_TwoO)_n, O as a negative ion_Two ^-(H_TwoO)_mIs the most
Generated stably.

The use of positive ions alone or negative ions alone has no particular effect on bacteria floating in the air. Positive ions and negative ions cause a chemical reaction, and hydrogen peroxide water H ₂ O ₂ or a hydroxyl radical (· OH), which is an active species, is generated. The hydrogen peroxide H ₂ O ₂ or the hydroxyl radical (.OH) has a strong activity, thereby eliminating bacteria floating in the air. In the experimental example showing the results in FIG. 27, 86 hours after the start of operation,
%, 93% after 4 hours and 99% after 20 hours.

While the ion generator 40 is generating ions, the light emitter 60 emits light, for example blue light, to illuminate the ion generator 40. By visually recognizing this from the outside of the viewing window 70, the user can know that the ion generator 40 is being driven, and can use it with confidence. Luminous body 60
Are covered with the reflection cover 63 and do not directly irradiate the viewing window 70. Therefore, even when the air purifier 1 is placed in a dark place, the ion generator 40 can be visually recognized without being dazzled by the direct irradiation light from the light emitter 60.
It is also possible to put the light emitter 60 in the glass tube 41 and make it appear that the ion generator 40 emits light from the inside. In addition, a special paint sensitive to an electric field is applied to the glass tube 41, and the color of the paint, that is, the color of the glass tube 41 changes between when the high voltage electrode 42 and the ground electrode 43 are and are not applied with an AC high voltage. You may do so.

The ion generator 40 generates positive ions and negative ions, but also generates ozone. Ozone affects the human body, and it is not preferable to increase the amount in the air. Therefore, it is necessary to reduce the ozone concentration as much as possible. For this reason, the ozone suppressing device 50 in which an ozone decomposing catalyst is supported on a wire mesh is arranged downstream of the ion generator 40. When air containing ozone passes through the ozone suppressing device 50, the ozone is decomposed. Is done. The ozone concentration of the air discharged from the sub outlet 16 can be reduced to one tenth or less of the standard value of the Japan Industrial Hygiene Association.

After passing through the ion generator 40, the air containing positive ions and negative ions generated from the ion generator 40 is blown out from the sub-outlet 16, and then is blown from the main outlet 15 by the wind direction setting means 130. The direction of the blown air flow is changed, and the air merges with the remaining air that has not passed through the ion generator 40 above the main outlet 15. The positive ions and the negative ions are diffused into the room on the strong airflow from the main outlet 15. As a result, dust is collected, positive ions and negative ions are added to the deodorized air, and the airborne bacteria in the indoor air are removed.

When the air purifier 1 is operated for a long time, dust is entangled in the suction port 13 and air escape becomes worse. However, even if such a situation occurs, the side suction port 1 is not affected.
Since abundant air flows in from the direction 4, air purification efficiency does not decrease.

The embodiment of the present invention has been described above. However, various modifications can be made without departing from the gist of the present invention.

[0075]

According to the present invention, positive ions and negative ions are simultaneously applied to an air purifier provided with a blower for circulating indoor air by applying an AC voltage to a high voltage electrode and a ground electrode opposed to each other with a dielectric interposed therebetween. A generator for generating ions was provided. Thereby, positive ions and negative ions having a disinfecting effect can be distributed throughout the room.
Since a filter for removing dust in the air is present on the upstream side of the ion generator, dust is removed from the circulating air, and dust adhesion to the ion generator can be prevented.

The air supplied to the ion generator is a part of the air that has passed through the filter, and the air containing ions generated by the ion generator is merged with the air that has passed through the filter. Therefore, ions can be spread to every corner of the room by powerful airflow.

In addition, since the air containing the ions generated by the ion generator and the air having passed through the filter are merged outside the main body of the air purifier, this is different from the case where the air is merged inside the main body of the air purifier. In addition, the ion-containing air flow can be reliably merged with the main air flow without being pushed back by the wind pressure.

By providing a wind direction setting means at the air outlet of the air that has passed through the ion generator, the ion-containing air flow can be directed in a direction that easily merges with the main air flow.

Further, the dielectric of the ion generator is cylindrical, and caps made of an elastic material are attached to both ends thereof, and one of the caps is fitted to the air purifier main body from a direction perpendicular to the axial direction of the dielectric. The other cap is brought into contact with the main body of the air cleaner so that a pressing force from the axial direction is generated on the dielectric, thereby fixing the ion generator in the main body of the air cleaner. By utilizing this, the ion generator can be securely attached.

A filter housing is provided at the center of the front of the air purifier main body, and a front panel having a size larger than the filter housing is provided at a predetermined interval on the front of the filter housing. Since the filter housing is exposed when the front panel is removed, the filter can be easily mounted, or the filter can be easily cleaned or replaced. In addition, the filter is covered by the front panel and does not impair the aesthetics of the air purifier.

Further, the gap between the front panel and the air purifier main body is used as a suction port for room air, and the front panel itself is provided with a suction port, so that the former suction port area is larger than the latter suction port area. The air passage capacity of the suction port can always be made large, and sufficient air can be supplied to the filter. This configuration is particularly effective when the inlet of the front panel is clogged.

In addition, an engaging projection that engages with a panel receiver protruding from the air cleaner body and supports the weight of the panel is formed on the upper portion of the front panel, and a movable engagement member that engages with the air cleaner body. Since the piece is located at the bottom of the front panel or the movable engagement piece that engages with the bottom of the front panel is located at the air purifier, screws are not required for mounting the front panel, it is easy to attach and detach, and the filter can be cleaned and replaced. It will be easier.

Further, a separate base for supporting the air purifier main body is provided. The base and the air purifier main body are provided with an engaging portion which is engaged by sliding the two together, and a slide in the opposite direction. Since the engagement means for keeping the engagement of the engagement portion by blocking is provided, the air cleaner body and the base for stably supporting the air cleaner body on the floor can be easily and reliably assembled. be able to.

Further, a viewing window through which the ion generator can be viewed is provided in the air cleaner body, and a circuit board disposed inside the air cleaner body is provided with a light emitting device for illuminating the ion generator in conjunction with driving of the ion generator. I put on my body,
The driving state of the ion generator can be easily visually recognized, and the luminous body for achieving this can be easily arranged.

Further, since a reflection cover for reflecting the light emitted from the illuminant in the direction of the ion generator is provided, the light emitted from the illuminant is collected by the ion generator, and the efficiency of the ion generator is reduced even if the luminance of the illuminant is small. Can be illuminated well. Since the light from the light emitter does not directly irradiate the viewing window, the user is not dazzled and the visibility can be improved.

[Brief description of the drawings]

FIG. 1 is a front perspective view of an air purifier according to an embodiment of the present invention.

FIG. 2 is a rear perspective view of the same.

FIG. 3 is a partial sectional top view of the same.

FIG. 4 is a schematic diagram illustrating the flow of air inside the air purifier.

FIG. 5 is an exploded perspective view showing an arrangement state of a front panel and each filter in the air purifier.

FIG. 6 is an exploded perspective view showing a structure and a mounting method of a prefilter in the air purifier.

FIG. 7 is a front perspective view similar to FIG. 1, with a front panel and a filter unit removed.

FIG. 8 is a vertical sectional view of the air purifier.

FIG. 9 is a perspective view showing an embodiment of a wind direction setting unit.

FIG. 10 is a sectional view of an ion generator.

FIG. 11 is a partial horizontal sectional view of an ion generator arrangement portion.

FIG. 12 is a partial cross-sectional view of a mounting portion of the ion generator.

FIG. 13 is an exploded perspective view showing an installation state of the ion generator.

FIG. 14 is a perspective view of a panel receiver that supports the front panel.

FIG. 15 is a perspective view of a hook portion used for attaching a front panel.

FIG. 16 is a partial rear view of the front panel showing a state of formation of the engaging projection;

17 is a view in the direction of arrow A in FIG.

FIG. 18 is a partial rear view of the front panel showing the state of attachment of the movable engagement piece.

19 is a sectional view taken along line BB of FIG.

FIG. 20 is a perspective view of a movable engagement piece and a slide guide.

FIG. 21 is a partial vertical sectional view showing a front panel mounting state.

FIG. 22 is a partial horizontal sectional view showing a front panel mounting state.

FIG. 23 is a partial cross-sectional partial side view showing a process of assembling the air cleaner body and the base.

FIG. 24 is a partial cross-sectional partial side view showing a combined state of the air purifier main body and the base.

FIG. 25 is a front view of an operation panel unit.

FIG. 26 is a front view of a remote controller.

FIG. 27 is a diagram showing data on removal of airborne bacteria in air.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Air purifier 10 Main body 11 Base 11b Engagement part 12 Front panel 13 Suction port 14 Side suction port 15 Main outlet 16 Sub-outlet 19 Front cover 20 Filter unit 21 Pre-filter 22 Deodorizing filter 23 Dust collecting filter 30 Blower 31 Fan REFERENCE SIGNS LIST 32 motor 40 ion generator 41 glass tube (dielectric) 42 high-voltage electrode 43 ground electrode 44 cap 45 cap 50 ozone suppressor 55 main passage 56 bypass passage 57 branching section 58 damper (air flow control means) 60 light emitting section 61 circuit board 63 Reflection cover 70 Viewing window 71 Front shell 75 Rear shell 75a Engagement part 80 Operation panel 90 Panel receiver 92 Engagement protrusion 100 Movable engagement piece 110 Hook part 120 Engagement means 130 Wind direction setting means

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Mitsunori Sekoguchi 22-22, Nagaike-cho, Abeno-ku, Osaka-shi, Osaka Inside (72) Inventor Mamoru Morikawa 22-22, Nagaike-cho, Abeno-ku, Osaka-shi, Osaka Co., Ltd. F term (reference) 4C080 AA07 BB02 BB04 BB05 CC01 HH02 JJ03 KK02 MM08 QQ17

Claims (10)

[Claims] 1. A blower that circulates indoor air, a filter that removes dust in sucked air, and a positive ion and a negative ion generated simultaneously by applying an AC voltage between electrodes facing each other with a dielectric interposed therebetween. In an air purifier provided with an ion generating device, a part of the air that has passed through the filter is supplied to the ion generating device, and air containing ions generated by the ion generating device is combined with the air that has passed through the filter. An air purifier characterized by circulation. 2. An air purifier, wherein the air containing ions generated by the ion generator and the air passing through the filter are combined outside the air purifier body. 3. A wind direction setting means is provided at an air outlet of the air passing through the ion generator.
An air purifier according to item 1. 4. A dielectric material of the ion generator is formed in a cylindrical shape, and caps made of an elastic material are mounted on both ends thereof, and one of the caps is fitted to the air purifier main body from a direction perpendicular to the axial direction of the dielectric material. The ion generating device is fixed in the air cleaner body by contacting the other cap with the air cleaner body so that a pressing force from the axial direction is generated on the dielectric. 1 or Claim 2
An air purifier according to item 1. 5. A filter housing is provided at the center of the front of the air purifier main body, and a front panel having a size larger than the filter housing is provided at a predetermined distance from the air purifier main body on the front of the filter housing. The air purifier according to any one of claims 1 to 3, wherein the air purifier is mounted. 6. A space between the front panel and the air purifier main body is used as a suction port for room air, and a suction port is also provided in the front panel itself, so that the former suction port area is larger than the latter suction port area. The air purifier according to claim 4, wherein: 7. An engaging projection for engaging a panel receiver projecting from the air purifier main body and supporting the weight of the panel at an upper portion of the front panel, and a movable engagement engaging with the air purifier main body. The air cleaner according to claim 4 or 5, wherein the piece is disposed at a lower portion of the front panel, or a movable engagement piece that engages with the lower portion of the front panel is disposed at a lower portion of the air cleaner body. 8. A separate base for supporting the air purifier main body is provided. The base and the air purifier main body are provided with an engaging portion which is engaged by sliding the two together, and a slide in the opposite direction. The air purifier according to any one of claims 1 to 6, further comprising an engagement means for keeping the engagement of the engagement portion by preventing the engagement. 9. A light-emitting window for illuminating the ion generator in conjunction with driving of the ion generator, wherein a viewing window through which the ion generator can be viewed is provided in the air cleaner body, and a circuit board disposed inside the air cleaner body is driven. The air purifier according to any one of claims 1 to 7, wherein the air purifier is mounted on a body. 10. The air purifier according to claim 8, further comprising a reflection cover for reflecting light emitted from the light emitter toward the ion generator.