JP2002095725A - Photocatalytic filter and air cleaner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a photocatalytic filter and air cleaner that contributes to the reduction of abnormal sounds caused by the collision of particles having photocatalytic substances. SOLUTION: The photocatalytic filter is provided with an accommodating chamber 4t, flame bodies 41, 46 having air ducts 41x, 46x, many particles having photocatalytic substances packed in the accommodating chamber 4t, fishnet members 42, 43 having many ventilative fishnet openings 42f, 43f smaller than the size of particles 40 residing in the air ducts 41x, 46x, which control the looseness of particles 40 as the fishnet members 42, 43, compress the packed-in particles 40. This photocatalyic filer can be used as an air cleaner as well.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a photocatalyst filter having a photocatalyst substance and an air purifier provided with the photocatalyst filter.

[0002]

2. Description of the Related Art A photocatalytic substance is activated by irradiation of light and has a function of decomposing and removing an organic substance or the like over time. Titanium oxide (TiO2) or the like is typical. Such photocatalytic substances are being used for decomposing and removing pollutants such as odor substances. Particles are provided as such a photocatalyst substance. In the industry, attempts have been made to use a photocatalytic filter formed by using a large number of particles having a photocatalytic substance and packing the particles in a frame (Japanese Patent Application Laid-Open No. 09-38487). According to this, the air to be purified can pass between the particles, so that the contact between the particles having the photocatalytic substance and the air is ensured, and the air can be purified well.

[0003]

However, in a photocatalytic filter in which a large number of particles having a photocatalytic substance are packed in a frame, a large number of particles having a photocatalytic substance rattle depending on the use environment. There is a problem that a collision may occur or particles may collide with a wall surface of the frame, causing abnormal noise and giving a sense of strangeness to a person. In particular, when used in an environment where vibration frequently acts, such as a vehicle,
Abnormal noise caused by the collision described above becomes remarkable.

The present invention has been made in view of the above circumstances, and has as its object to provide a photocatalyst filter and an air purifier that can contribute to reducing abnormal noise caused by the collision of particles having a photocatalytic substance. I do.

[0005]

A photocatalyst filter according to the present invention comprises a frame having a storage chamber and a ventilation window communicating with the storage chamber, and a large number of particles having a photocatalytic substance packed in the storage chamber of the frame. A mesh member attached to the ventilation window of the frame body and having a large number of mesh openings capable of passing air of a size smaller than the particles, and the mesh member is pressed against the packed particles to suppress rattling of the particles. It is characterized by doing.

An air purifier according to the present invention comprises an air inlet and an air outlet, an air flow path connecting them, a fan for forming an air flow flowing from the air inlet to the air outlet through the air flow path, and an air flow path. An air purifier having a purifying unit disposed in the air purifier for purifying an air flow flowing through the air flow path, wherein the purifying unit comprises:
To a photocatalyst filter according to claim 3.

[0007]

DESCRIPTION OF THE PREFERRED EMBODIMENTS According to the photocatalyst filter according to the present invention, since the mesh member attached to the ventilation window of the frame constituting the photocatalyst filter has flexibility in its nature, particles are stored in the accommodation chamber. It can be bent and deformed in the packing direction at high density. By utilizing the bending deformation of the mesh member in this manner, particles can be packed into the storage chamber at a high density, and the mesh member is directly or indirectly pressed against the packed particles to suppress rattling of the particles. Is done. Therefore, abnormal noise caused by rattling of the particles is also suppressed.

Further, ventilation is ensured by the mesh openings of the mesh member, and the contact between the particles having the photocatalytic substance in the photocatalytic filter and the air to be purified is ensured. Furthermore, since the mesh openings of the mesh member are smaller in size than the particles, the particles packed in the storage chamber are prevented from falling off the mesh member. The mesh member has a large number of mesh openings, and may be formed by weaving a wire or may be punched out of a large number of punching holes in some cases. When knitting a wire, a wire knitted vertically and horizontally may be used, or a wire may be extended only vertically or horizontally. The material of the wire constituting the mesh member is not particularly limited, and may be a metal such as carbon steel, stainless steel, an aluminum alloy, or titanium, or may be a resin, but while reducing the wire diameter of the wire to improve ventilation. Metal is preferable to secure the strength of the wire. The shape of the mesh opening of the mesh member is not particularly limited,
It may be square or circular. According to a preferred embodiment of the photocatalytic filter, the elastic member that comes into contact with the particles can be packed together with the particles into the frame. In this case, since the elastic member is packed in the storage chamber together with the particles, rattling of the particles packed in the storage chamber is further suppressed. The shape of the elastic member can be, for example, a sheet shape, a net shape, or a particle shape. When the elastic member has a large surface area, it is preferable that the elastic member can ventilate. In order to ensure ventilation, the elastic member can be made porous, for example, a mesh-shaped, porous layer having a large number of fine openings through which air can pass. The size of the opening is preferably smaller than the size of the particles in consideration of preventing the particles from falling off. The shape of the opening is not particularly limited, and may be square or circular. The elastic member can be formed using a soft polymer material such as resin or rubber. -Photocatalytic substances are effective for removing odor substances typified by tobacco, TiO ₂ , WO ₃ , CdS, SrTiO
_3. Known materials such as MoS ₂ can be used. Considering the ease of handling and the degree of activity, it is desirable to use TiO ₂ . As the crystal structure of TiO ₂ , any of rutile type and anatase type can be used, but an anatase type having a large catalytic activity is generally preferable. -The shape of the particles having a photocatalytic substance is not particularly limited,
Examples include a spherical shape, an elliptical spherical shape, a columnar shape, and a prismatic shape. The particles may be formed by the photocatalytic substance itself, or may be formed by supporting the photocatalytic substance on a particulate carrier with a binder. Examples of the carrier include silica gel particles and activated carbon, but are not limited thereto. The size of the particles having a photocatalytic substance varies depending on the application, and the upper limit is 30 mm, 20 mm,
0 mm, 5 mm, etc. can be exemplified, and the lower limit is 0.1 m
m, 0.5 mm, 1 mm, 3 mm, etc., but are not limited thereto. According to the air cleaner of the present invention, when the fan is driven, the air sucked from the air inlet flows through the air flow path to the air outlet, and is blown out from the air outlet. The contaminants contained in the air flow flowing through the air flow path adhere to the particles having the photocatalytic substance of the photocatalytic filter constituting the purifying section,
The air is purified. Since the air purifier according to the present invention is also provided with the photocatalyst filter having the above-described structure, the particles having the photocatalyst substance are obtained by utilizing the bending deformation of the mesh member attached to the frame of the photocatalyst filter. Can be packed in the accommodation chamber at a high density, the rattling of the particles is suppressed, and the noise caused by the rattling of the particles is also suppressed. Further, since the mesh member has mesh openings smaller in size than the particles, even if the particles are packed into the accommodation room at a high density, the particles packed in the accommodation room are prevented from falling off from the mesh member. According to a preferred embodiment of the air purifier according to the present invention, the air purifier has a grill provided on at least one of the air inlet and the air outlet, and at least one of the photocatalyst filter and the grill described above has a photocatalyst filter whose front and back are reversed. At one time, it is possible to have an attachment preventing portion for preventing the attachment of the photocatalytic filter to the grill. Thus, the photocatalyst filter can be prevented from being attached to the grill upside down, and the ability of the photocatalyst filter can be used normally. -According to the air purifier which concerns on this invention, you may provide separately the filter for dust capture other than a photocatalyst filter. In this case, the photocatalyst filter may be arranged on the downstream side or the upstream side of the dust trapping filter. However, since the dust trapping filter can capture large particles, consideration is given to improving the performance of the photocatalyst filter, and the like. In this case, the photocatalyst filter is preferably disposed downstream of the dust trapping filter. -According to the air purifier according to the present invention, it is possible to provide an excitation unit that excites the photocatalytic substance. As the excitation means, a light emitting diode, a black light, a cold cathode tube or the like can be adopted. A light emitting diode that emits light of a short wavelength can be employed as the light emitting diode.
The wavelength can be set to 00 nm, but is not limited to this wavelength range. A gallium nitride (GaN) -based light emitting diode can be used, but is not limited thereto. A light emitting diode is a small element, and generally does not require much space for installation, which is advantageous for downsizing.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which the present invention is applied to an air purifier having a photocatalytic filter will be described below with reference to the drawings. The air purifier according to the present embodiment is mounted on the ceiling side in the room of a vehicle such as an automobile, and as shown in FIG. 1, a main body 1 which is an air purifier main body has a thin shape, that is, a flat type. An air flow path 1c having a fan chamber 1a and a filter chamber 1b, and a fan 2 disposed in the fan chamber 1a.
And a filter 3 for dust capture arranged in the filter chamber 1b, and a resin intake grille 51 as a decorative plate detachably mounted on the lower surface side of the main body 1. As shown in FIG. 1, the main body 1 has an intake port 10 t
And a box-shaped body 12 formed by integrally connecting a front plate 10 having a front surface and a rear plate 11 on the vehicle body side. FIG.
, The intake grill 51 covers more than half of the lower surface of the body 12 of the main body 1 and forms a number of grill intake ports 52. On the downstream side of the intake grille 51, an air outlet 53 also serving as a filter inlet / outlet is formed. As shown in FIG. 2, the outlet 53 is opened downward with respect to a center line P of the filter chamber 1b along the air flow. The reason is that the air purifier of the present embodiment is mounted on the ceiling side of the room R, so that the purified air is blown out from the air outlet 53 toward the room R below. As shown in FIG.
The normal 53m of the outlet 53 is inclined in a direction away from the filter chamber 1b as it moves downward. Outlet 5
In addition to the function of blowing out the purified airflow toward the room R, the filter 3 can also function as a filter entrance for taking the filter 3 in and out as described later. The outlet grill 54 is made of resin, faces the interior R, and has a number of grill outlets 55. The size of the outlet grill 54 is the intake grill 5
Less than one. Grill outlet 55 communicates with filter room 1b and room R.

[0010] As shown in FIG.
c, from the upstream side to the downstream side,
A fan 2 facing t, a filter 3 for mainly capturing dust and the like, and a photocatalytic filter 4 for mainly removing odors such as tobacco are arranged in this order. The fan 2 is a centrifugal fan (for example, a multi-blade radial fan), and includes a plurality of rotating blades 20 and a driving unit 21 that drives the rotating blades 20.

As shown in FIG. 1, in the filter chamber 1b of the back plate 11 constituting the main body 1, as shown in FIG.
The concave portion 15 is formed by retracting the wall portion 11w of the back plate 11 in the direction in which the volume of b increases. The recess 15 is arranged on the upper side of the filter chamber 1b,
As will be understood from the description below, the filter 3 can function as a turning promotion space for turning the filter 3. As can be understood from FIG. 2, the wall portion 11w forming the concave portion 15 of the back plate 11 extends along the center line P of the filter chamber 1b in a direction along the air flow. As can be understood from FIG. 2, the recess 15 is provided on the opposite side to the outlet 53 which is also the filter inlet / outlet through the center line P of the filter chamber 1b. As shown in FIG. 2, the depth H <b> 1 of the recess 15 is set to be significantly smaller than the height HA of the filter 3. In addition, the concave length L1 of the concave portion 15 is slightly smaller than the length LA of the filter 3. A first guide portion 17 is formed at the upstream end of the filter chamber 1b in the recessed portion 15 and has a slope gradually lowering toward the upstream (filter chamber 1b). At the downstream end of the filter chamber 1b, as it goes downstream,
A second guide 18 having an inclination toward b) is formed.

The filter 3 is removably accommodated in the filter chamber 1b and is a dust collecting filter mainly for collecting dust for dust collection, and has air permeability and flexibility as shown in FIG. It is formed by pleating a thin filter material in a pleated shape so as to alternately form peaks 3m and valleys 3n, and has a substantially rectangular box shape (length L).
A, height HA, width DA, see FIGS. 2 and 3), and as shown in FIG. 2, has an upper surface 3u, a lower surface 3d, and a side surface 3e. The filter material constituting the filter 3 has a laminated structure in which a layer mainly composed of activated carbon and a layer subjected to a charge treatment are laminated, thereby improving the dust capturing property. As shown in FIG. 2, the end face 3fo of the upstream end 3f of the filter 3 is connected to the filter upstream engagement portion 19 of the back plate 11 of the main body 1.
This seals the air flowing through the air flow path 1c so as not to enter the recess 15 and positions the filter 3 in the insertion direction. As shown in FIG.
In the width direction (arrow E direction), and seals the entire width or almost the entire width of the end face 3fo of the upstream end 3f of the filter 3.

As shown in FIG. 2, the downstream end 3 of the filter 3
The end face 3ro of r is slightly engaged with the filter downstream engagement portion 1x held on the back plate 11 of the main body 1, thereby also positioning the filter 3 in the insertion direction and preventing the filter 3 from rattling. Is going. In addition, as shown in FIG.
Inclined guide surface 1y which is the lower surface of filter downstream engagement portion 1x
Is inclined downward toward the outlet grill 54 as it moves to the downstream side, and has a function of facilitating the tilting operation of the filter 3 to be taken in and out.

Further, a cushion member 31 for improving the sealing performance and further suppressing the rattling of the filter 3 is integrally held at the downstream end 3r of the filter 3. That is, as shown in FIG. 2, the cushioning material 31 of the upper surface 3u of the filter 3 comes into contact with the downstream end of the concave portion 15, so that the sealing property of the upper surface 3u of the filter 3 is maintained well,
The rattling of the filter 3 is further prevented. As shown in FIG. 2, when the blowout grill 54 is closed,
The pushing convex portion 57 of the blowing grill 54 is located on the lower surface 3 of the filter 3.
d, the filter 3
The sealing property of the lower surface 3d of the filter 3 is maintained well, and the play of the filter 3 is further suppressed.

As described above, the filter 3 is a filter chamber 1
b, the air flowing through the air flow path 1c is suppressed from passing through the recessed portion 15,
It passes through the filter 3 reliably. Filter 3
A tab 33 that can function as a filter pulling member is integrally provided above the downstream end 3r. When the tab 33 is pulled with a fingertip or the like, the filter 3 in the filter chamber 1b can be pulled out to the outlet 53 side.

The air purifier according to the present embodiment is attached to the ceiling of the vehicle using a claw member 90 provided at the rear end side, a fixture inserted through the insertion hole 14 of the main fixing portion 13, and the like. . Since the main body 1, the excitation means 49, and the photocatalytic filter 4 are thin, it can contribute to making the air purifier thin. Such a thin air purifier can be used in a ceiling room 2 even in a small room R.
It is arranged without feeling uncomfortable along with 00, which is advantageous for ensuring a wide interior R of the vehicle body. The ceiling wall 200 is the inner layer 200
And an outer layer 201.

Now, the configuration near the photocatalyst filter 4, which is the main part, will be described. In this embodiment, FIG.
As shown in the figure, the photocatalyst filter 4 is detachably held on the back surface 54r side of the blowout grill 54. Therefore, when the outlet grill 54 is removed from the outlet 53 of the intake grill 51 attached to the main body 1, the photocatalytic filter 4 is also automatically removed from the main body 1. The photocatalytic filter 4 is a deodorizing filter mainly for the purpose of deodorizing,
On the downstream side of the filter 3, the lower surface 4d is
4 and an upper surface 4 u is provided so as to face the excitation means 49. As shown in FIG. 8, the photocatalyst filter 4 includes a first frame 41 and a second frame 4 which are detachably attached to each other so as to form a storage chamber 4t.
6. In the photocatalyst filter 4, a large number of photocatalyst particles 40 are packed in the accommodation chamber 4t at a high density so as not to rattle. The gap between the adjacent photocatalyst particles 40 becomes an air passage. As shown in FIG. 8, the flat type photocatalyst filter 4 has a large number of photocatalyst particles 40 arranged side by side in the surface direction of the photocatalyst filter 4 in order to enhance the catalytic performance. The number of photocatalyst particles 40 arranged side by side in the thickness direction of No. 4 is reduced. In the photocatalyst filter 4 described above, as shown in FIG. 8, a ventilation window 41x for air transmission is formed in substantially the entire upper surface 4u of the first frame 41. Second frame 46
A ventilation window 46x for air permeation is formed in the entire area of the lower surface 4d.

The photocatalyst particles 40 are microspheres (diameter: for example, 2
-6 mm), and titanium oxide (Ti
O ₂ ) is the main component. The diameter of each photocatalyst particle 40 is substantially the same. As shown in FIG. 8, on the side of the photocatalytic filter 4 facing the excitation unit 49, a metal mesh member 42 having many mesh openings 42 f is provided with a first frame 41.
And the inner surface 4 of the first frame 41.
It is applied to 1v and is prevented from coming off. As shown in FIG. 8, on the side opposite to the excitation means 49, a polymer-based elastic member 44 having a large number of mesh openings 44f and a metal-based mesh member 43 having a large number of mesh openings 43f are provided with a photocatalyst. It is attached to the lower side of the particles 40 so as to face the ventilation window 46 x of the second frame 46. As shown in FIG. 8, the elastic member 44 and the mesh member 43 are provided on the inner surface 46 v of the second frame 46.
Has been detained. Here the excitation means 4
9, that is, along the direction of the arrow K1 shown in FIG.
2. Photocatalyst particles 40, a polymer material-based elastic member 44, and a metal-based mesh member 43 are arranged in this order. As shown in FIG. 9, the metal mesh members 42 and 43 are formed by weaving metal thin wires 42a and 43a in a net shape. As shown in FIG. 10, the polymer material-based small-diameter elastic member 44 is formed by weaving a wire 44a in which a soft layer 44c made of urethane or the like is coated on a core material 44b made of nylon or the like in a net shape, so that photocatalyst particles are formed. Excellent protection against 40. As can be understood from FIGS. 9 and 10, the mesh diameter Z of the mesh openings 42f and 43f of the metal mesh members 42 and 43.
A, the mesh diameter ZB of the mesh openings 44f of the polymer material-based elastic member 44 is substantially the same, and each is set to be smaller than the outer diameter ZE of the particulate photocatalyst particles 40. Therefore, the particulate photocatalyst particles 4 packed in the accommodation chamber 4t
0 is prevented from dropping from the mesh openings 42f, 43f of the mesh members 42, 43 of the photocatalytic filter 4 and the mesh opening 44f of the elastic member 44. In such a photocatalyst filter 4, the microspherical photocatalyst particles 40 can be packed at a high density into the storage chamber 4t of the photocatalyst filter 4 while preventing the microspherical photocatalyst particles 40 from falling off. 40 is not rattled, and the air permeability is also ensured.

FIG. 14 is a plan view of the photocatalytic filter 4. FIG. 15 shows a side view of the photocatalytic filter 4. FIG.
As shown in FIG. 3, the photocatalyst filter 4 is formed in a thin, flat, rectangular box shape having a small thickness in the ventilation direction so as to reduce ventilation resistance.
Are formed with a large number of side ventilation windows 4k. The ventilation property is further enhanced by the side ventilation window 4k, and the purification performance of the photocatalytic filter 4 can be further improved. The engaging claw 41w formed on the first frame 41 of the photocatalytic filter 4 is attached to the second frame 46.
To the first frame 41 and the second frame 46.
Are detachably connected. As shown in FIG. 14, a cross-shaped arm portion 41r is provided on a ventilation window 41x formed on the upper surface 4u of the first frame 41. Arm 41r
Is the first frame 41 while securing the opening area of the ventilation window 41x.
, And can function as an excessive deflection suppressing portion that suppresses excessive bending of the mesh member 42. Although not shown, an arm that can prevent the mesh member 43 from coming off is also provided on the ventilation window 46x of the second frame 46 in a similar manner.

The excitation means 49 shown in FIG. 8 excites the photocatalyst particles 40 in the photocatalyst filter 4, and is held above the photocatalyst filter 4 so as to face the upper surface 4u of the photocatalyst filter 4. The excitation means 49 is formed by arranging a large number of light emitting diodes 49m side by side, and has a thin shape, that is, a flat type along the flat type photocatalytic filter 4 as a whole. The light emitting diode 49m is a gallium nitride based optical semiconductor (emission wavelength peak 370 to 400 nm).
), And emits short-wavelength light to the photocatalyst particles 40.
And is exposed to the air flow path 1c.
When the light from the light emitting diode 49m is irradiated, the photocatalyst particles 40 are excited and activated, and the action of decomposing substances such as odor substances attached to the photocatalyst particles 40 is enhanced.
As shown in FIGS. 1 and 2, since the excitation unit 49 is disposed downstream of the filter 3 for removing dust, dust contained in the airflow is suppressed from adhering to the light emitting diode 49m, This is advantageous for securing the light amount of the light emitting diode 49m for a long time, and is also advantageous for securing the purifying ability of the photocatalyst particles 40 activated by the light emitted from the light emitting diode 49m.

The above-described photocatalytic filter 4 is connected to the blowout grill 5
The structure to be attached to No. 4 will be described. As shown in FIG. 11, the filter engaging portion 4
p is protruded plurally. When the photocatalyst filter 4 is moved in the direction of the arrow UA and pressed against the outlet grill 54, the filter engaging portion 4p of the photocatalyst filter 4
The photocatalyst filter 4 is detachably attached to the outlet grill 54. When the front and back of the photocatalyst filter 4 are reversed, the projection 4s of the photocatalyst filter 4 is
Therefore, the photocatalyst filter 4 cannot be attached to the outlet grill 54. Therefore, the photocatalyst filter 4 is attached to the outlet grill 54 so that the elastic member 44 covered with the polymer material layer is always on the lower surface side of the photocatalyst filter 4. Therefore, the protrusions 4s and 54s can function as an attachment preventing portion for preventing the photocatalyst filter 4 from being attached upside down. Therefore, the light emitted from the light emitting diode 49m is prevented from being blocked by the elastic member 44.
Therefore, it is advantageous for activating the photocatalyst particles 40 by the light emitted from the light emitting diode 49m, and is advantageous for securing the performance of the photocatalyst filter 4. The elastic member 44
Is always arranged on the side away from the light emitting diode 49m, so that deterioration of the elastic member 44 due to light irradiation can be suppressed.

As shown in FIG. 13, an insert such as a tool or a coin is inserted into a gap 54po between the filter engaging portion 4p and the filter engaged portion 54p, that is, outside the arrow SC.
When urged in the direction, the wall portion 54w of the blowout grill 54 having the filter engagement portion 54p is elastically deformed in the same direction, so that the filter engagement portion 4p of the photocatalytic filter 4 and the filter engagement portion of the blowout grill 54 54p is disengaged,
The photocatalyst filter 4 is removed from the outlet grill 54.
The frequency of removing the photocatalytic filter 4 is lower than the frequency of removing the filter 4 for capturing dust.

Next, a case where an air purifier is used will be described. In the state shown in FIG. 1, the fan 2 is rotated, and at the same time, the light emitting diode 49m of the excitation means 49 emits light to activate the photocatalyst particles 40. By the rotation of the fan 2, the air in the cabin R of the vehicle is sucked from the intake port 10 t through the grill intake port 52 of the intake grill 51, and the air flow flows through the air flow path 1 c and passes through the filter 3 and the photocatalyst particles 40 in order. Purified through. The purified air is blown into the room R from the grill outlet 55 of the outlet grill 54 via the outlet 53. By continuing such an operation, the room R is gradually purified. Generally, relatively large particles such as dust in the air are captured by the filter 3, and extremely small particles such as odorous particles contained in the air are adsorbed by the photocatalyst particles 40. . Organic substances and the like attached to the photocatalyst particles 40 are gradually decomposed and removed. Therefore, both the filter 3 and the photocatalytic filter 4 can function as a purifying unit for purifying the air flow.

When the air purifier has been used for a long time, the outlet grill 54 may be removed from the outlet 53 of the main body 1. This is a case where the filter 3 or the photocatalyst filter 4 is replaced. In this case, if the blowout grill 54 is accidentally dropped from the main body 1, the blowout grill 54 is damaged. Therefore, the present embodiment employs the following configuration. That is, as shown in FIGS. 6 and 7, one end of the blowout grill 54 has a rotating arm 56 having a protruding engagement head 56v at its tip.
Are protruding. A first engagement portion 1m and a second engagement portion 51 which are close to and opposed to each other via a space 51na are provided on the downstream side of the intake grille 51 constituting a part of the main body 1.
s is provided. As shown in FIGS. 6 and 7, the first engagement portion 1m and the second engagement portion 51s are opened in the direction in which the blowout grill 54 rotates to open and close the blowout opening 53 (arrow B1 and B2 directions). Direction side (front side of intake grill 51)
The second engaging portion 51s is disposed on the front side, and the first engaging portion 1m is disposed on the closing direction side (the back side of the intake grill 51).
Further, as shown in FIG. 7, the engagement end face 1 of the first engagement portion 1m is provided.
The mo and the engagement end surface 51so of the second engagement portion 51s are opposed to each other in the direction of the arrow KX, which is the direction in which the blowout grill 54 extends, and are set to be shifted by Δmk. Therefore, the engagement end surface 51so of the second engagement portion 51s is indicated by the arrow KX.
In the direction, the first engagement portion 1m is disposed closer to the outlet grill 54 than the engagement end surface 1mo.

As shown in FIG. 7, when the rotation angle of the blow grill 54 with respect to the main body 1 is small, the blow grill 54
Can be inserted into and removed from the space 51na between the first engaging portion 1m and the second engaging portion 51s along the directions of arrows S1 and S2. As shown in FIG. 6, when the rotation angle of the blowout grill 54 with respect to the main body 1 is large, the rotation arm 56 of the blowout grill 54 is connected to the engagement end face 5 of the second engagement portion 51s.
1so, and the rotating arm 5 of the blowout grill 54
6, the portion of the back surface 56r of the surface 56f engaged with the second engagement portion 51s is engaged with the first engagement portion 1m. In this state, as can be understood from FIG. 6, the turning arm 56 of the blowout grill 54 is in the turned position, and the first engagement portion 1m and the second
It is engaged with the engaging portion 51s by a two-point support structure. Therefore, the blow-off grill 54 in the rotated state is not temporarily dropped, but is temporarily held in the main body 1 in the rotated state. That is, in FIG. 6, a clockwise moment Mc shown in FIG. 6 acts on the blowout grill 54 by the weight of the blowout grille 54, and the blowout grille 54 rotates clockwise around the rotation arm 56 as a rotation center area. I will do it. But,
The first engagement portion 1m functioning as a stopper is formed by the blowout grill 5
4, the rotation of the blowout grill 54 is stopped at the rotation position. As a result, the blowout grill 54 is temporarily held so as not to fall naturally while being rotated.

It is to be noted that the blowing grill 54 having a certain weight is more effective than the case where the blowing grill 54 is too light.
4 is considered to be strongly engaged with the first locking portion 1m, the posture of the temporary holding of the blowout grill 54 is stabilized. In this regard, in the present embodiment, since the blowout grill 54 is integrally provided with the photocatalyst filter 4 containing the photocatalyst particles 40 in the form of fine particles, it has a certain weight and can stabilize the posture of the temporary holding. .

In addition, in this embodiment, as shown in FIGS. 6 and 7, an engaging head 56v is provided at the tip of the rotating arm 56, and the engaging head 56v is first locked. Since the engaging portion 1m is engaged with the rotating portion 56, the rotation arm portion 56 and the first locking portion 1m can be further prevented from coming off.
Can be further improved. When replacing the photocatalyst filter 4, as shown in FIG. 2, a grill engagement claw 54x as a grill engagement portion on the other end side of the blowout grill 54 is provided. Intake grill 51
The insert SA such as a tool, a coin, or a fingertip is inserted into the gap 51n between the grille engaging claw 51x and the rotary engagement operation. As a result, at least one of the grill engagement claws 54x and 51x is elastically deformed appropriately, and the engagement between the grill engagement claw 54x and the grill engagement claw 51x is released. Then, as shown in FIG. 4, the blowout grill 54 to which the photocatalyst filter 4 is integrally attached is lowered while rotating by its own weight in the direction of arrow B1 with the vicinity of the rotating arm 56 as the center of rotation. I do. In this state, as can be understood from the above, the rotating arm portion 56 of the outlet grill 54 is engaged with the first engaging portion 1m and the second engaging portion 51s, and as a result, the rotating outlet grill 5
4 is temporarily held by the main body 1 without falling naturally. Thereafter, as shown in FIG.
By lifting a small amount in two directions (closing direction) and reducing the rotation angle of the blow grill 54 with respect to the main body 1, the blow grill 5
4 and a first engaging portion 1m and a second engaging portion 56s.
Is naturally released. As a result, the rotating arm 56
Can be inserted into and removed from the space 51na between the first engaging portion 1m and the second engaging portion 51s. If the outlet grill 54 is moved in the direction of arrow B3 (see FIGS. 7 and 4) in such a state that it can be inserted and removed, the outlet grill 54 can be easily removed from the intake grill 51 of the main body 1 side. , The outlet 53 can be opened. The operations described above are
It suffices to simply lift the blow-off grill 54 that has been temporarily held downward and slightly remove the rotating arm 56 from the space 51na, and the operator can easily perform the operation with one hand.

After the outlet grille 54 is removed from the intake grille 51 as described above, the photocatalytic filter 4 is removed from the outlet grille 54 and replaced with a new one. Then, a new photocatalyst filter 4 is attached to the outlet grill 54,
Thereafter, as described above, the turning arm 56 of the blow grill 54 is
Space 51n between first engagement portion 1m and second engagement portion 56s
a, and the outlet grill 54 is pivoted upward in the direction of arrow B2 to detachably attach the outlet grill 54 to the intake grill 51.

A mode for attaching the filter 3 to the air purifier will be described. In this case, the filter 3 is pushed and moved along the air flow path 1c from the downstream side to the upstream side. That is, as can be understood from FIG. 5, the blow-out grill 54 is separated from the blow-out port 53 of the intake grille 51 of the main body 1 and the blow-out port 53 which is also the filter inlet / outlet is opened. As shown in FIG. 5, the filter 3 is inclined obliquely so that the upstream end 3f is on the upper side and the downstream end 3r is on the lower side. The filter 3 in that state is connected to the upstream end 3f.
From the outlet 53 of the intake grill 51 toward the filter chamber 1b along the direction of arrow D4 (see FIG. 5). At this time, the vicinity of the upstream end 3f of the filter 3 can be favorably guided by the inclined guide surface 1y of the filter downstream engaging portion 1x and the inclined guide action of the second guide portion 18 of the recessed portion 15. Then, the upper part of the upstream end 3f of the filter 3 is
5 while the filter 3 is a flat filter chamber 1
The filter 3 is swung while being pushed in so as to be gradually horizontal along the line b. The recess 15 is the filter chamber 1
Since the filter 3 is formed so as to face the filter b, the turning operation for turning the filter 3 inclined obliquely substantially horizontally becomes easy.
In particular, in this embodiment, if the upstream end 3f of the filter 3 hits the first guide portion 17, the upstream end 3f of the filter 3 can be guided downward by the inclined guide action of the first guide portion 17, The turning operation for turning the filter 3 sideways (almost horizontal state) is further facilitated.

After the filter 3 has been installed in the filter chamber 1b as described above, the outlet grill 54 is attached to the outlet 53 of the intake grill 51 in the same manner as described above.

The case where the filter 3 is removed from the filter chamber 1b of the main body 1 will be described. In this case, basically, the reverse operation to the case where the filter 3 is mounted in the filter chamber 1b may be performed, and the filter 3 in the filter chamber 1b may be used.
From the upstream side to the downstream side of the air flow path 1c. That is, first, the outlet grill 54 is removed from the intake grill 51 of the main body 1 and the outlet 53 which is also the filter inlet and outlet.
Release. Then, as can be understood from FIG. 5, while pulling the tab 33 connected to the upper part of the downstream end 3r of the filter 3 in the direction of arrow D5 toward the outlet 53,
The filter 3 is pulled out of the filter chamber 1b. At this time, the filter 3 is further pulled out while turning so that the lower end 3r of the filter 3 is inclined downward so that the upper part of the upstream end 3f of the filter 3 enters the recess 15. After being pulled out, the filter 3 is cleaned or replaced. Then, the cleaned or replaced filter 3 is placed in the filter chamber 1b as described above.
And the intake grille 5 fixed to the body 1
The outlet grille 54 is attached to the first outlet 53.

As described above, in this embodiment,
As shown in FIG. 8, the frame 4 constituting the photocatalytic filter 4
The net-like members 42, 43 attached to the ventilation windows 41x, 46x of 1, 46 are formed by weaving thin wires 42a, 43a, and have flexibility in nature. Therefore, both of the mesh members 42 and 43 can be bent and deformed in the direction of packing the photocatalyst particles 40 at a high density in the accommodation chamber 4t. By utilizing the bending deformation of the mesh members 42 and 43 in this manner, a large number of photocatalyst particles 40 are packed at high density without looseness in the accommodation room 4t, and the mesh members 42 and 43 are directly or It can be pressed indirectly. Therefore, rattling of the photocatalyst particles 40 in the storage chamber 4t is suppressed, and abnormal noise caused by rattling of the photocatalyst particles 40 is also suppressed. Further, the mesh members 42 and 43 described above are mesh openings 42 having a size smaller than the outer diameter of the photocatalyst particles 40.
Since the photocatalyst particles 40 packed in the storage chamber 4t are prevented from falling off from the mesh members 42 and 43, the photocatalyst particles 40 are prevented from falling off.

In this embodiment, as described above,
An elastic member 44 having a soft layer 44c in contact with the photocatalyst particles 40 is packed together with the photocatalyst particles 40 into the accommodation chamber 4t. For this reason, by the elastic deformation function of the elastic member 44, a large number of photocatalyst particles 4 packed in the accommodation chamber 4t are formed.
The rattling of 0 is further suppressed as compared with the case where the elastic member 44 is not provided. Therefore, damage and deterioration of the photocatalyst particles 40 due to friction due to rattling can be further prevented, and the durability and life of the photocatalyst particles 40 can be further improved. Further, even when an impact or the like acts on the photocatalyst filter 4, such as when the photocatalyst filter 4 is dropped on the floor, the elastic member 44 having the soft layer 44c can exert an impact relaxation effect, and 40 can be protected.

In order to enhance the purification performance of the photocatalyst filter 4, it is preferable that the ventilation of the photocatalyst filter 4 be sufficiently ensured and the transparency of the light emitted from the light emitting diode 49m be sufficiently ensured. In this respect, in the present embodiment, the mesh members 42 and 43 have a large number of mesh openings 42f and 43.
Because of having f, ventilation of the photocatalytic filter 4 is ensured. Further, the transparency of the light emitted from the light emitting diode 49m is well ensured. Further, since the elastic member 44 also has a large number of mesh openings 44f, the ventilation of the photocatalytic filter 4 is ensured, which is advantageous for improving the purification performance. Further, since the photocatalyst filter 4 is a flat type and has a small thickness in the ventilation direction, even if the photocatalyst particles 40 are packed in the photocatalyst filter 4, the ventilation of the photocatalyst filter 4 is sufficiently ensured and the photocatalyst filter 4 is purified. This is advantageous for improving performance.

In order to enhance the purifying performance of the photocatalytic filter 4, the photocatalytic filter 4 should face the light emitting diode 49m for activating the photocatalytic filter 4 with as large an area as possible, and the light receiving area for receiving the light from the light emitting diode 49m should be increased. Is preferred. In this respect, in this embodiment, the photocatalyst filter 4 is of a flat type having a small thickness, and its wide area is directly opposed to the light emitting diode 49m.
0 can be effectively activated, which is advantageous for enhancing the purification performance of the photocatalytic filter 4.

(Others) In the air purifier of the above-described embodiment, both the filter 3 for capturing dust and the photocatalytic filter 4 are provided. Filter 3 may be eliminated.

In the above-described embodiment, the photocatalyst filter 4 is mounted on an air purifier mounted on a vehicle. However, the present invention is not limited to this, and the photocatalyst filter 4 can be mounted on other devices required to reduce pollutants. The external shape of the photocatalytic filter 4 is not limited to a thin rectangular box shape, but may be a circular box shape. The shape of the arm 41r is not limited to the above embodiment. In addition, the present invention is not limited to only the embodiments described above and shown in the drawings, and can be implemented with appropriate modifications without departing from the gist. The above-described embodiments illustrate the concept of the present invention, and the words, members, and words modifying the members described in the examples can be described in each claim, even if only a part. .

(Supplementary Note) The following technical ideas can be understood from the above description. An air inlet and an air outlet, an air flow path connecting them, a fan for forming an air flow flowing from the air inlet to the air outlet through the air flow path, and an air flow arranged in the air flow path and flowing through the air flow path. In an air purifier having a purifying unit for purifying, the purifying unit includes a flat-type photocatalytic filter, and a flat-type excitation unit disposed along the photocatalytic filter so as to face the photocatalytic filter. An air purifier characterized. This is advantageous for reducing the thickness of the air purifier. -An air purifier characterized in that the photocatalyst filter is of a flat type and is detachably attached to the back side of the outlet grill. -In each claim, the photocatalyst filter or the air cleaner characterized by having an excessive bending prevention means (arm portion 41r) for suppressing excessive bending of the mesh member. This is advantageous for preventing damage to the mesh member. -The photocatalyst filter or the air purifier according to claim 2, wherein the elastic member is disposed on a side away from the excitation means such as a light emitting diode. The deterioration of the elastic member is suppressed. In each of the claims, the particles having the photocatalytic substance are contained in the photocatalytic filter so that the number of the particles arranged in the plane direction of the photocatalytic filter is large and the number of the particles arranged in the thickness direction of the photocatalytic filter is small. A photocatalytic filter or an air purifier, which is packed in a photocatalyst.

[0039]

According to the photocatalyst filter according to the present invention and the air purifier according to the present invention, since the mesh member attached to the ventilation window of the frame constituting the photocatalytic filter has flexibility, it has a photocatalytic substance. The particles can be bent and deformed in a direction of packing the particles at a high density in the storage chamber. By utilizing the bending deformation of the mesh member in this manner, the particles having the photocatalytic substance can be packed in the accommodation chamber at a high density, the rattling of the particles is suppressed, and the irregularity caused by the rattling of the particles having the photocatalytic substance is suppressed. Sound is also suppressed. Since the rattling of the particles having the photocatalytic substance is suppressed in this manner, it is advantageous to prevent the damage and deterioration of the particles caused by the friction based on the rattling, and the durability and the durability of the particles having the photocatalytic substance are improved. Life can be extended. Especially when the elastic member is packed in the accommodation chamber together with the particles, since the rattling of the particles is further suppressed, damage of the particles due to friction based on the rattling,
This is advantageous for further preventing deterioration. The air purifier according to the present invention is suitable for a case where the air purifier is mounted on a vehicle that vibrates during traveling.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of an air purifier according to an embodiment of the present invention.

FIG. 2 is an enlarged cross-sectional view of the vicinity of a filter and a photocatalytic filter of an air purifier according to one embodiment of the present invention.

FIG. 3 is a plan view of the air purifier according to the embodiment of the present invention.

FIG. 4 is an enlarged cross-sectional view showing an embodiment in which the blow-out grill is rotated downward and temporarily held according to the embodiment of the present invention.

FIG. 5 is an enlarged cross-sectional view schematically showing a process of taking a filter into and out of a filter chamber of a main body of an air purifier according to an embodiment of the present invention.

FIG. 6 is a partially enlarged cross-sectional view showing a state in which the rotation angle of the blowout grill is large and a rotation arm of the blowout grill is engaged with a first engagement portion and a second engagement portion.

FIG. 7 is a partially enlarged cross-sectional view showing a state in which the rotation angle of the blowout grill is small, and a rotation arm of the blowout grill can be inserted into and removed from the first engagement portion and the second engagement portion.

FIG. 8 is a partially enlarged cross-sectional view showing the vicinity of a photocatalyst filter and an excitation unit attached to a blowout grill.

FIG. 9 is a partially enlarged view showing a mesh member.

FIG. 10 is a partially enlarged view showing an elastic member.

FIG. 11 is a side view showing a state immediately before the photocatalytic filter is attached to the outlet grill.

FIG. 12 is a side view showing a state after the photocatalytic filter has been attached to the outlet grill.

13 is an enlarged cross-sectional view showing a cross section taken along line W17-W17 in FIG. 12 and showing a vicinity of a filter engaging portion in a state after the photocatalytic filter is attached to the outlet grill.

FIG. 14 is a plan view of a photocatalytic filter.

FIG. 15 is a side view of the photocatalytic filter.

[Explanation of symbols]

In the figure, 1 is a main body, 1c is an air flow path, 10t is an intake port, 2
Is a fan, 3 is a filter, 4 is a photocatalytic filter (purification unit), 4t is a storage chamber, 4s is a projection (attachment prevention unit), 40
Is a photocatalyst particle, 41 is a first frame, 41x is a ventilation window, 4
2, 43 are mesh members, 42f, 43f are mesh openings, 44
Is an elastic member, 44f is a mesh opening, 46 is a second frame, 46
x indicates a ventilation window, 49 indicates an excitation unit, 49m indicates a light emitting diode, 53 indicates an air outlet, and 54s indicates a protrusion (an attachment preventing portion).

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) F24F 7/00 B01D 53 / 36H (72) Inventor Kazuhiro Sakai 1 Ochiai Ogataai Kasuga-cho, Kasuga-machi, Nishi-Kasugai-gun, Aichi Prefecture Address Toyoda Gosei Co., Ltd. F-term (reference) 4C080 AA07 BB02 CC01 HH05 JJ05 KK08 LL03 MM02 NN05 QQ17 4D048 AA22 BA07X BA07Y BA13X BA15Y BA16Y BA26Y BA27Y BA41X BA42Y BA46Y BB01 CA01 BA03 BA02 ACOA BAA 4A BB04A BB06A BB09A BC12A BC36A BC50A BC59A BC60A CA17 EA02X EA02Y EB18Y EC22Y

Claims (5)

[Claims] 1. A frame having a storage chamber and a ventilation window communicating with the storage chamber, a large number of particles having a photocatalytic substance packed in the storage chamber of the frame, and attached to the ventilation window of the frame. A mesh member having a large number of mesh openings that can be ventilated and smaller in size than the particles, and the mesh member presses against the packed particles to suppress rattling of the particles. A photocatalytic filter characterized by the following. 2. The photocatalytic filter according to claim 1, wherein an elastic member that comes into contact with said particles is packed together with said particles in said frame. 3. A photocatalytic filter according to claim 2, wherein said elastic member has a mesh shape having a mesh opening through which air can pass. 4. An air inlet and an air outlet, an air flow path connecting the air inlet and the air outlet, a fan for forming an air flow flowing from the air intake through the air flow path to the air outlet, and a fan arranged in the air flow path. An air purifier having a purifying unit for purifying an air flow flowing through the air flow path, wherein the purifying unit includes the photocatalyst filter according to any one of claims 1 to 3. 5. A grill according to claim 4, further comprising a grill provided on at least one of said air inlet and said air outlet.
At least one of the photocatalyst filter and the grill according to claim 3, when the front and back of the photocatalyst filter are reversed,
An air purifier having an attachment preventing portion for preventing attachment of the photocatalytic filter to the grill.