JP6255574B2 - Deodorizing filter and air conditioner - Google Patents

Description

  The present invention relates to a deodorizing filter provided with activated carbon that adsorbs odorous components contained in air.

  The configuration of this conventional deodorizing filter has been as follows.

  That is, it has a configuration including a lattice-shaped activated carbon holder, a large number of granular activated carbon bonded to the activated carbon holder, and a cover portion that wraps the activated carbon holder to which the activated carbon is bonded (for example, a preceding structure similar to this). The following Patent Document 1 exists as a document).

JP 2006-43106 A

  The problem in the above conventional example was to add a fungicide to the activated carbon so as not to lower the deodorizing performance of the activated carbon.

  When adding a fungicide to activated carbon, it is conceivable to impregnate the activated carbon with a fungicide, but it penetrates into the pores of the activated carbon, closes the pores, changes the properties of the surface inside the pores, and deodorizes. The performance was degraded.

  Therefore, an object of the present invention is to add a fungicide to the activated carbon so as not to lower the deodorizing performance of the activated carbon.

In order to achieve this object, the present invention provides an activated carbon holder in which activated carbon is fixed by a first hot melt, and includes a mold prevention portion having a mold inhibitor on the surface of the activated carbon, and is fixed to the activated carbon holder. A part of the activated carbon is covered with a second hot melt containing the fungicide that is less likely to enter the pores of the activated carbon than the first hot melt. Yes, thereby achieving the initial objective.

  As described above, the present invention comprises an activated carbon holder, a number of granular activated carbons adhered to the activated carbon holder, and a mold prevention part provided on the surface of the activated carbon. Since the antifungal agent is contained and fixed to a part of the surface of the activated carbon, the antifungal agent can be added to the activated carbon so as not to deteriorate the deodorizing performance of the activated carbon.

  That is, since the anti-mold part is a hot melt containing an anti-mold agent, it is difficult to penetrate into the pores of the activated carbon when it is fixed to a part of the surface of the activated carbon. Thereby, while being able to suppress the fall of the deodorizing performance of activated carbon, the mold | generation which generate | occur | produces on the surface of activated carbon can also be suppressed.

  As a result, an antifungal agent can be added to the activated carbon so as not to lower the deodorizing performance of the activated carbon.

The figure which shows the schematic cross section of the deodorizing filter of Embodiment 1 of this invention. Schematic showing activated carbon support and activated carbon in the deodorizing filter The figure which shows the schematic cross section of the deodorizing filter The figure which shows activated carbon and mold prevention part of the same deodorizing filter The figure which shows the schematic cross section of the activated carbon and the mold prevention part of the same deodorizing filter A perspective view showing an air conditioner to which the deodorizing filter is applied. The figure which shows the cross section of the air conditioning apparatus to which the deodorizing filter is applied

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
As shown in FIGS. 1 to 4, the deodorizing filter 1 according to this embodiment includes an activated carbon holder 2, activated carbon 3, a mold prevention unit 4, and a cover unit 5.

  The activated carbon holder 2 is a lattice-shaped net 6 and includes an opening 7 having a regular square shape. The size of the opening 7 is 5 to 12 mm. The wire diameter of the net 6 is 0.5 to 2.0 mm. The activated carbon 3 is adhered to the surface of the net 6 which is the activated carbon holder 2 by the hot melt 8.

  An adhesion method in which the activated carbon 3 is adhered to the surface of the net 6 by the hot melt 8 will be described.

  First, the hot melt 8 is heated to form a liquid, the net 6 is immersed in the liquid hot melt 8, and the hot melt 8 is applied to the surface of the net 6. Next, a large number of granular activated carbon 3 is sprinkled on the net 6 coated with the hot melt 8, and the activated carbon 3 is adhered to the net 6 by the liquid hot melt 8. Finally, cooling is performed with the activated carbon 3 attached to the net 6 until the liquid hot melt 8 becomes solid. Here, even when the activated carbon 3 is solidified and bonded to the net 6, the opening 7 of the net 6 is smaller than the opening 7 before the activated carbon 3 is bonded, but includes the opening 7.

  An antifungal part 4 is fixed to the surface of the activated carbon 3. The activated carbon holding body 2 to which the activated carbon 3 provided with the mold prevention portion 4 is bonded is wrapped by a bag-shaped cover portion 5.

  The cover part 5 is a net-like size that does not allow the activated carbon 3 to pass through, is folded across the activated carbon holding body 2, is sewn on three sides, and is closed.

  The deodorizing filter 1 having the above configuration is mounted on an air conditioner 9 including a blowing means 14 as shown in FIGS. Specifically, the air conditioner 9 includes a main body case 12 having a suction port 10 and a blower outlet 11, and an air conditioning means 13 and a blower means 14 in the main body case 12. The air conditioning means 13 and the air blowing means 14 are provided in an air passage that connects the suction port 10 and the air outlet 11. The deodorizing filter 1 is provided in the air path between the suction port and the air blowing means. When the air blowing means 14 is driven, air is sucked from the suction port 10 and exhausted to the outside through the deodorizing filter 1 and the dust collecting filter which is the air conditioning means 13. The deodorizing filter 1 is mounted on the downstream side of the air passage of the dust collecting filter that is the air conditioning means 13. Here, indoor air is sucked into the air passage from the suction port 10, and the sucked air is blown in a substantially vertical direction with respect to the square-shaped opening 7 of the activated carbon holder 2 in the deodorizing filter 1. . An example of the air conditioning means 13 is a dust collection filter that captures at least one of pollen, dust, and dust particles. As described above, when the deodorizing filter 1 is mounted on the air conditioner 9, when mold fungus adheres to the deodorizing filter 1, the mold fungus can be inactivated by the mold prevention unit 4. It is possible to prevent the bacteria from being released again by blowing air.

  The feature in this embodiment is the anti-mold part 4 as shown in FIG. This anti-mold part 4 is one in which a hot-melt 18 contains an anti-mold agent 19 and is fixed to a part of the surface of the activated carbon 3. That is, the anti-mold part 4 contains the anti-mold agent 19 in the hot melt 18, and therefore, when it is fixed to a part of the surface of the activated carbon 3, it is difficult to enter the pores of the activated carbon 3. . Thereby, while being able to suppress the fall of the deodorizing performance of the activated carbon 3, the mold | generation which generate | occur | produces on the surface of the activated carbon 3 can also be suppressed.

  As a result, the fungicide 19 can be added to the activated carbon 3 so as not to lower the deodorizing performance of the activated carbon 3.

  This point will be described in more detail. The activated carbon 3 has three types of pores: macropores 15, mesopores 16, and micropores 17. A hole extending inward of the activated carbon 3 from the surface of the activated carbon 3 is a macro hole 15. A large number of holes extend inward of the activated carbon 3 from the inner surface of the macro hole 15. This is the meso hole 16. Many more holes extend from the inner surface of the meso hole 16. This is the micropore 17. The pore diameters of these pores become smaller in the order of macropores 15, mesopores 16, and micropores 17. Among these pores, it is the smallest micropore 17 that performs the most deodorization. It is the deodorization mechanism of the activated carbon 3 that confines odorous components in the micropores 17. The micropores 17 are connected to the micropores 17 extending from the other mesopores 16. Thereby, even if a part of many macropores 15 on the surface of the activated carbon 3 is blocked, the deodorizing effect is hardly lowered.

  When the hot melt 18 is melted and attached to the surface of the activated carbon 3 as in this embodiment, a part of the hot melt 18 enters the macro hole 15, but the meso hole 16, the micro hole 17 is considered difficult to enter.

  This is because even if the hot melt 18 is melted and attached to the surface of the activated carbon 3, the hot melt 18 has a high viscosity and is pasty, and the mesopores 16 and the micropores 17 are small. It is considered that it is difficult to enter the hole 16 and the micro hole 17. The mesopore 16 has a diameter of 2 to 50 nm, and the micropore 17 has a diameter of less than 2 nm. Thereby, while being able to suppress the fall of the deodorizing performance of the activated carbon 3, the mold | generation which generate | occur | produces on the surface of the activated carbon 3 can also be suppressed. An example of the hot melt 18 is a synthetic rubber hot melt adhesive.

  Further, since it is considered that a part of the hot melt 18 enters the macropores 15 of the activated carbon, it is considered that what is fixed to the surface of the activated carbon 3 is unlikely to come off from the surface of the activated carbon 3.

  Here, the fixing method of the mold prevention part 4 in this embodiment is demonstrated concretely.

  First, in a state where the hot melt 18 is warmed, a powdery fungicidal agent 19 is mixed, and the hot melt 18 contains the fungicidal agent 19. One example of the fungicide 19 is an organometallic compound, an organometallic compound, or an inorganic compound. The hot melt 18 containing the fungicide 19 is sprayed on one side of the net 6 to which the activated carbon 3 is bonded with a spray gun. The spray gun sprays the filamentous hot melt 18 from the hole at the center of the tip, and simultaneously adheres the activated carbon 3 from a number of holes around the center hole in almost the same direction as the spray from the center hole. Air blows out to one side of the net 6.

  As a result, the thread-like hot melt that has come out from the hole in the center of the spray gun is torn into a plurality of threads that are thinner than the thread-like hot melt. The plurality of thin thread-like hot melts 18 are fixed to a part of the surface of the activated carbon 3 as a layer so as to cover the entire one surface of the net 6 bonded with the activated carbon. That is, a plurality of thin thread-like hot melt layers 18 are fixed to a part of the surface of the activated carbon 3 so as to cover the opening 7 of the net 6. Here, the hot melt 18 containing the antifungal agent 19 in the form of a plurality of thin threads has a high viscosity and is paste-like, so it is difficult to enter the pores of the activated carbon 3 when adhering to the surface of the activated carbon. . Then, the plurality of thin thread-like hot melts 18 are fixed to a part of the surface of the activated carbon 3 as a layer so as to cover the entire one surface of the net 6 to which the activated carbon 3 is bonded. That is, a plurality of thin thread-like hot melt 18 layers adhere to a part of the surface of the activated carbon 3 so as to cover the opening of the net 6. However, since the thin thread-like hot melt 18 layer has a gap, the thin thread-like hot melt 18 does not cover the entire surface of the activated carbon 3 but covers only a part of the surface of the activated carbon 3. Is.

  Next, similarly, the hot melt 18 containing the fungicide 19 is sprayed on the other side of the net to which the activated carbon 3 is bonded with a spray gun.

  As a result, the thread-like hot melt that has come out of the center hole of the spray gun is split into a plurality of thread-like shapes that are thinner than the thread-like hot melt 18. Here, the hot melt 18 containing the antifungal agent 19 in the form of a plurality of thin threads has a high viscosity and is paste-like, and therefore, when attached to the surface of the activated carbon 3, it is difficult to enter the pores of the activated carbon 3. is there. The plurality of thin thread-like hot melts 18 are fixed to a part of the surface of the activated carbon 3 as a layer so as to cover the entire other surface of the net 6 to which the activated carbon 3 is bonded. That is, a plurality of thin thread-like hot melt 18 layers adhere to a part of the surface of the activated carbon 3 so as to cover the opening of the net 6. However, since the thin thread-like hot melt 18 layer has a gap, the thin thread-like hot melt 18 does not cover the entire surface of the activated carbon 3 but covers only a part of the surface of the activated carbon 3. Is.

  Finally, hot air is blown to one surface of the net 6 to which the activated carbon 3 is fixed by a hot air blowing device. With this hot air, a part of the thin thread-like hot melt 18 that is the anti-mold part 4 that is not fixed to the surface of the activated carbon 3 is fixed to the surface of the activated carbon 3. Further, hot air is blown by a hot air blowing device to various surfaces of the net 6 to which the activated carbon 3 is fixed. With this hot air, a part of the thin thread-like hot melt 18 that is the anti-mold part 4 that is not fixed to the surface of the activated carbon 3 is fixed to the surface of the activated carbon 3. Here, the thin thread-like hot melt 18 has a melted surface, but has a high viscosity and is paste-like, so that when it adheres to the surface of the activated carbon 3, it is difficult to enter the pores of the activated carbon 3.

  In addition, the blowing direction which blows hot air to the one side of the net | network 6 which adhere | attached the activated carbon 3 by a hot air blower, or many directions is the case where the deodorizing filter 1 is mounted in the air conditioning apparatus 9 provided with the ventilation means 14. The air in the room is blown to the deodorizing filter 1 by the blowing means 14 in the same direction.

  When the mold preventive agent 19 is contained and the hot melt 18 is fixed to a part of the surface of the activated carbon 3 by the above method, at least a part of the mold preventive part 4 has a thread shape. Thereby, since the surface area of the mold prevention part 4 becomes large, the mold | fungi which generate | occur | produce on the surface of the activated carbon 3 can further be suppressed.

  In addition, a part of the hot melt 18 enters the macropores 15 on the surface of the activated carbon 3 and solidifies, so that even the hot melt 18 having a thread shape is likely to adhere to the surface of the activated carbon 3.

  Further, at least a part of the mold prevention part 4 has a mesh shape. Thereby, since the fiber-shaped anti-mold part 4 intersects and the intersecting part 20 adheres and forms a mesh shape, the strength of the anti-mold part 4 can be improved.

  Further, the thread-like hot melt 18 that is the mold prevention part 4 is fixed across the surfaces of the plurality of activated carbons 3. That is, a part of the mold prevention unit 4 is provided with the space 21 between the surface of the activated carbon 3. Thereby, since a part of the mold prevention part 4 is provided with the space part 21 between the surfaces of the activated carbon 3, the surface area of the mold prevention part 4 is increased, and the mold generated on the surface of the activated carbon 3 is further suppressed. it can.

  Moreover, when hot air is blown to one surface of the net 6 to which the activated carbon 3 is fixed by a hot air blowing device, the thin thread-like hot melt in the opening 7 of the net 6 is melted and the inner surface of the opening 7 of the net 6 is melted. A thin thread-like hot melt 18 in the opening 7 of the net 6 is fixed to the activated carbon 3. As a result, the hot melt 18 containing the fungicide 19 can be fixed to a part of the surface of the activated carbon 3 adhered to the one surface side, the other surface side of the net 6 and the inner surface side of the opening of the net 6. The temperature of the hot air may be such that the surface of the thin thread-like hot melt 18 on the surface of the activated carbon 3 is melted.

  Furthermore, a thin thread-like hot melt 18 that is a mold prevention part 4 not fixed to the surface of the activated carbon 3 by blowing hot air to one side or many sides of the net to which the activated carbon 3 is fixed by a hot air blowing device. It is thought that a part of enters into the gap 22 between the adjacent activated carbons and the activated carbon 3a and the activated carbon 3b in a state of entering between the adjacent activated carbons 3a and 3b. That is, at least a part of the anti-mold part 4 covers the gap 22 between the activated carbon 3a and the activated carbon 3b adjacent to each other and adheres to a part of the surface of the activated carbon 3a and the activated carbon 3b. Thereby, it is possible to suppress mold fungus from entering the gap 22 between the activated carbon 3a and the activated carbon 3b.

  The anti-mold part 4 may be one in which the hot melt 18 contains the anti-mold agent 19 and the carbon black 23 and is fixed to a part of the surface of the activated carbon 3. Thus, when the hot melt 18 containing the carbon black 23 is solidified, the carbon black 23 is solid, and a slight gap is generated between the hot melt 18 and the carbon black 23. It is considered that the mold preventive agent 19 easily comes out on the surface of the hot melt 18, that is, the surface of the mold preventive part 4 due to the gap. This is because the molecules of the fungicide 19 move in the hot melt 18, but compared to the movement in the hot melt 18, the surface of the hot melt 18, that is, between the hot melt 18 and the carbon black 23. It is considered that the surface of the gap is easy to move although it is slight.

  Further, the carbon black 23 has a gap in the carbon black 23. It is considered that the molecules of the fungicide 19 also move easily in the gap in the carbon black 23, that is, in the inner surface of the carbon black 23 compared to the movement in the hot melt 18. That is, the anti-mold part 4 contains the anti-mold agent 19 and further the carbon black 23 in the hot melt 18, so that the anti-mold part 19 easily comes out on the surface of the anti-mold part 4, and the surface of the activated carbon 3. Generated mold can be further suppressed.

  The hot melt 8 and the hot melt 18 may be made of the same material. Thereby, the hot melt 8 for solidifying and adhering the activated carbon 3 to the net 6 and the hot melt 18 used for the anti-mold part 4 can be used. That is, since a plurality of types of hot melts are not prepared and one type of hot melt can be used, the production efficiency of the deodorizing filter 1 is improved.

  As described above, the present invention adheres the activated carbon holder, a large number of granular activated carbon bonded to the activated carbon holder, the mold prevention part provided on the surface of the activated carbon, and the activated carbon provided with the mold prevention part. And the anti-mold part contains a fungicide in a hot melt and is fixed to a part of the surface of the activated carbon, thus reducing the deodorizing performance of the activated carbon. An anti-fungal agent can be added to the activated carbon so that it does not.

  That is, the anti-mold part is a hot melt mainly composed of a thermoplastic resin and contains an anti-mold agent, so that when it is fixed to a part of the activated carbon surface, it does not easily enter the pores of the activated carbon. It is. Thereby, while being able to suppress the fall of the deodorizing performance of activated carbon, the mold | generation which generate | occur | produces on the surface of activated carbon can also be suppressed.

  As a result, an antifungal agent can be added to the activated carbon so as not to lower the deodorizing performance of the activated carbon.

  Therefore, it is expected to be used for air conditioners for home use and office use.

DESCRIPTION OF SYMBOLS 1 Deodorizing filter 2 Activated carbon holding body 3 Activated carbon 3a Activated carbon 3b Activated carbon 4 Mold prevention part 5 Cover part 6 Net 7 Opening 8 Hot melt 9 Air conditioning apparatus 10 Suction inlet 11 Outlet 12 Body case 13 Air conditioning means 14 Air blow means 15 Macro hole 16 Mesopores 17 Micropores 18 Hot melt 19 Antifungal agent 20 Crossing portion 21 Space portion 22 Gap 23 Carbon black

Claims (7)

In the activated carbon holder in which the activated carbon is fixed by the first hot melt, a part of the activated carbon which is provided with a mold preventing part having a mold inhibitor on the surface of the activated carbon and is fixed to the activated carbon holder is A deodorizing filter, which is covered with a second hot melt containing the anti-fungal agent, which is less likely to enter the pores of the activated carbon than the hot melt. The deodorizing filter according to claim 1, wherein at least a part of the anti-mold part has a thread shape. The deodorizing filter according to claim 2, wherein at least a part of the anti-mold part has a mesh shape. 4. The deodorizing filter according to claim 2, wherein a part of the mold prevention part includes a space part between the activated carbon surface and the surface of the activated carbon. The deodorizing filter according to any one of claims 2 to 4, wherein a part of the anti-mold part covers a gap between the activated carbon and the activated carbon adjacent to each other. The deodorizing filter according to any one of claims 1 to 5, wherein the anti-mold part contains an anti-mold agent and carbon black in hot melt. The deodorization filter according to any one of claims 1 to 6, a dust collection filter that captures at least one of pollen, dust, and dust fine particles, and externally through the deodorization filter and the dust collection filter by sucking air. And an air conditioner for exhausting the air.

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