JP2009050521A - Air cleaner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve cleaning function such as sterilization and deodorization by dispersively feeding ozone on the upstream side of a catalyst filter while preventing diffusion of ozone within a room. <P>SOLUTION: The air cleaner 1 cleans air with the action of oxygen radicals generated when ozone passes through catalyst filters 20. The air cleaner 1 includes an intake 11 for taking air into the air cleaner 1, and an outlet 12 for feeding the air treated inside the air cleaner 1 to the interior again. The catalyst filters 20 for decomposing ozone are provided in air channels 15 and 16 formed in the intake 11 and the outlet 12, respectively, and a porous tube 25 is provided in the vicinity of the intake 11. The air cleaner also has an ozone generating mechanism 30 for feeding ozone into the porous tube 25. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an air cleaning device that performs processing such as sterilization and deodorization on air.

Conventionally, an air cleaning device using ozone generated by the action of discharge is known (Patent Documents 1 to 4). In such an air cleaning device, oxygen radicals are decomposed by a catalyst, and viruses in the air are inactivated by using the oxygen radicals. In addition, cell membranes are destroyed and sterilized against bacteria and molds. , Odorous substances are deodorized by oxidative decomposition.
JP-A-9-31585 JP 2004-57253 A JP 2005-125070 A JP 2006-75402 A

  In the air cleaning devices of Patent Documents 1 to 3, all are generated by an ozone generator by disposing an ozone generator upstream of an air flow path formed inside the device and disposing a decomposition catalyst downstream. The generated ozone is decomposed by a decomposition catalyst so that ozone is not emitted outside the apparatus. However, the length of the air flow path formed inside the apparatus is limited, and it becomes difficult to sufficiently disperse the ozone generated by the ozone generator in the air to be processed. For this reason, in these air cleaning apparatuses of Patent Documents 1 to 3, ozone generated by the ozone generator concentrates on only a part of the decomposition catalyst, and ozone can be uniformly decomposed on the entire surface of the decomposition catalyst. However, the degradation performance was reduced.

  Moreover, in the air purifying apparatus of the above-mentioned patent document 2, in order to eliminate such inconvenience, a slit-like discharge hole is provided in the ozone diffusion pipe so as to release ozone uniformly. However, providing such an ozone diffusion pipe in a narrow air flow path has a drawback that the structure becomes complicated. In addition, in order to provide the ozone diffusion pipe, it is necessary to change the design of the size and shape of the air flow path, and it has not been possible to easily make improvements using existing air cleaning devices.

  On the other hand, in the air cleaning device of Patent Document 4, ozone can be sufficiently diffused into the air by supplying ozone into the room together with the conditioned air, and the ozone can be uniformly decomposed over the entire surface of the decomposition catalyst. Therefore, high decomposition performance can be exhibited, and cleaning treatment such as sterilization and deodorization can be performed efficiently. However, in the air cleaning device of Patent Document 4, although the indoor ozone concentration is suppressed to a low concentration that is harmless to the human body, such as 50 ppb, there is a concern of causing psychological unrest in terms of health and safety.

  An object of the present invention is to disperse and supply ozone to the upstream side of a catalytic filter while preventing ozone diffusion into the room, thereby improving clean functions such as sterilization and deodorization.

  In order to achieve this object, according to the present invention, there is provided an air cleaning device for purifying air by the action of oxygen radicals generated by passing ozone through a catalytic filter, wherein the air is purified inside the air cleaning device. And an air outlet that supplies air treated inside the air purifier again into the room, and is formed between the air inlet and the air outlet inside the air purifier. A catalyst for decomposing ozone is provided in the air flow path, a porous tube is provided in the vicinity of the suction port, and an ozone generating mechanism for supplying ozone into the porous tube is provided. An apparatus is provided.

  The ozone generating mechanism includes: a discharge plasma unit that generates ozone; an ozone channel that communicates the inside of the discharge plasma unit and the porous tube; and the ozone channel to the inside of the porous tube from the discharge plasma unit. You may have a pump which sends ozone. Moreover, the said suction inlet may be formed in slit shape, and the said perforated tube may be arrange | positioned along the longitudinal direction of the said suction inlet. A heat exchanger may be provided in the air flow path. In this case, a catalyst filter may be provided on the downstream side of the heat exchanger.

  According to the present invention, by releasing ozone from a perforated tube provided in the vicinity of the suction port, ozone can be dispersed and supplied to the air taken into the air purifier from the suction port. Then, by passing the air in which ozone is dispersed through the catalyst filter, it is possible to clean the air by the action of oxygen radicals generated by decomposing ozone. In this case, ozone can be dispersed in substantially the entire air taken into the air purifier from the suction port, and ozone can be uniformly decomposed over the entire surface of the catalyst filter by passing ozone over the entire surface of the catalyst filter. And high decomposition performance can be obtained.

  Moreover, the air cleaner of this invention can also improve an existing air cleaner simply by providing a perforated tube in the vicinity of a suction inlet, and can also raise a cleaning function.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is an explanatory diagram of a state in which an air purifying apparatus 1 according to an embodiment of the present invention is attached to an upper portion of a chamber 2. FIG. 2 is an explanatory diagram of the lower surface 10 of the air cleaning device 1 that is exposed on the ceiling surface of the chamber 2. FIG. 3 is a partially enlarged view of the porous tube 25. In addition, in this specification and drawing, about the component which has the substantially same function structure, duplication description is abbreviate | omitted by attaching | subjecting the same code | symbol.

  On the lower surface 10 of the air cleaning device 1, a suction port 11 that takes air inside the chamber 2 into the air cleaning device 1 and a blowout that supplies the air treated inside the air cleaning device 1 to the inside of the chamber 2 again. A mouth 12 is provided. In the illustrated example, on the lower surface 10 of the air cleaning device 1, the slit-shaped suction ports 11 are arranged in a substantially square shape, and a pair of rectangular blow-out ports 12 are arranged on the outer sides of two sides parallel to each other. is doing.

  An inner air flow path 15 and an outer air flow path 16 are provided inside the air purification apparatus 1, and the inside of the air purification apparatus 1 is interposed between the inner air flow path 15 and the outer air flow path 16. Is interposed. The suction port 11 is in communication with the inner air flow path 15, and the blowout port 12 is in communication with the outer air flow path 16. The suction port of the fan 17 communicates with the inside of the inner air flow path 15 (however, downstream of the heat exchanger 21 described later), and the discharge port of the fan 17 communicates with the outer air flow path 16. Then, by the power of the fan 17, the air inside the chamber 2 is taken into the inner air flow channel 15 from the suction port 11, blown to the outer air flow channel 16 through the fan 17, and again from the blowout port 12 to the inside of the chamber 2. It comes to supply air.

  In the inner air flow path 15, a catalyst filter 20 and a heat exchanger 21 are provided in the order of the air flow between the suction port 11 and the fan 17. The catalyst filter 20 contains a metal compound catalyst such as manganese dioxide, nickel oxide, iron tetroxide, copper oxide, cobalt carbonate, nickel carbonate, copper carbonate, nickel as a catalyst for decomposing ozone. . Ozone released from a porous tube 25, which will be described later, is decomposed in contact with the metal compound catalyst by the catalyst filter 20 to generate oxygen radicals.

  A heat source unit 22 is built in the air cleaning device 1, and a heat medium cooled or heated by the heat source unit 22 is circulated to the heat exchanger 21. The heat exchanger 21 adjusts the temperature of the air to a desired temperature by exchanging heat between the air flowing through the inner air flow path 15 and a heat medium.

  A porous tube 25 is provided in the vicinity of the suction port 11 formed in the lower surface 10 of the air cleaning device 1. The porous tube 25 is disposed over the entire length along the suction port 11 formed in a slit shape. Further, in the illustrated example, the perforated tube 25 is attached in the vicinity of the suction port 11 inside the suction port 11 (inside the air cleaning device 1, that is, inside the inner air flow path 15). As the porous tube 25, for example, a general-purpose porous tube made of a tetrafluoroethylene resin having excellent corrosion resistance and ozone resistance can be used.

  As shown in FIG. 3, the perforated tube 25 has a hollow, generally cylindrical shape with an interior 26 formed into a cavity. On the peripheral surface of the perforated tube 25, a large number of air holes 27 are distributed throughout.

  As shown in FIG. 1, ozone is supplied to the perforated tube 25 from an ozone generation mechanism 30. The ozone generation mechanism 30 has a discharge plasma unit 32 in which a discharge element 31 is built. Air is supplied from the pump 33 to the discharge plasma unit 32. In the discharge plasma unit 32, oxygen contained in the air supplied from the pump 33 is turned into ozone by the discharge of the discharge element 31. The discharge plasma unit 32 is communicated with the interior 26 of the perforated tube 25 by an ozone channel 35. Thereby, ozone generated by the discharge of the discharge element 31 in the discharge plasma unit 32 is sent to the inside 26 of the porous tube 25 through the ozone flow path 35 by the operation of the air pump 33. The air pump 33 applies a positive pressure to the inside 26 of the porous tube 25, and thereby ozone is uniformly released from the entire surface of the porous tube 25.

  In the air cleaning device 1 configured as described above, the air in the chamber 2 is taken into the inner air flow path 15 via the suction port 11. On the other hand, ozone generated in the discharge plasma unit 32 is sent to the inside 26 of the porous tube 25 through the ozone flow path 35 by the operation of the air pump 33. As a result, ozone is uniformly emitted from a large number of vent holes 27 distributed over the entire peripheral surface of the perforated tube 25. As a result, when passing through the suction port 11, ozone is released from the porous tube 25 disposed in the vicinity of the suction port 11 into the air sucked into the suction port 11 of the air cleaning device 1.

  In this case, since the porous tube 25 is disposed over the entire length of the suction port 11 formed in a slit shape, the peripheral surface of the porous tube 25 with respect to the air taken into the inner air flow path 15 from the suction port 11. Ozone can be released uniformly from the whole. Thereby, ozone can be uniformly dispersed in the entire air taken into the inner air flow path 15.

  The air in which ozone is dispersed in this way then passes through the catalyst filter 20 in the inner air flow path 15. Here, when passing through the catalyst filter 20, ozone contained in the air is decomposed by the action of the catalyst, and oxygen radicals are generated. The action of oxygen radicals inactivates viruses in the air, destroys cell membranes against bacteria and fungi, and eliminates odors from odorous substances by oxidative degradation. Done. Thus, the air is cleaned.

  In this case, as described above, since ozone is uniformly dispersed throughout the air taken into the inner air flow path 15, the air reaches the catalyst filter 20 with a uniform ozone concentration, and the catalyst filter 20 The catalytic action can be exerted on the entire surface.

  Then, the air thus purified passes through the heat exchanger 21 in the inner air flow path 15. Here, when passing through the heat exchanger 21, heat is exchanged with the heat medium circulated and supplied from the heat source unit 22, and the temperature of the air is adjusted to a desired temperature.

  In this way, the air that has been purified and adjusted to a desired temperature is blown into the outer air flow path 16 by the power of the fan 17, and is again supplied into the chamber 2 from the outlet 12. In this case, ozone supplied from the porous tube 25 in the vicinity of the suction port 11 is decomposed by the catalytic filter 20, so that ozone does not leak into the chamber 2 and an environment that is harmless to the human body is provided. .

  According to the air cleaning device 1 according to this embodiment, the catalytic action can be exerted on the entire surface of the catalytic filter 20, and high decomposition performance can be exhibited. Further, by simply providing the perforated tube 25 in the vicinity of the suction port 11, it is possible to simply improve the existing air cleaning device and enhance the cleaning function. In addition, it becomes unnecessary to design and manufacture a special dispersing device. In addition, what is necessary is just to set the diameter and length of the porous tube 25 according to a processing amount.

  As mentioned above, although an example of preferable embodiment of this invention was demonstrated, this invention is not limited to the form of illustration. It is obvious for those skilled in the art that various modifications or modifications can be conceived within the scope of the idea described in the claims, and these naturally belong to the technical scope of the present invention. It is understood. For example, as shown in FIG. 4, a catalyst filter 20 may be provided in the flow path downstream of the heat exchanger 21 and downstream of the discharge port of the fan 17. FIG. 4 shows an example in which the catalyst filter 20 is provided in the outer air flow path 16. By providing the catalyst filter 20 on the downstream side of the heat exchanger 21 in this way, air in which ozone is dispersed is brought into contact with the heat exchanger 21. As a result, mold growth on the cooling surface (fin coil, etc.) of the heat exchanger 21, which is often a problem during cooling, is prevented by the action of oxygen radicals generated by the reaction and decomposition of ozone with cooling surface condensation. In this case, the rate at which ozone reacts and decomposes with the dew condensation water on the cooling surface is a part of the total ozone, and most of the ozone reaches the outer air flow path 16 without being decomposed. Air cleaning by bacteria is performed.

  Moreover, although the form which provided the porous tube 25 inside the suction inlet 11 was demonstrated, the position which provides the porous tube 25 is not restricted to the inner side of the suction inlet 11, but the air taken into the inner air flow path 15 from the suction inlet 11 On the other hand, if it is a position where ozone can be released, it may be outside the suction port 11. However, when the porous tube 25 is provided outside the suction port 11, the porous tube 25 is provided at a position where most of ozone can be taken into the inner air flow path 15 from the suction port 11 by the power of the fan 17. In addition, the ozone generation mechanism 30 constituted by the discharge plasma unit 32 and the pump 33 may be provided inside the air cleaning device 1 or outside the air cleaning device 1.

  The present invention can be applied to the field of air conditioning.

It is explanatory drawing of the state which attached the air purifying apparatus concerning embodiment of this invention to the upper part of a chamber. It is explanatory drawing of the lower surface of an air purifying apparatus. It is the elements on larger scale of a perforated tube. It is explanatory drawing of the air purifying apparatus of embodiment by which the catalyst filter was provided in the downstream of the heat exchanger.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air purifier 2 Chamber 11 Suction inlet 12 Outlet 15 Inner air flow path 16 Outer air flow path 17 Fan 20 Catalytic filter 21 Heat exchanger 22 Heat source unit 25 Porous tube 26 Inside 30 Ozone generating mechanism 31 Discharge element 32 Discharge plasma unit 33 Pump 35 Ozone flow path

Claims (5)

An air cleaning device that purifies air by the action of oxygen radicals generated by passing ozone through a catalytic filter,
A suction port for taking air into the air cleaning device, and a blowout port for supplying air treated inside the air cleaning device to the room again,
Inside the air cleaning device, a catalyst filter for decomposing ozone is provided in an air flow path formed between the suction port and the blowout port,
A perforated tube is provided near the inlet,
An air purifier having an ozone generating mechanism for supplying ozone into the porous tube.   The ozone generating mechanism includes: a discharge plasma unit that generates ozone; an ozone channel that communicates the inside of the discharge plasma unit and the porous tube; and the ozone channel to the inside of the porous tube from the discharge plasma unit. It has a pump which sends ozone, The air cleaning apparatus of Claim 1 characterized by the above-mentioned.   The air purifier according to claim 1 or 2, wherein the suction port is formed in a slit shape, and the perforated tube is disposed along a longitudinal direction of the suction port.   The air cleaning apparatus according to claim 1, wherein a heat exchanger is provided in the air flow path.   The air purifier according to claim 4, wherein a catalyst filter is provided on the downstream side of the heat exchanger.

Images