JP2005233550A - Air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a restriction to the installation place for an oxygen-enriching film module when an oxygen-enriching device is assembled, as a part of an indoor unit, in an air conditioner having the oxygen-enriching device capable of enriching oxygen in a room by an oxygen-enriching film. <P>SOLUTION: This air conditioner 1 is so formed that an outdoor unit 3 having an outdoor fan 29 and an outdoor heat exchanger 24 is connected to the indoor unit 2 through refrigerant pipes 7 and comprises the oxygen-enriching film module 61 and an adsorbing fan 56 as an air supply fan. The oxygen-enriching film module 61 comprises the oxygen-enriching film 63 disposed in a casing 62 so that a space in the casing 62 can be divided into a primary side space S1 and a secondary side space S2 and allowing the oxygen in the air to be selectively permeated therethrough, and forms a part of the outdoor unit 3. The adsorbing fan 56 forms a part of the outdoor unit 3, and can supply the air into the primary side space S1 independently of air supply by the outdoor fan 29. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an air conditioner, and more particularly, to an air conditioner including an oxygen enricher capable of performing indoor oxygen enrichment.

2. Description of the Related Art Conventionally, there is an air conditioner including an oxygen enrichment device that can obtain oxygen enriched air using an oxygen enriched film. Such an air conditioner includes an outdoor refrigerant unit, an indoor unit, and a refrigerant pipe for connecting these units, and mainly performs indoor air conditioning. The oxygen enrichment apparatus is disposed outdoors, and mainly includes an oxygen enriched membrane module capable of obtaining oxygen enriched air from outdoor air, and the oxygen enriched air obtained by the oxygen enriched membrane module indoors. It is comprised from the decompression pump to supply. The oxygen enriched membrane module is mainly composed of a module casing and an oxygen enriched membrane disposed in the module casing so as to divide the space in the module casing into a primary side space and a secondary side space. Yes. The decompression pump is connected to the secondary space of the module casing. The oxygen-enriched membrane of the oxygen-enriched membrane module selectively selects oxygen in the air in the primary side space when the pressure in the secondary side space is made lower than the pressure in the primary side space by operating the decompression pump. It is a gas separation membrane that can permeate the gas and generate oxygen-enriched air in the secondary side space. The air in the primary side space of the oxygen-enriched membrane module uses airflow generated by the operation of the outdoor fan of the outdoor refrigerant unit when the oxygen enricher constitutes an outdoor unit together with the outdoor refrigerant unit. Has been replaced. In an air conditioner equipped with such an oxygen enrichment apparatus, it is possible to cool and heat the room and to enrich the room closed by the cooling and heating operation (for example, see Patent Documents 1 to 5).
Japanese Patent Laid-Open No. 3-75423 JP-A-3-217731 Japanese Patent Publication No. 7-30927 Japanese Patent Publication No. 7-109313 JP 2002-39569 A

  However, when the oxygen enrichment device forms a part of the outdoor unit together with the outdoor refrigerant unit as in the conventional oxygen enrichment device, the air flow generated by the operation of the outdoor fan of the outdoor unit is generated on the primary side. The oxygen enrichment module must be installed so that it can be introduced into the space, which will affect the installation space of the entire outdoor unit and the layout of the internal equipment, resulting in increased costs and installation. There are location constraints. Moreover, when a part of the air that has passed through the outdoor heat exchanger by the operation of the outdoor fan is introduced into the oxygen-enriched membrane module, the air heated in the outdoor heat exchanger is introduced during the cooling operation. As a result, the separation performance in the oxygen-enriched membrane is lowered.

  An object of the present invention is to provide an air conditioner equipped with an oxygen enrichment device capable of performing oxygen enrichment indoors with an oxygen enriched membrane, and when incorporating the oxygen enrichment device as a part of an outdoor unit, It is to reduce the restrictions on the location of the enrichment membrane module.

  The air conditioner according to claim 1 is an air conditioner configured by connecting an outdoor unit having an outdoor fan and an outdoor heat exchanger, and an indoor unit via a refrigerant pipe, and is oxygen-enriched. A membrane module and an air supply fan are provided. The oxygen-enriched membrane module is arranged in the casing so as to divide the casing and the space in the casing into a primary side space and a secondary side space, and oxygen that can selectively permeate oxygen in the air. And an enrichment film, which constitutes a part of the outdoor unit. The air supply fan constitutes a part of the outdoor unit, and can supply air to the primary side space separately from the outdoor fan. The air conditioner can supply oxygen-enriched air obtained by the oxygen-enriched membrane module into the room.

  In this air conditioner, air is supplied to the primary side space of the oxygen-enriched membrane module constituting a part of the outdoor unit by an air supply fan different from the outdoor fan of the outdoor unit. The arrangement restriction such as the installation of the oxygen-enriched membrane module is reduced so that the air flow generated by the operation of the outdoor fan can be introduced into the primary space, and the oxygen-enriched device is installed in the outdoor unit. It can be easily incorporated as a part.

The air conditioner according to claim 2 is the air conditioner according to claim 1, wherein the adsorbent that adsorbs moisture in the air and the moisture adsorbed by heating the adsorbent are desorbed into the air to obtain humidified air. And a humidifying device having a heating device that can perform the above-described operation. The air supply fan can supply air to the adsorbent.
The air conditioner further includes a temperature swing adsorption humidifier having an adsorbent and a heating device, and the air supply fan also has a function of supplying air to the adsorbent of the humidifier, The cost increase due to the addition of the oxygen enrichment function and the humidification function can be suppressed.

As described above, according to the present invention, the following effects can be obtained.
In the invention according to claim 1, air is supplied to the primary side space of the oxygen-enriched membrane module constituting a part of the outdoor unit by an air supply fan different from the outdoor fan of the outdoor unit. The arrangement restriction such as installing the oxygen-enriched membrane module is reduced so that the airflow generated by the operation of the outdoor fan as in the conventional system can be introduced into the primary space, and the oxygen-enriching device is installed in the outdoor unit. Can be easily incorporated as part of

  In the invention according to claim 2, since the air supply fan also has a function of supplying air to the adsorbent of the humidifier, an increase in cost due to the addition of the oxygen enrichment function and the humidification function can be suppressed. .

Hereinafter, embodiments of an air-conditioning apparatus according to the present invention will be described based on the drawings.
(1) Schematic Configuration of Air Conditioner FIG. 1 is an external view of an air conditioner 1 in which an embodiment of the present invention is adopted.
The air conditioner 1 is divided into an indoor unit 2 attached to an indoor wall surface U and the like, and an outdoor unit 3 installed outside the room. The outdoor unit 3 includes an outdoor refrigerant unit 4, a humidification unit 5 (humidification device), and an oxygen enrichment unit 6 (oxygen enrichment device). The indoor unit 2 and the outdoor unit 3 are connected to the refrigerant circuits of both units via a refrigerant pipe 7. In addition, the indoor unit 2 and the outdoor unit 3 are used when supplying heated air from the humidifying unit 5 or humidified air or oxygen-enriched air from the oxygen-enriched unit 6 to the indoor unit 2 side. Connected by. In the present embodiment, the humidification unit 5 is disposed so as to be superimposed on the upper side of the outdoor refrigerant unit 4, and the oxygen enrichment unit 6 is disposed so as to be superimposed on the upper side of the humidification unit 5. Does not become large. The air supply pipe 8 is connected to the side surface, the front surface, the back surface, and the like of the humidifying unit 5, and is connected to the indoor unit 2 through the indoor wall surface U. Here, the supply pipe 8 has a pipe diameter of about 20 mm to 30 mm.

(2) Arrangement of Equipment in Each Unit and Configuration of Refrigerant Circuit FIG. 2 is a diagram showing arrangement of each equipment in the indoor unit 2 and the outdoor unit 3 of the air conditioner 1 in which an embodiment of the present invention is adopted. It is. FIG. 3 is a schematic configuration diagram of a refrigerant circuit of the air conditioner 1, a schematic configuration diagram of the humidification unit 5, and a schematic configuration diagram of the oxygen enrichment unit 6.
The indoor unit 2 is provided with an indoor heat exchanger 11. This indoor heat exchanger 11 is a cross fin tube type heat exchanger panel composed of a heat transfer tube configured by connecting a plurality of hairpin-shaped tubes and a plurality of fins through which the heat transfer tubes are inserted. Heat is exchanged between the refrigerant that is supplied to the indoor heat exchanger 11 through the refrigerant pipe 7 and flows through the heat transfer tubes, and the air that contacts the heat transfer tubes and the fins. In the indoor unit 2, an indoor fan 12 and an indoor fan motor 13 that rotationally drives the indoor fan 12 are provided. The indoor fan 12 is a cylindrical cross-flow fan having a large number of blades on the peripheral surface, and generates an air flow in a direction intersecting the rotation axis. The indoor fan 12 sucks indoor air into the indoor unit 2 and blows out air after heat exchange with the refrigerant flowing in the heat transfer tube of the indoor heat exchanger 11 into the room. Furthermore, the pipe end of the air supply pipe 8 is inserted into the indoor unit 2 so that heated air supplied from the humidifying unit 5 or humidified air or oxygen-enriched air supplied from the oxygen-enriched unit 6 is contained in the room. After being blown out once into the unit 2, it is blown into the room by the indoor fan 12 together with the air sucked from the room.

  The outdoor refrigerant unit 4 is connected to the compressor 21, a four-way switching valve 22 connected to the discharge side of the compressor 21, an accumulator 23 connected to the suction side of the compressor 21, and the four-way switching valve 22. The outdoor heat exchanger 24 and the electric expansion valve 25 connected to the outdoor heat exchanger 24 are provided. The outdoor heat exchanger 24 is a cross fin tube type heat exchanger panel including a heat transfer tube configured by connecting a plurality of hairpin-shaped tubes and a plurality of fins through which the heat transfer tubes are inserted. It arrange | positions so that the back surface and side surface of the refrigerant | coolant unit 4 may be adjoined. The electric expansion valve 25 is connected to a liquid side communication pipe 32 via a filter 26 and a liquid closing valve 27, and is connected to one end of the indoor heat exchanger 11 via this liquid side communication pipe 32. The four-way switching valve 22 is connected to the gas side communication pipe 31 via the gas closing valve 28, and is connected to the other end of the indoor heat exchanger 11 via the gas side communication pipe 31. These communication pipes 31 and 32 correspond to the refrigerant pipe 7 in FIGS. 1 and 2. Further, in the outdoor refrigerant unit 4, in order to discharge the air after heat exchange by the outdoor heat exchanger 24 to the outside, the air is taken in from the back and side surfaces of the outdoor refrigerant unit 4 toward the front. An outdoor fan 29 that blows out is provided. The outdoor fan 29 is a propeller fan that is rotationally driven by the outdoor fan motor 30.

(3) Structure of humidifier Next, the structure inside the humidification unit 5 is demonstrated based on FIG.2 and FIG.3.
The humidification unit 5 includes a humidification unit casing located above the outdoor refrigerant unit 4, and a moisture absorption rotor 51 (adsorbent), a heater assembly 53 (heating device), a humidification fan 54, and an adsorption fan 56 are provided therein. A humidifying unit component device 50 such as (air supply fan) is disposed.

  The moisture absorption rotor 51 is a honeycomb-structured ceramic rotor having a generally disc shape, and has a structure in which air can easily pass. Specifically, the rotor has a circular shape in a plan view, and has a fine honeycomb (honeycomb) shape in a cross section cut along a horizontal plane. And the outdoor air introduce | transduced through the humidification unit air inlet flow path 60 passes through many cylinder parts of the moisture absorption rotor 51 whose cross section is polygonal. The main part of the moisture absorption rotor 51 is obtained by baking an adsorbent such as zeolite, silica gel, or alumina. This adsorbent such as zeolite has the property of adsorbing moisture in the air in contact and desorbing the adsorbed moisture when heated. The hygroscopic rotor 51 can be driven to rotate by a rotor drive motor 52.

The heater assembly 53 is disposed so as to cover one surface of the substantially half portion 51 b of the moisture absorption rotor 51. The heater assembly 53 can heat the air sucked from the outside and discharge it to the hygroscopic rotor 51 side.
The humidification fan 54 is disposed on the other surface side of the substantially half portion 51 b of the moisture absorption rotor 51 and at a position corresponding to the heater assembly 53. The humidifying fan 54 is a centrifugal fan that is rotated by a humidifying fan motor 55, and an outlet thereof is connected to the air supply pipe 8 via a humidified air supply channel 58. The humidifying fan 54 is a humidified air obtained by passing through a substantially half portion 51b of the moisture absorbing rotor 51 that has adsorbed moisture, or a heated air obtained by passing through a substantially half portion 51b of the moisture absorbing rotor 51 that has not adsorbed moisture. Is sent to the air supply pipe 8 via the humidified air supply flow path 58 and supplied to the indoor unit 2.

  The suction fan 56 is a centrifugal fan that is rotated by the suction fan motor 57 and is arranged so that outdoor air introduced through the humidification unit air inlet channel 60 can be passed through the moisture suction rotor 51. The adsorption fan 56 discharges the dehumidified air obtained by adsorbing and removing moisture when passing through the substantially half portion 51 a of the moisture absorption rotor 51 to the outside of the humidification unit casing via the dehumidification air discharge channel 59. The dehumidified air discharge channel 59 is connected to the oxygen enriched membrane module 61 of the oxygen enrichment unit 6 so that dehumidified air can be supplied. That is, the adsorption fan 56 also functions as an air supply fan for supplying air to the oxygen enrichment unit 6.

(4) Configuration of Oxygen Enriching Unit Next, the internal configuration of the oxygen enriching unit 6 will be described with reference to FIGS. Here, FIG. 4 is a schematic diagram of the oxygen-enriched membrane module 61.
The oxygen enrichment unit 6 includes an oxygen enrichment unit casing located above the humidification unit 5. The oxygen enrichment unit 6 includes an oxygen enrichment membrane module 61, a vacuum pump 65 (decompression pump), and an outlet of the vacuum pump 65. A connected oxygen-enriched air supply channel 67 and the like are arranged.

  The oxygen-enriched membrane module 61 is mainly composed of a module casing 62 and an oxygen-enriched module disposed in the module casing 62 so as to divide the space in the module casing 62 into a primary space S1 and a secondary space S2. And a chemical film 63. The oxygen-enriched film 63 has a property of easily transmitting oxygen and water in the air and not easily transmitting nitrogen, in other words, a property of selectively transmitting oxygen and water.

  In the primary side space S1, the air inlet 62a into which air supplied from the outside of the oxygen enrichment unit 6 is introduced, and the air remaining in the primary side space S1 without passing through the oxygen enrichment film 63 are contained. An air discharge port 62b to be discharged is provided. A filter 64 is disposed on the air inlet 62a side of the primary side space S1. In the present embodiment, the air inlet 62 a is connected to the outlet of the adsorption fan 56 via the dehumidified air discharge channel 59, and the air exhausted from the humidification unit 5 by the adsorption fan 56 is converted into one of the oxygen enriched film 63. It can be introduced into the secondary space S1. The air remaining in the primary space S1 without passing through the oxygen-enriched membrane is discharged from the air outlet 62b to the outside of the oxygen-enriched unit 6 through the oxygen-enriched unit air discharge channel 68. It is like that. The secondary space S2 is provided with an oxygen-enriched air discharge port 62c through which oxygen-enriched air having increased oxygen concentration through the oxygen-enriched film 63 is discharged.

  In FIG. 4, a single oxygen-enriched film 63 is arranged in the module casing 62 to form the primary side space S1 and the secondary side space S2, but this is not limitative. A plurality of primary space and secondary space are formed by disposing a plurality of oxygen-enriched membranes, such as hollow fiber membranes and plate-like membranes, in the module casing, and the primary side The spaces or the secondary spaces may be communicated with each other so as to have a functionally similar configuration as in FIG.

  The vacuum pump 65 is a pump for sucking the air in the primary side space S1 through the oxygen enriched film 63 and discharging the air in the secondary side space S2 to the oxygen enriched air supply channel 67. The vacuum pump 65 is driven by a pump motor 66, and in this embodiment, an oilless type is used so that lubricating oil is not mixed into the oxygen-enriched air. When the vacuum pump 65 is operated, a pressure difference is generated between the primary side space S1 and the secondary side space S2 in the oxygen enriched membrane module 61. Therefore, the primary side space S1 of the oxygen enriched membrane 63 is generated. Oxygen in the air introduced into the gas selectively passes through the secondary space S2 to obtain oxygen-enriched air. The oxygen-enriched air is discharged from the secondary space S2 to the oxygen-enriched air supply channel 67 by the vacuum pump 65.

  The oxygen-enriched air supply channel 67 is connected to the outlet of the vacuum pump 65 and the humidified air supply channel 58 of the humidifying unit 5. The oxygen-enriched air supply channel 67 is discharged from the oxygen-enriched membrane module 61 by the vacuum pump 65. This is a flow path for allowing the conditioned air to flow into the air supply pipe 8 via the humidified air supply flow path 58. That is, the oxygen-enriched air obtained by the oxygen-enriching unit 6 is supplied into the room via the air supply pipe 8. In the present embodiment, the oxygen-enriched air supply channel 67 is connected to allow the oxygen-enriched air to flow into the air supply pipe 8 via the humidified air supply flow path 58, but directly to the air supply pipe 8. You may come to connect.

Here, the vacuum pump 65 is disposed above the connection between the oxygen-enriched air supply channel 67 and the humidified air supply channel 58 (see FIG. 2). The oxygen-enriched air supply flow path 67 is arranged so that a portion between the outlet of the vacuum pump 65 and the connection portion with the humidified air supply flow path 58 has a downward slope toward the humidified air supply flow path 58. (See the wedge symbol W in FIG. 2).
(5) Operation | movement of an air conditioning apparatus Next, operation | movement of the air conditioning apparatus 1 is demonstrated using FIG.2 and FIG.3.

<Operation of refrigerant circuit>
First, the cooling operation will be described. During the cooling operation, the four-way switching valve 22 is in the state shown by the solid line in FIG. 2, that is, the discharge side of the compressor 21 is connected to the gas side of the outdoor heat exchanger 24, and the suction side of the compressor 21 is the outdoor heat. It is in a state connected to the gas side of the exchanger 24. Moreover, the liquid closing valve 27, the gas closing valve 28, and the electric expansion valve 25 are open.

  When the outdoor fan 29 of the outdoor refrigerant unit 4, the compressor 21, and the indoor fan 12 of the indoor unit 2 are activated in this refrigerant circuit state, the gas refrigerant is sucked into the compressor 21 and compressed, and then switched to four-way switching. It is sent to the outdoor heat exchanger 24 via the valve 22, and the outdoor air is heated and condensed. Here, outdoor air is taken into the outdoor refrigerant unit 4 from the back and side surfaces of the outdoor refrigerant unit 4 by driving the outdoor fan 29 (see arrow F1 in FIG. 2), and after crossing the outdoor heat exchanger 24, It is discharged from the front surface of the outdoor refrigerant unit 4 (see arrow F2 in FIG. 2). The condensed liquid refrigerant is decompressed by the electric expansion valve 25 and then sent to the indoor unit 2 via the liquid side communication pipe 32. Then, the liquid refrigerant sent to the indoor unit 2 is evaporated by cooling the indoor air in the indoor heat exchanger 11. Here, the indoor air is taken into the indoor unit 2 by driving the indoor fan 12 (see arrow F3 in FIG. 2), crosses the indoor heat exchanger 11, and then blown out from the indoor unit 2 into the room. (See arrow F4 in FIG. 2). The evaporated gas refrigerant is again sucked into the compressor 21 via the gas side communication pipe 31, the four-way switching valve 22 and the accumulator 23. In this way, the cooling operation is performed.

Next, the heating operation will be described. During the heating operation, the four-way switching valve 22 is in the state indicated by the broken line in FIG. 2, that is, the discharge side of the compressor 21 is connected to the gas side of the outdoor heat exchanger 24, and the suction side of the compressor 21 is the outdoor heat. It is in a state connected to the gas side of the exchanger 24. Further, the liquid closing valve 27 and the gas closing valve 28 are in an open state.
When the outdoor fan 29 of the outdoor refrigerant unit 4, the compressor 21, and the indoor fan 12 of the indoor unit 2 are activated in this refrigerant circuit state, the gas refrigerant is sucked into the compressor 21 and compressed, and then switched to four-way switching. It is sent to the indoor unit 2 via the valve 22 and the gas side communication pipe 31. The gas refrigerant sent to the indoor unit 2 is condensed by heating the indoor air in the indoor heat exchanger 11. The condensed liquid refrigerant is sent to the outdoor refrigerant unit 4 via the liquid side communication pipe 32. The liquid refrigerant sent to the outdoor refrigerant unit 4 is depressurized by the electric expansion valve 25, and is then evaporated by cooling the outdoor air by the outdoor heat exchanger 24. The evaporated gas refrigerant is again sucked into the compressor 21 via the four-way switching valve 22 and the accumulator 23. In this way, the heating operation is performed. In addition, since the flow of outdoor air and room air is the same as that at the time of cooling operation, description is abbreviate | omitted.

<Operation of humidification unit (humidification operation)>
Hereinafter, the operation of the humidification unit 5 when performing the humidification operation will be described.
The humidifying unit 5 takes outdoor air from outside into the humidifying unit casing through the humidifying unit air inlet channel 60 by rotating the suction fan 56 (see arrow F5 in FIG. 2). The air that has entered the humidifying unit casing passes through a substantially half portion 51 a of the humidifying rotor 51 and is discharged to the outside of the humidifying unit casing through the suction fan 56. At this time, the air taken into the humidifying unit casing from the outside becomes dehumidified air in which moisture contained in the air is adsorbed and removed when passing through a substantially half portion 51 a of the moisture absorption rotor 51. Yes. The dehumidified air is discharged to the outside of the humidifying unit casing through the dehumidified air discharge passage 59 (see arrow F8 in FIG. 2).

  The substantially half portion 51a of the moisture absorption rotor 51 that has adsorbed moisture in this adsorption process becomes the substantially half portion 51b on the side of the moisture absorption rotor 51 on which moisture is not adsorbed by the half rotation of the moisture absorption rotor 51. That is, the adsorbed moisture moves to a position corresponding to the heater assembly 53 and the humidifying fan 54 as the moisture absorption rotor 51 rotates. The moisture that has moved here is desorbed into the air flow generated by the humidifying fan 54 by the heat from the heater assembly 53.

  When the humidifying fan 54 is driven to rotate, air is taken into the humidifying unit casing from the outside through the humidifying unit air inlet channel 60 (see arrow F5 in FIG. 2), and the air is approximately half in which moisture is adsorbed by the hygroscopic rotor 51. Passes through the portion 51 b to the humidifying fan 54. The humidifying fan 54 sends the air that has passed through the hygroscopic rotor 51 to the indoor unit 2 via the humidified air supply channel 58 and the air supply pipe 8 (see arrows F6 and F7 in FIG. 2). The air sent out to the indoor unit 2 is humidified air containing moisture adsorbed by the hygroscopic rotor 51. In this way, the humidified air supplied from the humidifying unit 5 to the indoor unit 2 is blown out into the room.

<Operation of humidification unit (heating operation)>
Hereinafter, the operation of the humidifying unit 5 when performing the heating operation will be described.
When performing the heating operation, the humidification unit 5 operates only the heater assembly 53 and the humidification fan 54 without rotating the moisture absorption rotor 51. Specifically, the external air passes through the moisture-absorbing rotor 51 without being adsorbed without passing through the adsorption process, and the moisture is removed after the humidification operation is finished. This is performed by allowing air from the outside to pass through the hygroscopic rotor 51 and heating. The heated air obtained by such a heating operation is sent to the indoor unit 2 via the humidified air supply flow path 58 and the air supply pipe 8 by the humidifying fan 54 as in the humidifying operation (arrow F5 in FIG. 2, See F6 and F7).

<Operation of oxygen enrichment unit>
Hereinafter, the operation of the oxygen enrichment unit 6 when performing the oxygen enrichment operation will be described. The oxygen enrichment operation is performed in conjunction with the humidification operation or the heating operation of the humidification unit 5. For this reason, in the following description, it is assumed that humidified air or heated air is being sent to the indoor unit 2 via the humidified air supply channel 58 and the air supply pipe 8 by the humidifying fan 54.

  In the oxygen enrichment unit 6, the dehumidified air exhausted from the humidification unit casing by the adsorption fan 56 flows in the primary space S <b> 1 of the oxygen enriched membrane module 61 via the dehumidified air exhaust passage 59 (see FIG. The air introduced into the oxygen-enriched membrane module 61 passes through the oxygen-enriched membrane 63 and becomes oxygen-enriched air by driving the vacuum pump 65 with the arrows F8 and F11 of FIG. The oxygen-enriched air is discharged to the oxygen-enriched air supply channel 67 by the vacuum pump 65 (see arrow F10 in FIG. 2) and mixed with the heated air or humidified air flowing through the humidified air supply channel 58. It is later sent to the air supply pipe 8 and supplied to the indoor unit 2 (see arrow F7 in FIG. 2). Here, since the oxygen-enriched film 63 easily transmits moisture as well as oxygen in the air, the oxygen-enriched air flowing in the oxygen-enriched air supply channel 67 tends to contain a lot of moisture. is there. However, in the present embodiment, the oxygen-enriched air obtained by the oxygen-enriching unit 6 is mixed with the heated air or the humidified air flowing through the humidified air supply channel 58, and thus is in a state below the dew point. Thereby, dew condensation of moisture in the oxygen-enriched air from the supply pipe 8 to the room can be prevented.

  Moreover, in the air conditioner 1, the adsorption fan 56 that supplies air to the oxygen enrichment unit 6 is installed so as to supply dehumidified air obtained by adsorbing moisture in the moisture absorption rotor 51 of the humidification unit 5. Therefore, the water content in the oxygen-enriched air (see F10 in FIG. 2) obtained by the oxygen-enriching unit 6 can be reduced. Thereby, when supplying the oxygen-enriched air obtained by the oxygen-enriched unit 6 into the room, the effect of preventing moisture contained in the oxygen-enriched air from condensing in the air supply pipe 8 can be enhanced. Further, it is possible to suppress a decrease in the separation capability of the oxygen-enriched film 63 due to adhesion or dissolution of moisture to the oxygen-enriched film 63. Moreover, it contributes to the effective utilization of the dehumidified air obtained by the operation of the humidifying unit 5.

(6) Features of the air conditioner The air conditioner 1 of the present embodiment has the following features.
(A) In the air conditioner 1 of the present embodiment, the oxygen-enriched membrane module 61 that constitutes a part of the outdoor unit 3 by the adsorption fan 56 as an air supply fan different from the outdoor fan 29 of the outdoor unit 3. Since air is supplied to the primary side space S1, an oxygen-enriched membrane module is installed so that the airflow generated by the operation of the outdoor fan as in the prior art can be introduced into the primary side space. Arrangement restrictions are reduced, and the oxygen-enriched unit 6 can be easily incorporated as a part of the outdoor unit 3. For example, as in the present embodiment, the oxygen-enriched membrane module 61 can be disposed on the upper side of the humidifying unit 5.

Moreover, since the adsorption fan 56 also has a function of supplying air to the moisture absorption rotor 51 of the humidification unit 5, the increase in cost due to the incorporation of the oxygen enrichment unit 6 and the humidification unit 5 in the outdoor refrigerant unit 4 is suppressed. Can do.
Further, unlike the case where the outdoor air taken into the outdoor refrigerant unit 4 by the outdoor fan 29 is supplied to the oxygen-enriched membrane module 61, it is heated by the refrigerant flowing in the outdoor heat exchanger 24 during the cooling operation and becomes high temperature. Since it is possible to avoid the operation of introducing the air into the oxygen enrichment unit 6, it becomes possible to supply air having a relatively stable temperature to the oxygen enrichment unit 6, and the oxygen enrichment film 63. Thus, it is possible to prevent the deterioration of the separation performance and to supply oxygen-enriched air having a stable oxygen concentration into the room.

  (B) Since the air conditioning apparatus 1 of the present embodiment includes the temperature swing adsorption type humidification unit 5 including the moisture absorption rotor 51 and the heater assembly 53, heated air or humidified air can be obtained. This heated air or humidified air is guided to the outside of the humidifying unit 5 via the humidified air supply flow path 58, and enters the room from the outside of the humidifying unit 5 via the air supply pipe 8 connected to the humidified air supply flow path 58. It comes to be supplied. On the other hand, the oxygen-enriched unit 6 can obtain oxygen-enriched air from air (a part of the air blown by the outdoor fan 29 in this embodiment). This oxygen-enriched air is guided to the outside of the oxygen-enriched unit 6 via the oxygen-enriched air supply flow path 67. Here, when the operation of the oxygen enrichment unit 6 is linked to the humidification operation or the heating operation of the humidification unit 5, the oxygen enriched air supply channel 67 is connected to the humidified air supply channel 58 or the supply pipe 8. Therefore, the oxygen-enriched air containing a large amount of moisture obtained in the oxygen-enriched unit 6 is mixed with the heated air or humidified air obtained by the humidifying operation or heating operation of the humidifying unit 5 and then supplied indoors. It becomes like this.

  As a result, the oxygen-enriched air is mixed with the heated air or humidified air and becomes a state below the dew point. Therefore, when supplying the oxygen-enriched air obtained by the oxygen-enriched unit 6 into the room, the air supply pipe Condensation of moisture contained in the oxygen-enriched air in 8 can be prevented. For this reason, it is not necessary to install a drain unit such as a drain trap in the oxygen-enriched air supply channel 67 or the supply pipe 8. Moreover, since humidification and oxygen enrichment can be performed at the same time in the room, the humidity and oxygen concentration of room air that has been cut off by air conditioning can be maintained in a comfortable state.

  Moreover, in the air conditioner 1, the adsorption fan 56 that supplies air to the oxygen enrichment unit 6 is installed so as to supply dehumidified air obtained by adsorbing moisture in the moisture absorption rotor 51 of the humidification unit 5. Therefore, the water content in the oxygen-enriched air (see F10 in FIG. 2) obtained by the oxygen-enriching unit 6 can be reduced. Thereby, when supplying the oxygen-enriched air obtained by the oxygen-enriched unit 6 into the room, the effect of preventing moisture contained in the oxygen-enriched air from condensing in the air supply pipe 8 can be enhanced. Further, it is possible to suppress a decrease in the separation capability of the oxygen-enriched film 63 due to adhesion or dissolution of moisture to the oxygen-enriched film 63. Moreover, it contributes to the effective utilization of the dehumidified air obtained by the operation of the humidifying unit 5.

  (C) In the air conditioner 1 of this embodiment, the oxygen-enriched air supply pipe provided for supplying oxygen-enriched air into the room in the air conditioner having the conventional oxygen-enriching unit is omitted. Thus, the oxygen-enriched air can be supplied through the air supply pipe 8 for supplying the heated air or the humidified air obtained by the humidifying unit 5 into the room. The air supply pipe 8 has a pipe diameter several times larger than that of the conventional oxygen-enriched air supply pipe (for example, if the pipe diameter of the conventional oxygen-enriched air supply pipe is 6 mm and the pipe diameter of the air supply pipe 8 is 25 mm) It is possible to make it difficult for fluid sound when oxygen-enriched air is blown into the room.

  Thereby, it is possible to prevent the user in the room from feeling uncomfortable without installing a silencer. Further, by operating the oxygen enrichment unit 6 in conjunction with the heating operation or humidification operation of the humidification unit 5, a relatively small flow rate of oxygen enriched air can be accompanied by a large flow rate of heated air or humidified air. Therefore, the oxygen-enriched air can be stably supplied into the room.

  (D) In the air conditioner 1 of the present embodiment, the oxygen enrichment obtained by sucking the air supplied to the oxygen enrichment unit 6 through the oxygen enrichment film 63 and passing through the oxygen enrichment film 63. A vacuum pump 65 is used as a device for discharging the crystallization air into the oxygen-enriched air supply channel 67. With such a configuration, moisture in the oxygen-enriched air may be condensed in a portion of the oxygen-enriched air supply flow channel 67 on the downstream side of the vacuum pump 65. For this reason, when dew condensation occurs in the portion between the outlet of the vacuum pump 65 and the connection portion of the oxygen-enriched air supply flow channel 67 with the humidified air supply flow channel 58, the condensed water flows back to the vacuum pump 65. There is a fear.

  However, in this air conditioner 1, the vacuum pump 65 is disposed above the connection portion between the oxygen-enriched air supply flow path 67 and the humidified air supply flow path 58, so that oxygen is discharged from the outlet of the vacuum pump 65. It is possible to prevent the condensed moisture from flowing back to the vacuum pump 65 in the portion between the enriched air supply channel 67 and the connection portion with the humidified air supply channel 58. If the oxygen-enriched air supply flow path 67 is directly connected to the air supply pipe 8 as a box with this embodiment, the vacuum pump 65 is connected to the humidified air supply flow path 58 and the air supply pipe 8 through the connecting portion. If it is arranged on the upper side, the same effect as in the present embodiment can be obtained.

Further, since the oxygen-enriched air supply channel 67 is installed so as to be inclined downward from the outlet of the vacuum pump 65 toward the connection portion with the humidified air supply channel 58, the condensed moisture is oxygen-enriched. It is possible to prevent the air supply channel 67 from accumulating.
(7) Other Embodiments While the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments and can be changed without departing from the scope of the invention. It is.

(A) In the above embodiment, the humidification unit and the oxygen enrichment unit are arranged in a stack on the upper side of the outdoor refrigerant unit. However, the arrangement is not limited to this arrangement. For example, on the upper side of the outdoor refrigerant unit. Both units may be arranged side by side.
(B) In the above embodiment, all the dehumidified air is supplied to the oxygen enrichment unit, but only a part of the dehumidified air is supplied to the oxygen enrichment unit, and the remaining dehumidified air is discharged to the outside. It may be.

  (C) In the above embodiment, air is supplied to the primary side space of the oxygen-enriched membrane module using the adsorption fan of the humidification unit. However, if there is no humidification unit, the oxygen-enrichment unit A fan other than the outdoor fan may be provided inside.

  By utilizing the present invention, in an air conditioner equipped with an oxygen enrichment device capable of performing oxygen enrichment indoors with an oxygen enrichment membrane, when incorporating the oxygen enrichment device as part of an outdoor unit, Restrictions on the installation location of the oxygen-enriched membrane module can be reduced.

1 is an external view of an air conditioner in which an embodiment of the present invention is adopted. It is a figure which shows arrangement | positioning of each apparatus in the indoor unit of the air conditioning apparatus by which one Embodiment of this invention was employ | adopted, and the outdoor unit. It is the schematic block diagram of the refrigerant circuit of the air conditioning apparatus by which one Embodiment of this invention was employ | adopted, the schematic block diagram of a humidification unit, and the schematic block diagram of an oxygen enrichment unit. It is a schematic diagram of an oxygen-enriched membrane module.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus 2 Indoor unit 3 Outdoor unit 5 Humidification unit (humidification apparatus)
6 Oxygen enrichment unit (oxygen enrichment device)
7 Refrigerant piping 24 Outdoor heat exchanger 29 Outdoor fan 51 Hygroscopic rotor (adsorbent)
53 Heater assembly (heating device)
56 Suction fan (supply fan)
61 Oxygen-rich membrane module 62 Module casing (casing)
63 Oxygen-enriched film S1 Primary space S2 Secondary space

Claims (2)

An air conditioner configured by connecting an outdoor unit (3) having an outdoor fan (29) and an outdoor heat exchanger (24) and an indoor unit (2) via a refrigerant pipe (7). ,
The casing (62) and the space in the casing are disposed in the casing so as to divide the space in the casing into a primary space (S1) and a secondary space (S2), and selectively transmit oxygen in the air. An oxygen-enriched membrane (63) capable of, and an oxygen-enriched membrane module (61) constituting a part of the outdoor unit;
A part of the outdoor unit is provided, and an air supply fan (56) capable of supplying air to the primary side space separately from the outdoor fan,
It is possible to supply oxygen-enriched air obtained by the oxygen-enriched membrane module indoors.
Air conditioner (1). Humidification having an adsorbent (51) for adsorbing moisture in the air and a heating device (53) capable of desorbing moisture adsorbed by heating the adsorbent into the air to obtain humidified air Further comprising a device (5) as part of the outdoor unit (3),
The air supply fan (56) is capable of supplying air to the adsorbent.
The air conditioner (1) according to claim 1.

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