JP2008075922A - Humidity-conditioning cooling/heating device and spatial structure using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To achieve high humidity conditioning effect while performing indoor air cooling or heating, and to dispose of dew condensation water generated on a cooled/heated part during cooling. <P>SOLUTION: A heat source body10 10 and a humidity conditioning body 11 are arranged in parallel with each other through an air layer 12, and a water discharge portion 14 is formed to discharge the dew condensation water generated in the air layer 12. The inside of a room is heated/cooled by the heat source body 10 through the air layer 12 and the indoor-side humidity conditioning body 11, and a comfortable indoor humidity can be kept by the indoor-side humidity conditioning body 11. Further the dew condensation water generated on the heat source body 10 faced to the air layer 12 in cooling, is discharged to the external through the water discharging portion 14. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a humidity control air conditioner installed on an indoor wall and a space structure using the same.

  Conventionally, as a means for cooling or heating a room, an air conditioner and a fan heater are generally well known and widely used, but a radiant type air conditioner is also known.

  The former air conditioner or fan heater adjusts the room temperature by changing the indoor air into cold air or hot air and sends it into the room. (Especially warm air) may directly hit the human body, which is a major cause of discomfort. In addition, unpleasant sensations are caused by the loud sound of wind blowing, which is annoying, and the temperature in the room is uneven. Further, when the cooling and dehumidifying operation is performed with an air conditioner or the like, there is a problem that it is difficult to stably maintain an appropriate humidity such that excessive dehumidification occurs during the operation and the humidity increases excessively after the operation is stopped. In addition, during heating operation, it is not possible to alleviate over-drying of humidity, and a humidifying means is required.

  On the other hand, the radiant air conditioner has the advantage that the indoor air is warmed by far infrared rays rather than air current, so there is no sound of wind and there is no uncomfortable feeling when the hot air directly hits the human body.

  However, in the radiant air conditioner, since the cooling and heating part is exposed in the room, it is necessary to treat the condensed water generated in the cooling and heating part during cooling.

  As a means for treating this condensed water with a humidity control material, conventionally, as disclosed in Patent Document 1, a heat generating film (heater) that generates heat by energization is provided on the back surface of the humidity control material, and the heat control film is adjusted by energization. It has been proposed to heat the damp material and release the dampness into the room, while stopping the heating of the dampening material by stopping the energization of the heat generation film, and to absorb the dampness in the room.

  Moreover, in what is shown by patent document 2, a Peltier device is attached to the back surface of a humidity control material, and a humidity control material is heated or cooled by this Peltier device.

On the other hand, in recent residences, heat insulation and airtightness have been achieved, and the performance of heating equipment has been improved, the use of interior materials with low humidity control, the introduction of outside air due to the mandatory use of ventilation equipment, etc. Humidity decreases and the indoors in winter are becoming dry. As means for humidifying the interior of this winter season, conventionally, as disclosed in Patent Document 3, a humidity supply means is provided on the back side of the humidity conditioner whose surface faces the room, and a humidity control material containing this humidity is provided. It has been proposed to humidify a room by heating with a heating element provided integrally with the humidity control material.
Japanese Utility Model Publication No. 2-8529 JP-A-8-278046 Japanese Patent No. 3606815

  However, in the above-mentioned conventional Patent Document 1, since the temperature difference between the humidity conditioner and the room is small (the humidity conditioner is not cooled) just by stopping the heating of the humidity conditioner by the heat generation film, the conditioner is not cooled. There is a problem that the humidity control effect of the wet material is low.

  Moreover, in the thing of the patent document 2, since the cooling surface of the Peltier element is in direct contact with the humidity control material, there is a high risk that the humidity control material is condensed. Since it has the property of generating heat, it needs to be exhausted.

  Furthermore, in the thing of patent document 3, since the heat generating body is provided in the back surface of the humidity control material, the moisture absorption area of a humidity control material reduces by the part of the heat generating body, and the moisture discharge | released from a moisture supply means is reduced. There is a problem that the humidity control material cannot absorb moisture sufficiently and its efficiency is poor. Moreover, the thing of patent document 3 is a system which only adjusts indoor humidity, Comprising: The use of heating is not considered. In addition, since there is no cooling section, there is a problem that the dehumidifying ability is low only in the summer when dehumidification is performed only with the humidity control material.

  The present invention has been made in view of such various points, and the main purpose thereof is to devise the structure of the humidity control air conditioner, so that a high humidity control effect can be obtained at the same time as performing indoor cooling or heating, In addition, it is to be able to treat the dew condensation water generated in the cooling and heating part during cooling.

  In order to achieve the above object, in the present invention, an air layer connected to the drainage portion is formed between the heat source body and the humidity control body, and condensed water is generated in the air layer.

  Specifically, the invention of claim 1 is a humidity control air conditioner that is installed on a wall of a room and that cools or heats the room while humidity is controlled, and is located on the outside of the room. A heat source body (cooling / heating body) that generates air and a humidity control body that is located indoors and humidity-controls the air are arranged in parallel with an air layer interposed therebetween, and condensation formed in the air layer A drainage unit for discharging water is provided.

  According to the first aspect of the present invention, the humidity control air conditioner is installed such that the heat source body is located on the outdoor side and the humidity control body is located on the indoor side in the wall portion of the building. The room can be heated and cooled via the air layer and the humidity controller on the indoor side. The indoor humidity is adjusted by the humidity control body on the indoor side. Therefore, cooling and dehumidification (moisture absorption) can be performed by the cooling operation of the heat source body in summer, and heating and humidification (humidification) can be performed by the heating operation of the heat source body in winter.

  And since the air layer is provided between the humidity control body and the heat source body, even if the heat source body generates cold (cold) during cooling operation, no condensation occurs on the humidity control body, and the dew condensation is air Since it is generated on the heat source body in the bed and the condensed water is discharged to the outside through the drainage portion, the indoor interior material and the structural housing are not wetted. Moreover, the indoor humidity control body can keep the indoor humidity comfortable not only during cooling and heating operations but also when the operation is stopped.

  In addition, even if the air conditioning operation of the humidity control air conditioner is stopped, the humidity control body itself is cooled by that time, so the temperature difference between the room and the humidity control body is kept large, and the humidity control of the humidity control body The effect can be enhanced.

  According to a second aspect of the present invention, the heat source body includes a circulation passage through which cold water or hot water made by a chiller / heater flows, and a radiating panel unit that radiates cold heat or cold heat from the cold water flowing through the circulation passage. It is characterized by being.

  According to the second aspect of the present invention, the heat source body is made of a chiller / heater and radiates cold heat from the cold water flowing through the circulation passage or warm heat from the hot water at the panel portion. There is no need to provide.

  The invention according to claim 3 is characterized by comprising a moisture supply means for supplying moisture from the air layer side (back surface) to the humidity control body when the heat source body generates heat.

  According to the third aspect of the present invention, when the heat of the heat source body is generated, the moisture supply means is operated to supply the moisture, and this humidity is absorbed into the humidity control body from the air layer side (back side), and the humidity control body To the indoor side is released as moist warm air. This can prevent indoor drying.

  In addition, when the heat source stops generating heat, even if the indoor temperature decreases and the relative humidity increases, the excess humidity is absorbed by the humidity control body, and the heat source body is turned ON / OFF. A comfortable humidity state can be maintained regardless of switching.

  Invention of Claim 4 is invention which concerns on a space structure, The humidity control air conditioning apparatus of any one of the said Claims 1-3 is installed in at least 1 of the several wall part of a room, and another wall part or ceiling A humidity control material is applied to at least one of the indoor surfaces.

  In this invention, the humidity control air conditioner is installed in at least one of the plurality of wall portions of the room, and the humidity control material is applied to at least one indoor surface of the other wall portion or ceiling. Due to the humidity control action of the wet material, the room can be maintained in a comfortable humidity range even during the time when the humidity control air conditioner is stopped.

  As described above, according to the humidity control air conditioner of the invention of claim 1, the heat source body and the humidity control body are juxtaposed on the wall portion of the room through the air layer, and the dew condensation water generated in the air layer By providing a drainage section that discharges air, the heat source body can heat and cool the room through the air layer and the humidity controller on the indoor side to cool and cool the room, and also on the heat source body facing the air layer during cooling Condensed water that has condensed in this way can be discharged to the outside through the drainage section to prevent the interior materials and structural enclosures from getting wet, and the indoor humidity control body can keep indoor humidity comfortable. be able to.

  According to invention of Claim 2, the heat source body shall be provided with the circulation path through which the cold water or warm water made with the water cooler / heater flows, and the panel part which radiates the cold heat of this cold water or the warm water temperature. Thus, cold heat or warm heat can be generated without requiring exhaust heat means like a Peltier element.

  According to the invention of claim 3, when the heat source body is heated, the moisture supply means for supplying moisture from the air layer side to the humidity control body is provided, so that the moisture source is supplied from the moisture source means when the heat source body is heated. The humidity can be absorbed by the humidity control body from the air layer side (rear side) and released from the humidity control body to the indoor side as humid warm air, while the temperature of the room decreases when the heat source heat generation stops. Even if the relative humidity increases, the excess humidity can be absorbed by the humidity control body, and a comfortable humidity state can be maintained regardless of ON / OFF switching of the heat source body.

  According to the spatial structure of the invention of claim 4, the humidity control air conditioner is installed on at least one of the plurality of wall portions of the room, and the humidity control material is applied to at least one indoor surface of the other wall portion or ceiling. Thereby, even in the time zone when the humidity control air conditioner is stopped, the space can be maintained in a comfortable humidity range.

  Hereinafter, the best embodiment of the present invention will be described in detail with reference to the drawings. The following description of the preferred embodiments is merely exemplary in nature and is in no way intended to limit the invention, its application, or its application.

(Embodiment 1)
In FIG. 2, 1 is a room provided in a building such as a house, and this room 1 has a floor 2, a plurality of wall portions 3, 3,... (The front wall portion is not shown in FIG. 2) and Surrounded by a ceiling 4. Among the four wall portions 3, 3,..., Inside the one wall portion 3 on the left side in FIG. It is installed in an embedded state, and the humidity control air conditioner A cools or heats the interior of the room 1 from the wall portion 3 where the humidity control air conditioner A is located.

  As shown in FIG. 1, the humidity control air conditioner A includes a heat source body 10 (cooling / heating body) installed on the outdoor side and a humidity control body 11 installed on the indoor side. While the heat source body 10 is panel-shaped, the humidity control body 11 is plate-shaped, both are arranged in parallel with each other, and an air layer 12 is interposed between the heat source body 10 and the humidity control body 11. It is installed.

The heat source body 10 is, for example, a use-side heat exchanger of a heat pump type air conditioner that generates cold (cold) or warm heat by circulating a refrigerant such as Freon, CO ₂ (carbon dioxide gas), or ammonia gas in a refrigerant circuit. Etc., and generates heat during the cooling operation of the humidity control air conditioner A, and generates heat during the heating operation. During the cooling operation, the room is cooled by the cold generated by the heat source body 10 via the air layer 12 and the humidity control body 11, while during the heating operation, the air layer 12 and the humidity control body 11 are heated by the heat generated by the heat source body 10. The interior of the room is heated.

  On the other hand, the humidity control body 11 is for controlling the air inside the chamber 1. For example, a volcanic vitreous multilayer board having a plurality of fine holes (trade name “Sarari” manufactured by Daiken Kogyo Co., Ltd.). A "etc.) is preferably used. The humidity control body 11 only needs to have a function of absorbing and releasing humidity with respect to the air in the chamber 1 and the air layer 12, and the material thereof is rock wool board, gypsum board, calcium silicate, slag gypsum board, dielite (large In addition to the wood fiber board, there are those made by adding clay minerals and porous materials to the face material to give humidity conditioning and breathing performance, clay mineral fired boards, etc. There is no particular limitation.

  The humidity control body 11 constitutes a wall surface inside the chamber 1 and may have a design property such as attaching a decorative sheet or paper to the surface.

  The thickness of the air layer 12 (the distance between the indoor side surface of the heat source body 10 and the outdoor side surface of the humidity control body 11) is that dew condensation water generated in the air layer 12 of the humidity control air conditioner A contacts the humidity control body 11. Without being particularly limited, it is preferably about 3 to 300 mm.

  The lower end portion of the air layer 12 communicates with the drainage portion 14. The drainage part 14 is disposed on the lower side of the air layer 12 (between the heat source body 10 and the humidity control body 11) and has a bottomed drainage pan 15 that opens upward (air layer 12 side), and the drainage pan 15 The drainage pipe 16 is connected to the drainage port 15a at the bottom and extends to the outside of the room. The drainage part 14 allows the condensed water generated in the air layer 12 during the cooling operation of the humidity control air conditioner A to flow into the drainage pan 15. In this case, the water is discharged through the water distribution pipe 16.

  Therefore, in this embodiment, when the room is cooled, the humidity control air conditioner A is cooled. During this cooling operation, the heat source body 10 on the outdoor side is in a cooling state that generates cold (cold), and the cold heat from the heat source body 10 enters the inside of the chamber 1 through the air layer 12 and the humidity control body 11 on the indoor side. It is transmitted and the room is cooled. On the other hand, when the room is heated, the humidity control air conditioner A is heated. During this heating operation, the heat source body 10 enters a heating state in which heat is generated, and the heat from the heat source body 10 is transmitted to the inside of the room 1 through the air layer 12 and the humidity control body 11 to heat the room. And the indoor humidity is adjusted by the humidity control body 11 on the indoor side. Thus, indoor cooling and dehumidification (moisture absorption) can be performed in summer, and heating and humidification (humidification) can be performed in winter.

  At that time, since air conditioning is performed without using wind, such as an air conditioner or a fan heater, there is no discomfort or noise caused by direct air hitting the human body. In addition, since the room is cooled and heated by substantially the entire wall 3, the temperature distribution in the room can be formed in a uniform temperature distribution from the floor 2 to the ceiling 4.

  Furthermore, since the humidity control air conditioner A is installed in a state where a part of the air conditioner is embedded in the wall portion 3, unlike a case where the air conditioner protrudes from the wall surface or the floor surface, a flat wall surface can be maintained. Good design.

  Further, since the air layer 12 is provided between the humidity control body 11 and the heat source body 10, dew condensation occurs in the humidity control body 11 when the heat source body 10 is in a cooling state during the cooling operation of the humidity control air conditioner A. No condensation occurs on the heat source body 10 in the wall 3 (in the air layer 12). And since this dew condensation water is discharged | emitted through the drain pan 15 and the water distribution pipe 16 of the drainage part 14, it does not wet the interior material and structure of a building.

  Moreover, since the humidity control body 11 is provided with the humidity control body 11, the humidity control air conditioner A is operated from the state where the humidity control air conditioner A is operated to cool or heat the room. Even when the operation of A is switched to the stopped state, the humidity adjustment body 11 can suppress fluctuations in the indoor humidity, and the indoor space can be kept comfortable.

  In addition, even if the operation of the humidity control air conditioner A is stopped, the humidity control body 11 itself is cooled during the cooling operation. Therefore, the humidity control body 11 is caused by a large temperature difference between the humidity control body 11 and the room. Can improve the humidity control effect.

(Embodiment 2)
3 and 4 show Embodiment 2 of the present invention (in the following embodiments, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals and detailed description thereof is omitted), and the heat source The configuration of the body 10 is changed.

  That is, in this embodiment, the heat source body 10 includes a circulation pipe 20 in which a circulation passage 19 is formed and radiation panels 21 and 22. As shown in FIG. 4, the circulation pipe 20 is bent in a meandering shape so as to have a plurality of straight portions 20 a, 20 a,... Extending in parallel in the vertical direction (or in the horizontal direction). Both ends are connected to an outdoor electric or gas chiller / heater 24 that cools water to generate cold water or heats water to generate hot water via connection pipes 25a and 25b on the supply side and discharge side. It is connected, and the cold water or the hot water made by the cold / hot water device 24 is circulated in the circulation passage 19 inside the circulation pipe 20 and flows.

  An indoor radiant panel portion 21 is disposed on the indoor side of the circulation pipe 20, and an outdoor radiant panel portion 22 is disposed on the outdoor side. The circulation pipe 20 is sandwiched between the two panel portions 21 and 22 so as to be integrated. It is fixed to the joint. Both panel parts 21 and 22 are made of, for example, a material having high heat conductivity. The outdoor radiant panel part 22 has a heat insulating layer on the outdoor side and a heat transfer layer such as metal on the indoor side surface. Therefore, the heat of cold water or hot water flowing through the circulation passage 19 in the circulation pipe 20 is radiated toward the indoor side (the humidity control body 11 side) by the two panel portions 21 and 22. Other configurations are the same as those of the first embodiment.

  Therefore, also in this embodiment, the same operational effects as those of the first embodiment can be obtained. In particular, in the case of the second embodiment, the cold source or hot temperature generating means of the heat source body 10 generates heat from the cold water or hot water generated by the cold water heater 24 and flowing through the circulation passage 19 in the circulation pipe 20. Therefore, there is an advantage that it is not necessary to provide heat exhausting means unlike the Peltier element.

(Embodiment 3)
5 to 8 show the third embodiment. In the second embodiment, the circulation pipe 20 having the circulation passage 19 formed therein is disposed between the radiation panel portions 21 and 22, whereas the radiation panel portion. A circulation passage 19 is defined in the space between 21 and 22.

  That is, in this embodiment, as shown in FIGS. 5 and 6, the heat source body 10 is provided with an outdoor heat insulating panel 26 at the outdoor end position. The outdoor heat insulating panel 26 is not particularly limited as long as it has heat insulating properties such as an extruded polystyrene foam heat insulating plate, polyethylene foam, hard urethane foam heat insulating plate, phenol foam heat insulating plate, and the like.

  A concave portion 23 is formed in the middle portion of the indoor side surface of the outdoor heat insulating panel portion 26 so that the indoor side surface is partially rectangular and opened downward. In this recessed portion 23, a thin rectangular box-shaped outdoor radiant panel portion 22 formed substantially in the same recessed shape as the recessed portion 23 is accommodated in a fitted state with the opening facing the indoor side. The opening to the indoor side of the outdoor radiant panel unit 22 is covered with the indoor radiant panel unit 21 and closed in a liquid-tight manner, and the outdoor radiant panel unit 22 and the indoor radiant panel unit 21 are integrated. A closed space with a small thickness is formed in both.

  The indoor radiant panel portion 21 and the outdoor radiant panel portion 22 are both made of a thin plate having heat conductivity such as metal, and the vertical direction is formed on the outdoor side surface (back surface) of the intermediate portion of the indoor radiant panel portion 21. A plurality of vertical partition walls 21a, 21a,... Extending in parallel to each other are projected in the horizontal direction with an interval. The interval between the vertical partition walls 21a and 21a and the interval between the vertical partition wall 21a located at the left end in FIG. 6 and the side wall surface at the left end in FIG. 6 in the outdoor radiation panel 22 are substantially the same. The distance between the vertical partition wall 21a located at the right and the side wall surface at the right end of FIG. 6 in the outdoor radiation panel 22 is larger than the distance between the vertical partition walls 21a and 21a.

  As shown in an enlarged view in FIG. 8, each vertical partition wall 21a has a bent structure in which a part of a plate is bent so as to protrude to the outdoor side, and its distal end (outdoor end) is an outdoor radiant panel. Are in contact with or bonded to the portion 22, and the vertical barrier ribs 21 a, 21 a,... Have a plurality of vertically long spaces closed by the outdoor radiating panel portion 22 and the indoor radiating panel portion 21 in the recessed portion 23. It is divided into spaces.

  The upper wall surface of the recessed portion 23, and hence the upper wall portion of the outdoor radiating panel portion 22 in the recessed portion 23, is inclined so as to increase from the right side to the left side in FIG. Further, the upper end portions of the vertical partition walls 21a, 21a,... Are all arranged at positions spaced apart from the upper wall portion (the upper wall surface of the recessed portion 23) of the outdoor radiation panel 22 by a certain distance. Yes. On the other hand, the lower end portions of the other vertical partition walls 21a, 21a,... Except for the vertical partition wall 21a at the right end in FIG. 6 are all arranged at a position spaced upward from the lower wall portion of the outdoor radiation panel 22. And the upper wall of the outdoor radiant panel portion 22 is such that the straight lines connecting the upper end portions and the lower end portions of the vertical partition walls 21a, 21a,... It inclines in parallel with the part (upper wall surface of the recessed part 23). Further, the lower end portion of the vertical partition wall 21a at the right end in FIG. 6 extends so as to abut on the lower side wall portion of the outdoor side radiation panel portion 22.

  Furthermore, the lower part of the indoor radiating panel 21 extends from the lower part of the vertical partition wall 21a at the right end of FIG. 6 to the left side wall surface of the outdoor radiant panel part 22 in FIG. A horizontal partition wall 21b extending obliquely so as to be continuous between the lower end portions of the vertical partition walls 21a, 21a,... Is formed with the same folding structure as each vertical partition wall 21a.

  Further, the horizontal partition wall 21b has a position between adjacent vertical partition walls 21a and 21a, and a position between the vertical partition wall 21a at the left end of FIG. 6 and the side wall surface on the left side of FIG. A hole-shaped communication path 19e, 19e,... Is formed by partially eliminating the bent structure, and the space above and below the horizontal partition wall 21b communicates with each other through the communication paths 19e.

  The closed space formed by the indoor radiating panel portion 21 and the outdoor radiating panel portion 22 by the vertical partition walls 21a, 21a,... And the horizontal partition wall 21b is between the vertical partition walls 21a, 21a and the left side of FIG. Of the vertical partition wall 21a and the outdoor radiant panel portion 22 in FIG. 6 and the right side vertical wall 21a and the outdoor radiant panel portion 22 at the right end of FIG. 6 is located between the right side wall surface and is wider than the ascending passage 19a, and is located at the upper end of the space and the downstream end (upper end) of the ascending passages 19a, 19a,. An upper collecting passage 19c that communicates with the upstream end (upper end) of 19b, and is surrounded by a horizontal partition wall 21b and a vertical partition wall 21a at the right end of FIG. Up Are partitioned and formed on the lower manifolds 19d which communicates through a communication passage 19e, the circulation passage 19 is constituted by these passages 19a~19d and the communication passage 19e.

  Further, at the lower part of the indoor side radiating panel portion 21, a supply side connection pipe 25a that communicates with the lower collecting passage 19d at a site on the right side of FIG. 6 and a discharge that communicates with the downstream end (lower end) of the descending passage 19b. The side connection pipe 25b is inserted. These connection pipes 25a and 25b penetrate the drain pan 15 in a liquid-tight manner and are connected to the chiller / heater 24. The chilled water or hot water produced by the chiller / heater 24 is connected to the connection pipes 25a and 25b. Through the circulation passage 19 in the recess 23. Specifically, chilled water or hot water from the chiller / heater 24 is supplied to the lower collecting passage 19d of the circulation passage 19 via the supply-side connecting pipe 25a, and each communication passage 19e is connected to the lower collecting passage 19d. To the ascending passages 19a to raise the ascending passages 19a, collect them from the downstream end (upper end) to the upper collecting passages 19c, and then supply them to the descending passages 19b to lower the descending passages 19b. Circulation is performed such that the downstream end (lower end) of the passage 19b is returned to the chiller / heater 24 via the connection pipe 25b on the discharge side, and the heat of the chilled water or hot water flowing through the circulation passage 19 is supplied to both panel portions 21 and 22 (mainly Radiation is performed toward the indoor side (the humidity control body 11 side) by the indoor side radiation panel portion 21). Other configurations are the same as those of the second embodiment (see FIGS. 3 and 4).

  Therefore, also in this embodiment, the same operational effects as those of the second embodiment can be achieved. In particular, in the case of this embodiment, the heat source body 10 is formed by integrating the radiating panel portions 21 and 22 made of thin plate materials, and the circulation passage 19 is formed in the space covered with the radiating panel portions 21 and 22. Therefore, compared to the second embodiment, there is an advantage that the processing of the heat source body 10 at the factory can be easily performed.

  In the third embodiment, the vertical partition wall 21a and the horizontal partition wall 21b of the indoor side radiating panel portion 21 are formed by a ridge-shaped bent structure, but instead, formed by a structure such as a rib, 19e may be formed by a hole. Further, the circulation passage 19 formed inside the outdoor radiant panel portion 22 by the indoor radiant panel portion 21 is not limited to the above layout, and an appropriate layout can be adopted.

(Embodiment 4)
FIG. 9 shows Embodiment 4 in which moisture is supplied to the air layer 12. That is, in this embodiment, in the configuration of the third embodiment (see FIGS. 5 to 8), a humidifier 28 as a moisture supply means is provided at the lower end portion of the air layer 12 (opening of the drain pan 15). Yes. The humidifier 28 (humidity supply means) is operated in conjunction with the humidity control air conditioner A in which the heat source 10 generates heat, and is operated in conjunction therewith. The humidifier 28 (humidity supply means) By humidifying the air in the air layer 12, the humidity is supplied to the humidity control body 11 from the air layer 12 side (back side). The other configuration is the same as that of the third embodiment.

  Therefore, in the case of this embodiment, when the heat source 10 generates heat during the heating operation of the humidity control air conditioner A, moisture is supplied from the humidifier 28 (humidity supply means) to the air layer 12. This moisture is absorbed by the humidity control body 11 from the air layer 12 side (back side) and is released from the humidity control body 11 as warm warm air to the indoor side. This can prevent indoor drying. On the other hand, when the generation of warm heat in the heat source body 10 is stopped and the indoor temperature is lowered, and the indoor relative humidity is increased accordingly, the excess humidity is absorbed by the humidity control body 11. That is, a comfortable humidity state can be maintained regardless of ON / OFF switching of the heat source body 10 during the heating operation of the humidity control air conditioner A.

  Further, when the heat source body 10 generates heat, the air in the air layer 12 is heated by the heat source body 10 to generate an updraft, and the humidifier 28 (humidity supply means) is disposed at the lower end of the air layer 12. Therefore, the humidity from the humidifier 28 (humidity supply means) is supplied to the air of the air layer 12 at the lower end and then rises on the rising airflow, so that the entire humidity control body 11 can absorb moisture efficiently. be able to.

  In addition, the said moisture supply means can replace with the humidifier 28, and can use the apparatus which discharge | releases water in the shape of a mist, the container containing water (thing which evaporates the water in this container naturally), etc., What is necessary is just to be able to supply moisture to the humidity control body 11 from the back side.

  Further, the humidifier 28 (humidity supply means) can be provided at a position other than the lower end of the air layer 12, but as described above, the humidifier 28 can efficiently absorb moisture in the whole air conditioning body 11. It is preferable to provide the lower end portion of the layer 12.

  Further, moisture supply means such as the humidifier 28 having the configuration of the third embodiment may be provided in the configuration of the first or second embodiment, and the same effect can be obtained.

(Embodiment 5)
FIG. 10 shows a fifth embodiment in which a humidity control material is applied. That is, in this embodiment, as in the first embodiment, the humidity conditioning air conditioner A is partially embedded in the left wall 3 of the plurality of walls 3, 3,. The humidity control air conditioner A cools or heats the room from the wall 3.

  And the humidity control material 30 (it attaches | subjects a dot and shows in a figure) is constructed in the indoor side surface of the remaining wall part 3,3, .... The surface makeup of the humidity control material 30 is applied in the same manner as the surface makeup of the humidity control body 11 in the humidity control air conditioner A, and the wall portions 3, 3,. The interior finish with the wall 3 of the humidity control body 11 is also used.

The humidity control material 30 is a moisture absorption / release moisture in the middle humidity range of “JIS A 1470-1 (Hygroscopic building material moisture absorption / release test method-Part 1: Humidity response method / Moisture absorption / release test method)”. It has a performance of 29 g / m ² · 12 h or more, and has a moisture permeability resistance of 1.50 × 10 ⁻³ m ² measured by a measurement method defined in “JIS A 1324 (Method for measuring moisture permeability of building materials)”. What is spA / ng or less is preferable. Other configurations are the same as those of the first embodiment.

  Therefore, in this embodiment, the humidity control air conditioner A is installed in one of the plurality of wall portions 3, 3,... In the room, and the humidity control material 30 is applied to the other wall portions 3, 3,. Therefore, even in the time zone when the operation of the humidity control air conditioner A is stopped, the room can be kept in a comfortable humidity range by the humidity control material 30 constructed on the other wall portions 3, 3,.

  In addition, the surface makeup of the humidity control material 30 is applied in the same manner as the surface makeup of the humidity control body 11 in the humidity control air conditioner A, and the wall portions 3, 3,. Since the interior finish with the wall 3 of the humidity control body 11 of A is also used, a sense of unity is created in the room, and a clean impression can be given.

  In addition, in this embodiment, although the humidity control material 30 is constructed in the indoor side surface of wall part 3, 3, ..., wall part 3, 3 other than the wall part 3 in which the humidity control air conditioner A is installed. ,... Or at least one of the indoor side surfaces of the ceiling 4 may be provided with the humidity control material 30, and the same effect as the above embodiment can be achieved.

  Moreover, you may provide the humidity control material 30 of the structure of this Embodiment 4 in the structure of any of the said Embodiments 2-4, and the same effect is obtained.

(Other embodiments)
In the above-described embodiment, the heat source body 10 that circulates refrigerant or cold / hot water is used. However, the heat source body 10 is not limited to such a refrigerant or cold / warm water circulation system, and for example, hot water and cold water are supplied independently. It is also possible to use what has been made to do. For example, as means for supplying hot water, there are electric water heaters, boilers for gas and oil boilers, use of hot water by solar systems, use of waste heat by cancellation, cogeneration, etc., while supplying cold water Means include use of well water, cold water by an ice maker, and cold storage water. In addition, a cooling and heat dissipation panel can also be configured using a heat pipe.

  Next, specific examples will be described.

(Test 1)
FIG. 11 shows the results of a test for examining the relative humidity change in the room when the humidity control air conditioner A is switched from the cooling operation state to the operation stop state in the configuration of the third embodiment (see FIGS. 5 to 8). Show. In addition, as a comparative example, the humidity control body 11 and the air layer 12 are not provided, and only the heat source body 10 is provided, and the relative humidity change in the non-humidity control space where humidity control is not performed is illustrated. The relative humidity is a value obtained by dividing the amount of water vapor in the air by the amount of saturated water vapor.

  In the comparative example, the humidity greatly decreases with the start of the cooling operation, and when the operation is stopped, the humidity increases rapidly and returns to the original state. On the other hand, in the example of this invention, the humidity at the time of air_conditionaing | cooling operation has not drastically fallen and the humidity rises moderately even after the operation is stopped. From this, it can be seen that, even when the cooling operation and the stop thereof are switched, the humidity adjusting body 11 suppresses the fluctuation of the indoor humidity, and the humidity of the indoor space is kept comfortable.

(Test 2)
Moreover, FIG. 12 shows the result of the test which investigated the relative humidity change of the room | chamber interior when the humidity control air-conditioning apparatus A was switched from the heating operation state to the operation stop state in the structure of Embodiment 4 (refer FIG. 9). Further, as Comparative Example 1, the humidity control body 11 and the air layer 12 are not provided, and only the heat source body 10 is provided, and the relative humidity change in the non-humidity control space where the humidity control is not performed. The relative humidity change of the humidity control space provided with the heat source body 10 and the humidifier 28 (humidity supply means) without the body 11 and the air layer 12 is shown.

  In Comparative Example 1, the humidity greatly decreases with the start of the heating operation. Even when the operation is stopped, the humidity does not increase easily and is kept dry for a long time. In Comparative Example 2, the humidity is kept constant during the heating operation by the supply of moisture by the humidifier 28 (humidity supply means), but the relative humidity increases rapidly as soon as the operation is stopped. . On the other hand, in the example of the present invention, during the heating operation, the humidity is kept constant by the supply of moisture by the humidifier 28 (humidity supply means) as in Comparative Example 2, and the humidity is adjusted even if the operation is stopped thereafter. The relative humidity is kept slightly higher than that during the heating operation due to the excessive moisture absorption by the body 11. From this, it can be seen that the humidity of the indoor space is suppressed by the humidity control body 11 even when the heating operation and the stop thereof are switched, and the humidity of the indoor space is kept comfortable.

  INDUSTRIAL APPLICABILITY The present invention prevents wetness of indoor interior materials and structural enclosures and can keep indoor humidity comfortable, so it is extremely useful in the field of humidity control air conditioners that cool or heat indoors while conditioning the humidity. High industrial applicability.

FIG. 1 is a cross-sectional view showing a humidity control air conditioner according to Embodiment 1 of the present invention in a state of being incorporated in an indoor wall. FIG. 2 is a perspective view showing a room in which the humidity control air conditioner is incorporated in the wall. FIG. 3 is a view corresponding to FIG. FIG. 4 is a partially broken front view of the humidity conditioning air conditioner according to the second embodiment as viewed from the indoor side. FIG. 5 is a view corresponding to FIG. FIG. 6 is a view corresponding to FIG. FIG. 7 is a perspective view showing a partially broken heat source body in the third embodiment. FIG. 8 is an enlarged cross-sectional view illustrating a main part of the heat source body in the third embodiment. FIG. 9 is a view corresponding to FIG. FIG. 10 is a view corresponding to FIG. FIG. 11 is a characteristic diagram showing a test result of a change in relative humidity in the room when the humidity control air conditioner is switched from the cooling operation state to the operation stop state. FIG. 12 is a characteristic diagram showing a test result of a change in relative humidity in the room when the humidity control air conditioner is switched from the heating operation state to the operation stop state.

Explanation of symbols

A Humidity control air conditioner 1 Room 3 Wall 4 Ceiling 10 Heat source body 11 Humidity control body 12 Air layer 14 Drainage part 19 Circulation passage 20 Circulation pipe 21 Indoor side radiant panel part 22 Outdoor side radiant panel part 24 Cooling water heater 26 Outdoor side Heat insulation panel 28 Humidifier (humidity supply means)
30 Conditioning material

Claims (4)

A humidity control air conditioner installed on a wall of a room to cool or heat the room while humidity is controlled,
A heat source body that generates cold or warm heat located on the outdoor side and a humidity control body that adjusts air humidity located on the indoor side are provided side by side with an air layer interposed therebetween,
A humidity control air conditioner characterized in that a drainage unit for discharging condensed water generated in the air layer is provided. In the humidity control air conditioner of Claim 1,
The heat source body is a circulation passage through which cold water or hot water made by a cold water heater flows,
A humidity control air conditioner comprising: a radiant panel portion that radiates cold heat or cold water flowing through the circulation passage. In the humidity control air conditioning apparatus of Claim 1 or 2,
A humidity control air conditioner comprising a humidity supply means for supplying moisture to the humidity control body from the back surface on the air layer side when the heat source body generates heat. The humidity control air conditioner according to any one of claims 1 to 3 is installed on at least one of a plurality of wall portions of the room,
A spatial structure in which a humidity control material is applied to at least one indoor surface of another wall or ceiling.

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