JP2017067365A - Humidity control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a humidity control system which continuously humidify a habitable room in winter.SOLUTION: A humidity control system 100 for supplying humidified air to a habitable room includes: a first chamber 1A and a second chamber 1B in which humidity control materials are accommodated inside; a first air supply passage 21 for supplying air with high relative humidity to each chamber; a second air supply passage for supplying air with low relative humidity to each chamber; a ventilation passage 24 for supplying the air which has passed each chamber to the habitable room 25; and a control device for controlling the first air supply passage 21, the second air supply passage 22 and the ventilation passage 24. The control device performs a parallel operation in which one out of the first chamber 1A and the second chamber is in a humidity absorption mode and the other is in a humidity release mode respectively. In the first chamber and the second chamber, the humidity absorption mode and the humidity release mode are repeated alternately, and the humidified air is supplied to the habitable room 25 substantially continuously. An air amount in the humidity absorption mode is larger than an air amount in the humidity release mode.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a humidity control system, for example, a humidity control system capable of continuously humidifying a living room in winter.

  Conventionally, humidity control panels using diatomaceous earth or the like have been widely used on the wall surfaces of living rooms in buildings. For example, when the relative humidity of the air in the room is high, the humidity control panel can absorb the water vapor. Further, when the relative humidity of the air in the room is low, water vapor contained in the humidity control panel is released into the air. Therefore, the humidity control panel can adjust the humidity of the room air.

JP 2004-76494 A

  However, the humidity control panel as described above passively absorbs and releases moisture according to the relative humidity of the air in the room, so it is difficult to intentionally control the moisture absorption and release of the humidity control panel. It is. For example, when the relative humidity of the air in the room decreases, the humidity control panel releases the water vapor it holds into the air, but after releasing all the water vapor, the room cannot be further humidified. . Accordingly, a system that continuously humidifies the living room has been desired, particularly in winter.

  In order to obtain continuously humidified air, a system using a first humidity control chamber and a second humidity control chamber of the same specification in parallel can be considered. In this system, for example, outside air having a high relative humidity is supplied to the first humidity control chamber, and a moisture absorption mode in which the water vapor is adsorbed to the humidity control material is performed. Meanwhile, for example, heated air having a low relative humidity is supplied to the second humidity control chamber, and a moisture release mode is performed in which water vapor is released from the humidity control material to humidify the heating air. Air humidified in the second humidity control chamber is supplied to the living room.

  Next, in anticipation of the release of the humidity control material in the second humidity control chamber, this time, heated air having a low relative humidity is supplied to the first humidity control chamber, and the first humidity control chamber is supplied. The humidified air is taken out from the air, and outside air having a high relative humidity is supplied to the second humidity control chamber to absorb moisture.

  By continuously performing the above operation, the first humidity control chamber and the second humidity control chamber repeat the cycle of moisture absorption and dehumidification, respectively, and the heated air is always humidified from either one of the chambers. Can be obtained.

  However, as a result of various experiments by the inventors, it has been found that the moisture absorption rate is generally smaller than the moisture release rate. For this reason, in order to efficiently perform the above-described cycle of moisture absorption and moisture release to each chamber, it is necessary to supply an optimal air volume in the case of absorbing moisture and releasing moisture.

  The present invention has been devised in view of the actual situation as described above, and can control the moisture absorption and desorption of the humidity control material, and can maximize the moisture absorption capability and moisture release capability of the humidity control material. The main purpose is to provide a simple humidity control system.

  The present invention is a humidity control system for supplying humidified air to a living room, and includes a first chamber in which a humidity control material is stored, and a humidity control material is stored in the first chamber. A second chamber having substantially the same specifications, a first air supply passage for supplying air having a high relative humidity to the first chamber and the second chamber, and a relative humidity for the first chamber and the second chamber. A second air supply path for supplying low air, a ventilation path for supplying air that has passed through the first chamber and the second chamber to the living room, the first air supply path, the second air supply path, and the ventilation. A control device for controlling a path, wherein the control device controls the first air supply path to supply air having a high relative humidity to one of the first chamber and the second chamber, A moisture absorption mode for adsorbing water vapor in the air to the humidity control material of the chamber and the second air supply path are controlled to supply the air having a low relative humidity to the other of the first chamber and the second chamber. And a moisture release mode for releasing the water vapor held by the humidity control material in the chamber into the air in parallel, and in each of the first chamber and the second chamber, The moisture absorption mode and the moisture release mode are alternately repeated so that the humidified air is substantially continuously supplied to the living room, and the air volume in the moisture absorption mode is greater than the air volume in the moisture release mode. It is large.

  In another aspect of the present invention, in each of the first chamber and the second chamber, the amount of moisture adsorbed by the humidity control material in the moisture absorption mode and the amount of water vapor of the humidity conditioning material in the moisture release mode are determined. The difference from the released amount may be 10% or less.

  In another aspect of the present invention, the humidity conditioner may have temperature dependency.

  In another aspect of the present invention, the air volume of the first air supply path may be 1.5 ± 0.2 times the air volume of the second air supply path.

  In another aspect of the present invention, outside air is supplied to the first air supply path, and air obtained by warming a mixture of the air in the living room and the outside air with an air conditioner is supplied to the second air supply path. It may be supplied.

  According to the humidity control system of the present invention, a moisture absorption mode in which air having a high relative humidity is supplied to one of the first chamber and the second chamber and water vapor in the air is adsorbed to the humidity control material of the chamber, and the first chamber In addition, a moisture release mode is performed in parallel, in which air having a low relative humidity is supplied to the other of the second chambers, and water vapor held by the humidity control material in the chamber is released into the air. In each of the first chamber and the second chamber, the moisture absorption mode and the moisture release mode are alternately repeated, and the humidified ventilation air can be taken out substantially continuously and supplied to the living room. Can do. Accordingly, the room can be continuously humidified.

  According to the present invention, in each chamber, the air volume in the moisture absorption mode is set larger than the air volume in the moisture release mode. In general, the moisture absorption rate of the humidity control material is smaller than the moisture release rate, so as described above, by controlling the air volume, the moisture absorption amount and moisture release amount to the humidity control material of each chamber are balanced, The cycle of moisture absorption and moisture release can be performed efficiently. Therefore, according to the present invention, it is possible to provide a humidity control system capable of maximizing the moisture absorption capability and moisture release capability of the humidity control material.

It is a side view of the house using the humidity control system which concerns on embodiment of this invention. It is a perspective view of the 1st chamber of this embodiment. It is a perspective view of the 2nd chamber of this embodiment. It is a longitudinal cross-sectional view of a 1st chamber. It is AA sectional drawing of FIG. (A) And (B) is the principal part enlarged view of FIG. It is BB sectional drawing of FIG. It is a flowchart which shows an example of operation | movement of the humidity control system of this embodiment. It is a graph which shows the relationship between the equilibrium moisture content of a humidity control material, and relative humidity.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Each drawing is for enhancing the understanding of the contents of the invention, and exaggerated display is included, and it is pointed out in advance that the scales and the like are not exactly the same between the drawings.

  FIG. 1 is a side view conceptually showing an example of a house 20 in which the humidity control system 100 according to the present embodiment is used for a ventilation system. More specifically, the humidity control system 100 can be air-conditioned and humidified while ventilating the room 25 of the house 20 in winter.

  In the humidity control system 100 of the present embodiment, as the humidity control chamber 1, a first chamber 1A and a second chamber 1B having substantially the same specifications are used in parallel. That is, in the present embodiment, the first chamber 1A and the second chamber 1B having the same shape, volume, and humidity control capability are used as the humidity control chamber 1. Hereinafter, an example of the first chamber 1A will be described as a representative, but it is pointed out that the second chamber 1B also has the same structure.

  2 is a perspective view of the first chamber 1A, and FIG. 3 is a perspective view of the second chamber 1B. As shown in FIGS. 2 and 3, each chamber 1 </ b> A and 1 </ b> B includes a casing 3 that divides a space 2 inside, and a humidity control material (shown in a dotted shape) 4 that is located in the space in the casing 3. Including.

  In the present embodiment, the casing 3 divides, for example, a substantially rectangular parallelepiped space 2, and an inlet 5 to which air is supplied is formed on one end side, while air is discharged on the other end side. An outlet 6 is formed. In the present embodiment, each chamber 1A and 1B is provided with two inlets 5 on the lower surface side and two outlets 6 on the upper surface side. Thereby, the casing 3 can provide an air flow from the inlet 5 toward the outlet 6 in the space 2. In the present embodiment, a vertical air flow from the inlet 5 toward the outlet 6 is provided in the space 2 of the casing 3.

  As for the shape of the casing 3, any shape can be adopted as long as it can partition a space inside. In a preferred embodiment, the casing 3 has a multilayer structure including an inner layer 3a on the space 2 side and an outer layer 3b on the outer side. The inner layer 3a is made of, for example, a heat insulating material. Thereby, the space 2 inside the casing 3 is thermally insulated from the outside, and as a result, the temperature of the inside air (and thus the relative humidity) can be minimized. This is effective for causing the humidity control material 4 to exhibit a stable moisture absorbing function or moisture releasing function.

  The humidity control material 4 is preferably an inorganic porous material, for example, and used by mixing one or more of diatomaceous mudstone, diatom shale, allophane, silica gel, imogolite, sepiolite, zeolite, and Oya stone. It is done. These humidity-controlling materials 4 may be in a state as produced as natural minerals, or may be baked or modified. In the present embodiment, a zeolite-based porous material is used as the humidity control material 4.

  The humidity control material 4 of this embodiment is used in a granular form. The particle diameter of the humidity control material 4 is not particularly limited, but if it becomes excessively large, the strength and the workability may be deteriorated, so that it is, for example, 2 mm or less, more preferably 1 mm or less. desirable.

  As shown in FIGS. 2 and 3, the humidity control material 4 of the present embodiment is disposed on at least the surface of the sheet material 7. As the sheet material 7, any material can be adopted as long as the humidity control material 4 in the form of particles can be held on the surface. In a preferred embodiment, the sheet material 7 can be suitably selected from a paper material made of pulp fibers, a cloth material such as a nonwoven fabric or a woven fabric, and a sheet formed by a binder such as a resin.

  As the sheet material 7 of the present embodiment, a mixed paper made from a mixed material of pulp fibers and a particulate humidity control material 4 is used. Thereby, many humidity control materials 4 can be arranged not only on both surfaces of sheet material 7, but also in the inside. Further, when a cloth material or a resin material is used as the sheet material 7, the humidity control material 4 can be attached to the surface thereof using an adhesive or a binder.

  FIG. 4 shows a longitudinal sectional view of an embodiment of the first chamber 1A of the present embodiment. FIG. 5 is a cross-sectional view taken along the line AA in FIG. As shown in FIGS. 4 and 5, the sheet material 7 on which the humidity control material 4 is arranged has a plurality of surfaces arranged at intervals in the casing 3 so as to follow the air flow in the casing 3. Yes. That is, the surface of the sheet material 7 is arranged along the vertical direction in the casing 3, and a plurality of sheets are arranged at intervals in a direction perpendicular to the plane of the sheet material 7.

  The first chamber 1 </ b> A and the second chamber 1 </ b> B configured as described above supply the humidity adjusting material 4 by supplying air having high relative humidity (for example, low temperature outside air in winter) to the inlet 5 of the casing 3. It is possible to adsorb water vapor in the air and to take out the dehumidified air from the outlet 6 of the casing 3 (hereinafter referred to as “moisture absorption mode”). Conversely, the first chamber 1A and the second chamber 1B supply air having a low relative humidity to the inlet 5 of the casing 3 (for example, air that has been heated and air-conditioned in winter). Water vapor is released into the air, and the humidified air can be taken out from the outlet 6 of the casing 3 (hereinafter referred to as “moisture release mode”).

  Moreover, since the humidity control material 4 distribute | arranged to 1st chamber 1A and 2nd chamber 1B of this embodiment is distribute | arranged on the surface of several sheet | seat material 7, it raises the contact opportunity with the air in the casing 3. , The moisture exchange area can be increased. Therefore, the first chamber 1A and the second chamber 1B of the present embodiment can maximize the moisture absorption capability and moisture release capability of the humidity control material 4.

  Furthermore, as a result of various experiments by the inventors, the moisture absorption / release rate of the humidity control material 4 is affected by the heat capacity of the carrier (sheet material 7) that holds the humidity control material. It has been found that the wet rate is improved. In this regard, since the sheet material 7 holding the humidity conditioning material 4 is small in thickness and has a small heat capacity, the humidity conditioning material is used in the first chamber 1A and the second chamber 1B of the present embodiment. The moisture absorption / release rate of 4 can be increased.

  As well represented in FIG. 5, the sheet material 7 includes, for example, a first sheet material 7a and a second sheet material 7b.

  As for the 1st sheet material 7a, the surface of both sides faces the space 2 of the casing 3. To face the space 2 means to be disposed so as to substantially contact the air in the space 2. On the other hand, only one surface of the second sheet material 7b faces the space 2 of the casing 3, and the other surface is in contact with the inner surface 3i of the casing 3 (that is, the inner surface of the inner layer 3a in this embodiment). , Not substantially in contact with the air in the space 2.

  FIG. 6A shows an enlarged view of a main part of the first sheet material 7a of FIG. The first sheet material 7a is bent at the main body 10 extending along the space 2 along the inner surface 3i of the casing 3 and fixed to the casing 3 along the inner surface 3i of the casing 3 in a cross section perpendicular to the air flow. Part 11. In such a first sheet material 7 a, the humidity control material 4 can be disposed on both the surface along the longitudinal direction of the main body 10 and the surface orthogonal to the main body 10 (the surface of the end portion 11). . Therefore, the humidity control material 4 can be more efficiently arranged on the inner surface of the casing 3.

  Moreover, since the main-body part 10 of the 1st sheet | seat material 7a is not contacting the inner layer 3a of the casing 3, the moisture absorption / release speed | rate of the humidity control material 4 currently hold | maintained there can be raised effectively. Therefore, it is desirable to arrange more humidity control materials 4 at such positions.

  On the other hand, FIG. 6B shows an enlarged view of a main part of the second sheet material 7b of FIG. The other surface of the second sheet material 7 b is in contact with the inner surface 3 i of the inner layer 3 a made of the heat insulating material of the casing 3. For this reason, since the 2nd sheet material 7b is hold | maintained by the casing 3, the moisture absorption-and-release rate of the humidity control material 4 falls. It is desirable to arrange relatively few humidity control materials 4 at such positions.

  From such a viewpoint, as shown in FIG. 6A, the first sheet material 7a of the present embodiment includes a plurality of unit sheet materials 12 with a humidity control material having a thickness t (in this example, two sheets). On the other hand, as shown in FIG. 6B, the second sheet material 7b of the present embodiment has fewer unit sheet materials 12 having a thickness t than the first sheet material 7a. It is formed using the number of sheets. In the present embodiment, the second sheet material 7 b is formed of one unit sheet material 12. Each unit sheet material 12 is configured to have substantially the same amount of humidity conditioning material (mass). Therefore, in the first chamber 1A and the second chamber 1B of the present embodiment, the humidity control material arrangement amount (mass) of the second sheet material 7b is larger than the humidity control material arrangement amount (mass) of the first sheet material 7a. They are small, and their ratio is about 1: 2.

  The thickness t of the unit sheet material 12 is not particularly limited, but is desirably as small as possible. Thereby, it is possible to arrange more unit sheet materials 12, and consequently, the humidity control material 4 in the space 2 of the casing 3 while improving the moisture absorption / release performance of the humidity control material 4. On the other hand, if the thickness t of the unit sheet material is too small, the strength and durability may be reduced. From such a viewpoint, the thickness t is preferably about 0.5 to 2.0 mm.

  FIG. 7 is a cross-sectional view taken along the line BB in FIG. As shown in FIG. 7, the sheet material 7 is such that the end 15 on the inlet 5 side and the end 16 on the outlet 6 side are separated from the inlet 5 and the outlet 6 by a distance L along the air flow, respectively. Is provided. With such a configuration, the air supplied from the inlet 5 is uniformly supplied to the gaps between the sheet materials 7 and can be taken out from the outlet 6, which ensures a moisture absorption / release action in a wide range. it can. In a preferred embodiment, the distance L is preferably about 50 to 200 mm.

  Returning to FIG. 1, air having a high relative humidity is supplied to one inlet 5 of the first chamber 1 </ b> A via the first air supply path 21. In general, in winter, the outside air has a temperature lower than that of the air in the living room 25 and thus has a higher relative humidity. Therefore, in the present embodiment, the first air supply path 21 supplies the outside air having a high relative humidity to the first chamber 1A and the second chamber 1B in the winter season to execute the moisture absorption mode. For example, one end of the first air supply path 21 communicates with the outside air through a basic ventilation port 28 provided in the foundation 26 of the house 20.

  Further, the first air supply path 21 includes a first branch path 21A and a second branch path 21B that are selectively switched by the switching damper 30 in the middle thereof. In this embodiment, the first branch path 21A of the first air supply path 21 is one inlet 5 of the first chamber 1A, and the second branch path 21B of the first air supply path 21 is one inlet of the second chamber 1B. 5 are connected to each other. Therefore, the first air supply path 21 can be operated in the moisture absorption mode by supplying the outside air only to either the first chamber 1A or the second chamber by switching the switching damper 30.

  Air having a low relative humidity is supplied to the other inlet 5 of the first chamber 1 </ b> A via the second air supply path 22. In this embodiment, the 2nd air supply path 22 is comprised as a flow path for conveying the air for ventilating, air-conditioning (heating) the living room 25 to the 1st chamber 1A and the 2nd chamber 1B, for example, One end side is connected to the heat source chamber 40.

  The heat source chamber 40 includes a casing that partitions a thermally insulated space inside, and an indoor unit 50 of an air conditioner is disposed in the casing. In the heat source chamber 40, a first inlet 40 a into which outside air introduced into the underfloor space from the basic ventilation port 28 is taken into the air suction port side of the indoor unit 50, and air (internal air) from the ventilation outlet 25 b of the living room 25. ) Are introduced, respectively. Further, the heat source chamber 40 is provided with an outlet 40 c on the air outlet side of the indoor unit 50 from which air exchanged by the indoor unit 50 is blown out. One end of the second air supply path 22 is connected to the outlet 40c. In the heat source chamber 40, the air inlet and the air outlet of the indoor unit 50 are separated so as not to mix each other's air.

  Therefore, by operating the air conditioner, the indoor unit 50 in the heat source chamber 40 raises the mixture of fresh outside air and the air in the living room 25 to a desired temperature (lowers the relative humidity), and is used for ventilation. The air can be discharged from the outlet 40c. In the present embodiment, outside air is introduced into the underfloor space from the basic ventilation port 28 as the outside air, and in this underfloor space, heat exchanged once with geothermal heat is used, but it is directly led by a duct or the like. May be used, and various types of outside air can be employed.

  The second air supply path 22 includes a first branch path 22 </ b> A and a second branch path 22 </ b> B that are selectively switched by the switching damper 32 in the middle of the second air supply path 22. In the present embodiment, the first branch path 22A of the second air supply path 22 is the other inlet 5 of the first chamber 1A, and the second branch path 22B of the second air supply path 22 is the other of the second chamber 1B. One inlet 5 is connected to each. Therefore, the second air supply path 22 controls the switching damper 32 so that only one of the first chamber 1A and the second chamber 1B has the heated relative humidity generated in the heat source chamber 40. Low ventilation air can be supplied and operated in moisture release mode. Thereby, the ventilation air humidified by receiving water vapor from the humidity control material 4 can be taken out from the outlet 6 of the first chamber 1A or the second chamber 1B to which the ventilation air is supplied.

  An exhaust path 23 is connected to one outlet 6 of the first chamber 1A. The exhaust path 23 is a flow path for discharging the air that has passed through the first chamber 1A and the second chamber 1B to the outside of the house 20, and, for example, one end side is outside air through the back of the house 20, the roof of the eaves, or the like. Communicated with.

  Further, the exhaust path 23 includes a first branch path 23A and a second branch path 23B that are selectively switched by the switching damper 34 in the middle thereof. In the present embodiment, the first branch path 23A of the exhaust path 23 is connected to one outlet 6 of the first chamber 1A, and the second branch path 23B of the exhaust path 23 is connected to one outlet 6 of the second chamber 1B. Yes. Further, the exhaust passage 23 is provided with an exhaust fan 35 for making the first branch passage 23A and the second branch passage 23B negative pressure.

  The exhaust path 23 can discharge one of the first chamber 1 </ b> A and the second chamber 1 </ b> B to the outside of the house 20 by switching the switching damper 34. In the present embodiment, the switching damper 34 is controlled so that the exhaust path 23 is connected only to the chamber operating in the moisture absorption mode. As a result, the moisture conditioning material 4 in the chamber is deprived of water vapor, and the air with reduced relative humidity is discharged to the outside air of the house 20.

  One end of the ventilation path 24 is connected to the other outlet 6 of the first chamber 1A. The ventilation path 24 is a flow path for supplying air that has passed through the first chamber 1 </ b> A or the second chamber 1 </ b> B to the living room 25 of the house 20. The other end of the ventilation path 24 communicates with the ventilation inlet 25 a of the living room 25. In addition, the ventilation path 24 includes a first branch path 24A and a second branch path 24B that are selectively switched by the switching damper 36 in the middle thereof.

  In the present embodiment, the first branch path 24A of the ventilation path 24 is connected to another outlet 6 of the first chamber 1A, and the second branch path 24B of the ventilation path 24 is connected to another outlet 6 of the second chamber 1B. Has been. In the present embodiment, the switching damper 36 of the ventilation path 24 is switch-controlled so that the first chamber 1A or the second chamber 1B operated in the moisture release mode communicates with the living room 25.

  The switching dampers 30, 32, 34 and 36, the fan 35 and the air conditioner described above are switched and controlled by a control device (not shown) according to a predetermined processing procedure.

  The operation flow of the ventilation system configured as described above is shown in the flowchart of FIG.

  First, the control device starts timing (step S1), and then switches the first chamber 1A to the moisture release mode (step S2). Thereby, the ventilation air humidified in the first chamber 1 </ b> A is supplied to the living room 25.

  In the moisture release mode of the first chamber 1A, the control device causes the first branch path 22A of the second air supply path 22 and the inlet 5 of the first chamber 1A to communicate with each other by switching the switching damper 32. Further, the control device causes the first branch path 24A of the ventilation path 24 and the outlet 6 of the first chamber 1A to communicate with each other by switching the switching damper 36. Thereby, the ventilation air conditioned in the heat source chamber 40 passes through the second air supply path 22, is humidified by the humidity control material 4 of the first chamber 1 </ b> A, and is supplied to the living room 25 through the ventilation path 24. At this time, for example, the control device controls the damper 33 provided in the ventilation inlet 25a of the living room 25 to set the air volume passing through the first chamber 1A to “air volume A”. Thus, the moisture release mode is performed with the air volume A.

  Next, the control device switches the second chamber 1B to the moisture absorption mode (step S3). Thereby, the moisture conditioner 4 of the second chamber 1B can absorb the water vapor of the outside air.

  In the moisture absorption mode of the second chamber 1B, the control device causes the second branch passage 21B of the first air supply passage 21 and the inlet 5 of the second chamber 1B to communicate with each other by switching the switching damper 30. In addition, the control device causes the second branch passage 23B of the exhaust passage 23 and the outlet 6 of the second chamber 1B to communicate with each other by switching the switching damper 34. Accordingly, the outside air having a high relative humidity passes through the first air supply path 21, is absorbed by the humidity control material 4 in the second chamber 1 </ b> B, and is discharged to the outside of the house 20 through the exhaust path 23. At this time, the control device sets the air volume of the first air supply path 21 to “air volume B”, for example, by controlling the exhaust fan 35. Thereby, the moisture absorption mode is performed with the air volume B. This air volume B is set larger than the air volume A in the moisture release mode.

  As described above, the moisture absorption rate of the humidity control material 4 tends to be smaller than the moisture release rate. One of the causes is the temperature dependency of the zeolitic humidity control material used in this embodiment. FIG. 9 shows an example of a graph showing a relationship between a general equilibrium moisture content of a zeolite-based humidity conditioning material and a relative humidity of air. Thus, the humidity control material 4 shows different moisture absorption / release performance depending on the relative humidity (temperature) of the surrounding air. And in the moisture absorption mode and moisture release mode of the humidity control material 4, the temperature of the supplied air differs and it is thought that the difference in the air temperature has influenced the difference between moisture absorption speed and moisture release speed. .

  Therefore, as in the present invention, by setting the air volume B in the moisture absorption mode to be larger than the air volume A in the moisture release mode, for example, the moisture release of the humidity control material 4 of the first chamber 1A in the moisture release mode. The amount and the moisture absorption amount of the humidity control material 4 of the second chamber 1B in the moisture absorption mode can be balanced or substantially matched, and as a result, the moisture absorption / release capacity of each humidity control material 4 is utilized to the maximum. It becomes possible to do.

  In a preferred embodiment, in each of the first chamber 1A and the second chamber 1B, the difference between the moisture absorption amount of the moisture conditioning material 4 in the moisture absorption mode and the moisture release amount of the humidity conditioning material 4 in the moisture release mode is It is desirable to adjust the air flow ratio B / A so that it is 10% or less, preferably 7% or less. This ratio can be appropriately determined based on the ratio of the moisture absorption rate and the moisture release rate of the humidity control material 4 to be used. In this embodiment, since the moisture absorption speed of the humidity control material 4 is about 2/3 of the moisture release speed, the air volume B in the moisture release mode is 1.5 ± 0.2 times the air volume A in the moisture absorption mode, Preferably, it is set to 1.5 ± 0.1 times.

  Next, the control device determines whether or not a predetermined time has elapsed (step S4), and if the result is negative (N in step S4), loops steps S2 and S3. Therefore, until the predetermined time elapses, the first chamber 1A is operated in the moisture release mode, while the second chamber 1B is operated in the moisture absorption mode. The above “time” can be arbitrarily set, but for example, the humidity conditioner 4 finishes moisture completely based on the moisture absorption / release performance of the humidity conditioner 4 of each chamber 1A and 1B, the passing air volume, and the like. It can be set as the last minute time.

  Next, when the result of step S4 is affirmative (Y in step S4), the control device resets the previous time count and starts a new time count (step S6).

  Next, the control device switches the first chamber 1A to the moisture absorption mode (step S7). Thereby, the moisture conditioner 4 of the first chamber 1A can absorb the water vapor of the outside air.

  In the moisture absorption mode of the first chamber 1A, the control device causes the first branch passage 21A of the first air supply passage 21 and the inlet 5 of the first chamber 1A to communicate with each other by switching the switching damper 30. Further, the control device causes the first branch passage 24A of the exhaust passage 23 and the outlet 6 of the first chamber 1A to communicate with each other by switching the switching damper 34. Accordingly, the outside air having a high relative humidity passes through the first air supply path 21, is absorbed by the humidity control material 4 in the first chamber 1 </ b> A, and is discharged to the outside of the house 20 through the exhaust path 23. Note that the air volume of the first air supply path 21 is maintained at the previously adjusted air volume B, and the moisture absorption mode of the first chamber 1A is also performed with the air volume B.

  Next, the control device switches the second chamber 1B to the moisture release mode (step S8). Thereby, the ventilation air humidified by the second chamber 1B is supplied to the living room 25 this time.

  In the moisture release mode of the first chamber 1A, the control device causes the second branch path 22B of the second air supply path 22 and the inlet 5 of the second chamber 1B to communicate with each other by switching the switching damper 32. In addition, the control device causes the second branch path 24B of the ventilation path 24 and the outlet 6 of the second chamber 1B to communicate with each other by switching the switching damper 36. Thereby, the ventilation air conditioned in the heat source chamber 40 passes through the second air supply path 22, is humidified by the humidity control material 4 in the second chamber 1 </ b> B, and is supplied to the living room 25 through the ventilation path 24. Note that the air volume of the second air supply path 22 is maintained at the previously adjusted air volume A, and the moisture release mode of the second chamber 1B is also performed with the air volume A.

  Next, the control device determines whether or not the predetermined time has elapsed (step S9), and if the result is negative (N in step S9), loops steps S7 and S8. Therefore, until the predetermined time elapses, the second chamber 1B is operated in the moisture release mode, while the first chamber 1A is operated in the moisture absorption mode. Next, when the result of step S9 is affirmative (Y in step S9), the control device resets the previous time measurement (step S10) and starts a new time measurement (step S1). Thereafter, step S2 and subsequent steps are repeated.

  As described above, in the present embodiment, the first chamber 1A and the second chamber 1B are always in different operation modes. Therefore, while the first chamber 1A is operated in the moisture absorption mode, the second chamber 1B is operated in the moisture absorption mode, and while the first chamber 1A is operated in the moisture absorption mode, the second chamber 1B is in the moisture release mode. It is driven by. Therefore, in the system of the present embodiment, the humidified air can be taken out substantially continuously and supplied to the living room 25 by alternately using the moisture release mode of the first chamber 1A or the second chamber 1B. it can.

  Moreover, in this embodiment, by setting the air volume B in the moisture absorption mode to be larger than the air volume A in the moisture release mode, for example, the moisture release amount of the humidity control material 4 of the first chamber 1A in the moisture release mode. And the moisture absorption amount of the humidity conditioner 4 of the second chamber 1B in the moisture absorption mode can be balanced or substantially matched, and as a result, the moisture absorption / release capacity of each humidity conditioner 4 is utilized to the maximum. It becomes possible.

  Therefore, according to the ventilation system using the humidity control system 100 of the present embodiment, the outside air that has been air-conditioned and humidified can be continuously and efficiently supplied to the living room 25.

A humidity control chamber was prototyped with a rectangular parallelepiped shape of 2.5 m × 0.45 m × 0.15 m. A total of 1.8 kg of zeolitic humidity control material was placed in each chamber with an arrangement area of 3.6 m ² . And the moisture absorption amount in the moisture absorption mode and the moisture release amount in the moisture release mode were measured. In the moisture absorption mode, outside air having a temperature of 5 ° C. and an absolute humidity of 4.5 g / kg ′ was supplied to the humidity control chamber. In the moisture release mode, air having a temperature of 35 ° C. and an absolute humidity of 4.5 g / kg ′ obtained by warming the outside air with an air conditioner was supplied to the humidity control chamber. And the moisture absorption / release amount of the humidity control material was measured by changing the air volume in the moisture release mode and the moisture absorption mode. The test results are shown in Table 1.

  As a result of the test, when the air volume in the moisture absorption mode was larger than the air volume in the moisture release mode, it was confirmed that the moisture absorption / release amounts were close to each other.

DESCRIPTION OF SYMBOLS 1 Humidity control chamber 1A 1st chamber 1B 2nd chamber 4 Humidity control material 20 House 21 1st air supply path 22 2nd air supply path 24 Ventilation path 25 Living room 100 Humidity control system

Claims (5)

A humidity control system for supplying humidified air to a living room,
A first chamber containing a humidity control material therein;
A second chamber containing a humidity control material therein and having substantially the same specifications as the first chamber;
A first air supply path for supplying air having a high relative humidity to the first chamber and the second chamber;
A second air supply path for supplying air having a low relative humidity to the first chamber and the second chamber;
A ventilation path for supplying air that has passed through the first chamber and the second chamber to a living room;
A control device that controls the first air supply path, the second air supply path, and the ventilation path;
The control device controls the first air supply path to supply air having a high relative humidity to one of the first chamber and the second chamber, and water vapor in the air is supplied to the humidity control material in the chamber. Moisture absorption mode to adsorb,
The second air supply path is controlled to supply air having a low relative humidity to the other of the first chamber and the second chamber, and water vapor held by the humidity control material in the chamber is released into the air. The moisture release mode to be performed in parallel,
Moreover, in each of the first chamber and the second chamber, the moisture absorption mode and the moisture release mode are alternately repeated, and the humidified air is supplied to the living room substantially continuously, A humidity control system, wherein an air volume in the moisture absorption mode is larger than an air volume in the moisture release mode.   In each of the first chamber and the second chamber, a difference between the moisture adsorption amount of the humidity control material in the moisture absorption mode and the moisture release amount of the humidity conditioning material in the moisture release mode is 10%. The humidity control system according to claim 1, wherein:   The humidity control system according to claim 1, wherein the humidity control material has temperature dependency.   The humidity control system according to any one of claims 1 to 3, wherein an air volume of the first air supply path is 1.5 ± 0.2 times an air volume of the second air supply path. Outside air is supplied to the first air supply path,
The humidity control system according to any one of claims 1 to 4, wherein the second air supply path is supplied with air obtained by heating an air-fuel mixture of air in the living room and outside air with an air conditioner.