JP2014129930A - Humidity control module and humidity controller including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize the size reduction of a humidity control module by suppressing the temperature change of liquid absorbent in relation to the humidity control module for exchanging air and moisture by the liquid absorbent.SOLUTION: A humidity control module includes: moisture-permeable tubes (43) in which liquid absorbent flows; heat transfer tubes (48) that cause heat exchange between the liquid absorbent in the moisture-permeable tubes (43) and a heat medium provided therein; and air passages (50) that accommodate therein the moisture-permeable tubes (43) and the heat transfer tubes (48), and in which the air exchanging the moisture with the liquid absorbent flows. A network structure (60) in which the moisture-permeable tubes (43) cross the heat transfer tubes (48) in a state in which the moisture-permeable tubes (43) contact the heat transfer tubes (48) in a plurality of portions is formed.

Description

  The present invention relates to a humidity control module that adjusts the humidity of air using a liquid absorbent and a humidity control apparatus including the humidity control module.

  Conventionally, a liquid absorbent, such as an aqueous lithium chloride solution, and a moisture permeable film that allows only water vapor to pass through without passing through the liquid absorbent, and moisture between the air and the liquid absorbent through the moisture permeable film. There is known a humidity control apparatus that controls the humidity of the air by exchanging the air.

  For example, Patent Document 1 discloses a humidity control apparatus including an absorbent circuit in which a liquid absorbent circulates and a refrigerant circuit in which a refrigerant circulates to perform a refrigeration cycle. This humidity control apparatus includes a moisture absorption part and a moisture release part. In the moisture absorbing section and the moisture releasing section, the air passage provided with the fan is partitioned from the passage of the liquid absorbent by a moisture permeable membrane. And the condenser of a refrigerant circuit is arrange | positioned in the channel | path into which a liquid absorbent flows toward a moisture release part from a moisture absorption part. Further, an evaporator of the refrigerant circuit is disposed in a passage through which the liquid absorbent flows from the moisture releasing portion toward the moisture absorbing portion.

  In this humidity control apparatus, the liquid absorbent cooled by the evaporator flows into the moisture absorption part, and water vapor contained in the air is absorbed by the liquid absorbent through the moisture permeable film in the moisture absorption part, thereby The air in the passage is dehumidified. Further, in this humidity control apparatus, the liquid absorbent heated by the condenser flows into the moisture release section, and in the moisture release section, a part of the moisture of the liquid absorbent is vaporized to become water vapor, through the moisture permeable membrane. The air in the air passage is humidified by being released into the air.

JP 05-146627 A

  In the humidity control apparatus disclosed in Patent Document 1, a liquid absorbent that has been heated or cooled in advance by a refrigerant exchanges air and moisture through a moisture permeable membrane. When water vapor in the air is absorbed by the liquid absorbent, absorption heat is generated. On the other hand, when the moisture of the liquid absorbent is released into the air, the liquid water takes heat from the liquid absorbent and vaporizes. For this reason, in the humidity control apparatus disclosed in Patent Document 1, the temperature of the liquid absorbent gradually rises in the process in which the liquid absorbent absorbs the water vapor, and the liquid absorbent hardly absorbs the water vapor as the temperature rises. It will become. Further, in this humidity control apparatus, the temperature of the liquid absorbent gradually decreases in the process of releasing the moisture of the liquid absorbent into the air, and it becomes difficult for water vapor to be released from the liquid absorbent as the temperature decreases. .

  Therefore, in the conventional humidity control apparatus in which the liquid absorbent which has been heated or cooled in advance transfers air and moisture through the moisture permeable membrane, the moisture absorbent membrane is provided in order to obtain sufficient humidity control performance. There exists a problem that a moisture absorption part and a moisture release part will enlarge.

  The present invention has been made in view of such points, and an object of the present invention is to provide a liquid produced by exchanging air and moisture in a humidity control module that adjusts the humidity of air using a liquid absorbent. The purpose is to reduce the size of the humidity control module by suppressing the temperature change of the absorbent.

  In order to achieve the above object, in the present invention, heat exchange between the liquid absorbent and the heat medium is also performed in an air passage through which moisture is exchanged between the liquid absorbent and air.

  Specifically, the first invention is directed to a humidity control module (40) that humidifies or dehumidifies air using a liquid absorbent. The first aspect of the present invention includes a moisture permeable tube (43) through which the liquid absorbent does not permeate but permeate water vapor. The moisture absorbent pipe (43) through which the liquid absorbent flows, and a heating or cooling heat medium. A heat transfer pipe (48) that exchanges heat between the liquid absorbent in the moisture permeable tube (43) and the internal heat medium, and the moisture permeable tube (43) and the heat transfer tube (48) are installed, And an air passage (50) through which air for transferring and receiving moisture is provided. The first invention is characterized in that the moisture permeable tube (43) and the heat transfer tube (48) form a network structure (60) that intersects with each other at a plurality of locations.

  In the first aspect of the invention, the moisture permeable tube (43) and the heat transfer tube (48) installed in the air passage (50) form a network structure (60) and intersect with each other at a plurality of locations. Therefore, the liquid absorbent flowing in the moisture permeable tube (43) is provided with the heat or cold of the heat medium in the heat transfer tube (48) at a plurality of locations. Thereby, the temperature change of the liquid absorbent that occurs when the liquid absorbent exchanges air and moisture is suppressed.

  In the humidity control module (40) of the first invention, when the air in the air passage (50) is dehumidified, when a cooling heat medium flows through the heat transfer tube (48), it flows through the moisture permeable tube (43). The liquid absorbent is cooled by the cooling heat medium in the heat transfer tube (48). A part of the water vapor contained in the air in the air passage (50) is absorbed by the cooled liquid absorbent through the moisture permeable tube (43). When the liquid absorbent absorbs water vapor, heat of absorption is generated, but the moisture absorbent pipe (43) through which the liquid absorbent flows is in contact with the heat transfer pipe (48) at multiple locations. In the process of flowing through the moisture permeable tube (43), the heat transfer tube (48) is intermittently cooled by the heat medium. As a result, the amount of heat that the liquid absorbent rises in temperature due to the action of absorption heat while flowing in the moisture permeable tube (43) is absorbed by the heat medium flowing in the heat transfer tube (48). Therefore, even if absorption heat is generated when the liquid absorbent absorbs water vapor, an increase in the temperature of the liquid absorbent flowing in the moisture permeable tube (43) can be suppressed.

  In the humidity control module (40) of the first invention, when the air in the air passage (50) is humidified, if a heating medium flows through the heat transfer tube (48), the moisture permeable tube (43) The liquid absorbent flowing through is heated by the heat medium in the heat transfer tube (48). Part of the moisture contained in the heated liquid absorbent is converted into water vapor, passes through the moisture permeable tube (43), and is given to the air in the air passage (50). When moisture contained in the liquid absorbent evaporates, it takes heat away from the surroundings, but the moisture permeable tube (43) through which the liquid absorbent flows is in contact with the heat transfer tube (48) at multiple locations. The absorbent is intermittently heated by the heat medium in the heat transfer tube (48) in the process of flowing through the moisture permeable tube (43). As a result, the amount of heat that the liquid absorbent cools down due to the vaporization of moisture while flowing in the moisture permeable tube (43) is quickly compensated by the heat medium flowing in the heat transfer tube (48). Therefore, even if heat is taken away from the surroundings in the process of vaporization of the water contained in the liquid absorbent, the temperature drop of the liquid absorbent flowing in the moisture permeable tube (43) can be suppressed.

  According to a second aspect of the present invention, in the humidity control module (40) of the first aspect, the moisture permeable tube (43) and the heat transfer tube (48) constituting the network structure (60) extend in directions orthogonal to each other. It is characterized by being provided with a plurality at intervals.

  In the second aspect of the invention, since the network structure (60) is configured by providing a plurality of moisture permeable tubes (43) and heat transfer tubes (48) and assembling them in a lattice shape, the network structure (60) 60) is realized with a simple configuration.

  According to a third aspect of the present invention, in the humidity control module (40) of the first or second aspect, a plurality of the network structures (60) are provided along the air flow direction of the air passage (50). It is characterized by.

  In the third aspect of the invention, since the plurality of mesh structures (60) are provided along the air flow direction of the air passage (50), the air flowing through the air passage (50) ) Is humidified or dehumidified.

  According to a fourth aspect of the present invention, in the humidity control module (40) of the second or third aspect, the moisture permeable tube (43) constituting the network structure (60) includes a plurality of the moisture permeable pipes (43) constituting the network structure (60). The heat transfer tube (48) meanders between the heat transfer tubes (48), and is in contact with a part of the outer peripheral surface of the heat transfer tubes (48) along the circumferential direction thereof.

  In the fourth aspect of the invention, the moisture permeable tube (43) constituting the network structure (60) is a meandering tube, and is in contact with a part of the outer peripheral surface of each heat transfer tube (48) along its circumferential direction. Therefore, for example, compared to the case where the moisture permeable tube (43) and the heat transfer tube (48), which are both straight pipes, are simply in contact at the intersection, these moisture permeable tube (43) and the heat transfer tube (48 ) Increases in contact area.

  According to a fifth invention, in the humidity control module (40) of any one of the second to fourth inventions, the heat transfer tube (48) constituting the network structure (60) constitutes the network structure (60). The meandering pipe meanders between the plurality of moisture permeable pipes (43), and is in contact with a part of the outer peripheral surface of the moisture permeable pipe (43) along the circumferential direction thereof.

  In the fifth invention, the heat transfer tube (48) constituting the network structure (60) is a meandering tube, and contacts a part of the outer peripheral surface of each moisture permeable tube (43) along its circumferential direction. Therefore, for example, compared to the case where the moisture permeable tube (43) and the heat transfer tube (48), which are both straight pipes, are simply in contact at the intersection, these moisture permeable tube (43) and the heat transfer tube (48 ) Increases in contact area.

  A sixth invention is characterized in that, in the humidity control module (40) of the fifth invention, the heat transfer tube (48) is a resin tube.

  In the sixth aspect of the invention, since the heat transfer tube (48) is a resin tube, there is no occurrence of rust and it is lightweight. Moreover, since the resin tube can be reduced in diameter to about 1 mm and can be flexible, the workability of the heat transfer tube (48) is improved.

  According to a seventh aspect, in the humidity control module (40) of any one of the first to fifth aspects, the heat transfer tube (48) is a copper capillary tube.

  In the seventh aspect of the invention, since the heat transfer tube (48) is a copper capillary tube, it has a high thermal conductivity and is suitable for the heat transfer tube (48).

  The eighth invention is characterized in that, in the humidity control module (40) of the second invention, the moisture permeable tube (43) and the heat transfer tube (48) are straight tubes extending linearly.

  In the eighth invention, since the moisture permeable tube (43) and the heat transfer tube (48) are both straight tubes, the network structure (60) is realized with a simple configuration.

  According to a ninth invention, in the humidity control module (40) of any one of the second to eighth inventions, a pair of absorptions in which both ends of the plurality of moisture permeable tubes (43) are arranged to face each other. Each of the plurality of heat transfer tubes (48) is connected to a pair of heat medium headers (47) disposed opposite to each other, respectively, and is connected to the agent header (42). 42) and the pair of heat medium headers (47) partition the air passage (50).

  In the ninth aspect of the invention, since both ends of the plurality of moisture permeable tubes (43) are respectively connected to the pair of absorbent headers (42), from one absorbent header (42) to the other absorbent header ( The liquid absorbent is circulated in the plurality of moisture permeable tubes (43) by sending the liquid absorbent to each of the moisture permeable tubes (43) to 42). Also, since both ends of the plurality of heat transfer tubes (48) are connected to the pair of heat medium headers (47), respectively, each heat transfer tube is transferred from one heat medium header (47) to the other heat medium header (47). By sending the heat medium through (48), the heat medium flows through the plurality of heat transfer tubes (48). Since the pair of absorbent headers (42) and the pair of heat medium headers (47) partition the air passage (50), members for partitioning the air passage (50) are used as the headers (42, 48). ) Is not required separately.

  A tenth aspect of the invention is directed to a humidity control apparatus (10). The humidity control module (40) according to any one of the first to ninth aspects of the invention, and a moisture permeable tube (43) of the humidity control module (40). ), An absorbent circuit (30) for supplying a liquid absorbent to the heat transfer pipe (48) of the humidity control module (40), and a heat medium circuit (35) for supplying a heat medium for heating or cooling to the heat transfer tube (48), Air supply means (27, 28) for supplying air to the air passage (50) of the humidity control module (40), and dehumidifies the air flowing in the air passage (50) of the humidity control module (40) or It is characterized by humidification.

  In the tenth aspect of the invention, when the heat medium circuit (35) supplies a heat medium for heating to the heat transfer tube (48) of the humidity control module (40), it flows through the air passage (50) of the humidity control module (40). Air is humidified. That is, in the humidity control module (40), the liquid absorbent flowing in the moisture permeable tube (43) is allowed to flow inside the heat transfer tube (48) at a plurality of contact points between the moisture permeable tube (43) and the heat transfer tube (48). The water vapor heated by the heating heat medium and released from the liquid absorbent through the moisture permeable tube (43) is given to the air in the air passage (50). On the other hand, when the heat medium circuit (35) supplies a cooling heat medium to the heat transfer pipe (48) of the humidity control module (40), the air flowing through the air passage (50) of the humidity control module (40) is dehumidified. . That is, in the humidity control module (40), the liquid absorbent flowing in the moisture permeable tube (43) is allowed to flow inside the heat transfer tube (48) at a plurality of contact points between the moisture permeable tube (43) and the heat transfer tube (48). The water vapor is cooled by the cooling heat medium, and the water vapor contained in the air in the air passage (50) is absorbed by the liquid absorbent through the moisture permeable tube (43).

  According to the first invention, the moisture permeable tube (43) and the heat transfer tube (48) installed in the air passage (50) form a network structure (60) and intersect with each other at a plurality of locations. Therefore, the liquid absorbent flowing in the moisture permeable tube (43) is provided with the air flowing through the air passage (50) while being provided with the heat or cold of the heat transfer medium in the heat transfer tube (48) at a plurality of locations. Moisture is exchanged with the liquid absorbent in the moisture permeable tube (45). Therefore, the temperature change of the liquid absorbent that occurs when the liquid absorbent transfers air and moisture can be suppressed, and as a result, the humidity control module (40) can be downsized.

  Further, according to the first invention, the liquid absorbent and the heat medium exchange heat in the air passage (50) through which air and the liquid absorbent exchange moisture, so that moisture absorption is performed as disclosed in Patent Document 1. Compared to cooling or heating the liquid absorbent at a position distant from the head and moisture release section, there is almost no heat loss of the liquid absorbent that occurs between the time when the liquid absorbent is heated or cooled and before the exchange of air and moisture. The liquid absorbent need not be excessively cooled or heated in anticipation of temperature changes of the liquid absorbent due to the absorption or release of water vapor. Therefore, in the humidity control module (40), it is possible to reduce energy required to cause the liquid absorbent to absorb moisture or release moisture.

  According to the second invention, since the network structure (60) is composed of a plurality of moisture permeable tubes (43) and a plurality of heat transfer tubes (48) assembled in a lattice pattern, the network structure (60 ) Can be realized easily.

  According to the third invention, compared with the case where only one network structure (60) is provided in the air passage (50), the humidification amount or the dehumidification amount with respect to the air flowing through the air passage (50) is increased. The humidity control capability of the humidity control module (40) can be improved.

  According to the fourth invention, for example, compared to the case where the moisture permeable tube (43) and the heat transfer tube (48), both of which are straight pipes, are simply in contact at the intersection, these moisture permeable tubes (43) and Since the contact area with the heat transfer tube (48) increases, the heat exchange rate between the liquid absorbent flowing in the moisture permeable tube (43) and the heat medium flowing in the heat transfer tube (48) can be improved. It is possible to sufficiently exchange heat between the liquid absorbent and the heat medium.

  According to the fifth invention, for example, compared to the case where the moisture permeable tube (43) and the heat transfer tube (48), which are both straight pipes, are simply in contact at the intersection, these moisture permeable tubes (43) and Since the contact area with the heat transfer tube (48) increases, the heat exchange rate between the liquid absorbent flowing in the moisture permeable tube (43) and the heat medium flowing in the heat transfer tube (48) can be improved. It is possible to sufficiently exchange heat between the liquid absorbent and the heat medium.

  According to 6th invention, generation | occurrence | production of rust can be eliminated in a heat exchanger tube (48), and weight reduction of a humidity control module (40) can be achieved. Moreover, the workability of the heat transfer tube (48) can be improved.

  According to the seventh invention, the heat transfer tube (48) can have good thermal conductivity, the heat medium flowing in the heat transfer tube (48) and the liquid absorbent flowing in the moisture permeable tube (43); Can be sufficiently heat exchanged.

  According to the eighth invention, the network structure (60) composed of the moisture permeable tube (43) and the heat transfer tube (48) can be simplified.

  According to the ninth aspect, the humidity control module (40) can be realized compactly with a simple configuration.

  According to the tenth invention, the humidity control module (40) of the first to ninth inventions can be downsized by suppressing the temperature change of the liquid absorbent, and the liquid absorbent can absorb moisture or Since it has an excellent characteristic that it can reduce the energy required to release moisture, the humidity control device (10) including the humidity control module (40) can be made compact, Energy efficiency can be improved.

FIG. 1 is a plan view schematically showing the structure of a humidity control apparatus according to Embodiment 1 of the present invention. FIG. 2 is a circuit diagram showing configurations of an absorbent circuit and a refrigerant circuit provided in the humidity control apparatus according to Embodiment 1 of the present invention. FIG. 3 is a perspective view schematically showing the structure of the humidity control module constituting the humidity control apparatus according to Embodiment 1 of the present invention. FIG. 4 is a cross-sectional view showing an intersection of a moisture permeable tube and a heat transfer tube in a network structure provided in the humidity control module according to Embodiment 1 of the present invention. FIG. 5 is a perspective view schematically showing the structure of the humidity control module according to the second embodiment of the present invention. FIG. 6 is a cross-sectional view showing an intersection of a moisture permeable tube and a heat transfer tube in a network structure provided in a humidity control module according to Embodiment 2 of the present invention. FIG. 7: is sectional drawing which shows the cross | intersection part of the moisture permeable tube and heat exchanger tube in the network structure provided in the humidity control module which concerns on Embodiment 2 of this invention. FIG. 8 is a perspective view schematically showing the structure of a humidity control module according to a modification of Embodiment 2 of the present invention. FIG. 9 is a front view schematically showing the structure of the humidity control module according to the third embodiment of the present invention. FIG. 10: is a front view which shows roughly the structure of the humidity control module which concerns on the modification of Embodiment 3 of this invention. FIG. 11 is a configuration diagram schematically showing a humidity control apparatus according to another embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1 of the Invention
The humidity controller (10) according to the first embodiment is an absorption humidity controller that adjusts the humidity of room air by dehumidifying and humidifying air using a liquid absorbent.

-Configuration of humidity control device-
The humidity control apparatus (10) of this embodiment is demonstrated referring FIG.1 and FIG.2.

  As shown in FIG. 1, the humidity control apparatus (10) of this embodiment is provided with a casing (20). The casing (20) is formed in a rectangular parallelepiped box shape. An external air suction port (21) and an exhaust port (24) are formed on one end face of the casing (20). An air supply port (22) and an inside air suction port (23) are formed on the other end face of the casing (20). The internal space of the casing (20) is partitioned into an air supply passage (25) and an exhaust passage (26).

  The air supply passage (25) communicates with the outside air suction port (21) and the air supply port (22). In the air supply passage (25), an air supply fan (27) which is an air supply means and an air supply side module (40a) which is a first humidity control module are arranged. On the other hand, the exhaust passage (26) communicates with the inside air suction port (23) and the exhaust port (24). In the exhaust passage (26), an exhaust fan (28) as air supply means and an exhaust side module (40b) as a second humidity control module are arranged.

  In addition to the air supply fan (27), the air supply side module (40a), the exhaust fan (28), and the exhaust side module (40b), the casing (20) includes an absorbent circuit (30) shown in FIG. A refrigerant circuit (35) which is a heat medium circuit is accommodated.

  As shown in FIG. 2, the absorbent circuit (30) is a closed circuit in which an air supply side module (40a), an exhaust side module (40b), and a pump (31) are connected. In this absorbent circuit (30), the discharge side of the pump (31) is at the inlet of the absorbent passage (41b) of the exhaust side module (40b), and the outlet of the absorbent passage (41b) of the exhaust side module (40b) is The inlet of the absorbent passage (41a) of the supply side module (40a) and the outlet of the absorbent passage (41a) of the supply side module (40a) are connected to the suction side of the pump (31). The absorbent circuit (30) is filled with, for example, an aqueous lithium chloride solution as a liquid absorbent.

  The refrigerant circuit (35) is a closed circuit in which a compressor (36), a four-way switching valve (37), an expansion valve (38), an air supply side module (40a), and an exhaust side module (40b) are connected. Circuit. In this refrigerant circuit (35), the discharge side of the compressor (36) is connected to the first port of the four-way switching valve (37), and the suction side of the compressor (36) is connected to the second port of the four-way switching valve (37). Is done. Further, in this refrigerant circuit (35), the heat transfer member (46b) of the exhaust side module (40b), the expansion valve (38), and the like in order from the third port to the fourth port of the four-way switching valve (37). The heat transfer member (46a) of the air supply side module (40a) is disposed. The refrigerant circuit (35) performs a vapor compression refrigeration cycle by circulating the filled refrigerant. The refrigerant circuit (35) supplies the refrigerant as a heat medium for heating or cooling to the air supply side module (40a) and the exhaust side module (40b).

  The four-way switching valve (37) is switched between a first state (state indicated by a solid line in FIG. 2) and a second state (state indicated by a broken line in FIG. 2). In the four-way switching valve (37) in the first state, the first port communicates with the third port, and the second port communicates with the fourth port. On the other hand, in the four-way switching valve (37) in the second state, the first port communicates with the fourth port, and the second port communicates with the third port.

-Configuration of humidity control module-
The supply side module (40a) and the exhaust side module (40b) are both configured by a humidity control module (40) having the same configuration. Here, the humidity control module (40) will be described with reference to FIGS. 3 and 4 as appropriate.

  The humidity control module (40) humidifies or dehumidifies air using a liquid absorbent. As shown in FIG. 3, the humidity control module (40) includes an absorbent passage (41), a heat transfer member (46), and an air passage (50). The absorbent passage (41) includes a pair of absorbent headers (42) and a plurality of moisture permeable tubes (43). The heat transfer member (46) includes a pair of refrigerant headers (47) and a plurality of heat transfer tubes (48).

  The pair of absorbent headers (42) are formed in a flat rectangular box shape, and are disposed, for example, facing each other in the vertical direction. One absorbent header (42) constitutes a liquid supply header (42a) into which liquid absorbent is supplied from the absorbent circuit (30). The other absorbent header (42) constitutes a drain side header (42b) for discharging the internal liquid absorbent to the absorbent circuit (30).

  The pair of refrigerant headers (47) are formed in a flat rectangular box shape like the absorbent header (42), and are disposed to face each other in the left-right direction, for example, so as to form a right angle with the pair of absorbent headers (42). ing. One refrigerant header (47) is supplied with refrigerant from the refrigerant circuit (35) when the four-way switching valve (37) is in the first state and is refrigerant circuit when the four-way switching valve (37) is in the second state. A first refrigerant header (47a) for discharging the internal refrigerant to (35) is configured. The other refrigerant header (47) discharges the internal refrigerant to the refrigerant circuit (35) when the four-way switching valve (37) is in the first state, and the refrigerant circuit when the four-way switching valve (37) is in the second state. The second refrigerant header (47b) to which the refrigerant is supplied from (35) is configured.

  The pair of absorbent header (42) and the pair of refrigerant headers (47) are joined to each other to partition an air passage (50) through which air flows. The air passage (50) communicates with the air supply passage (25) or the exhaust passage (26) through the ventilation port (49). The air supplied from the air supply fan (27) or the exhaust fan (28) flows through the air passage (50). A plurality of moisture permeable tubes (43) and a plurality of heat transfer tubes (48) are installed in the air passage (50).

  Each of the plurality of moisture permeable tubes (43) is a straight tube extending in a straight line, and is mutually connected between the pair of absorbent headers (42), that is, across the air passage (50) in the height direction. It extends in a posture in which the axial directions are parallel. Both ends of each moisture permeable tube (43) are connected to a pair of absorbent headers (42), respectively, and the pair of absorbent headers (42) communicate with each other through each moisture permeable tube (43). The liquid absorbent supplied from the absorbent circuit (30) to the liquid supply side header (42a) is branched and sent from the liquid supply side header (42a) to the plurality of moisture permeable tubes (43). It flows inside the wet tube (43). Then, the liquid absorbent flowing in the plurality of moisture permeable tubes (43) is sent to the drain side header (42b), merges, and is discharged from the drain side header (42b) to the absorbent circuit (30). Is done. Thus, the liquid absorbent circulating through the absorbent circuit (30) flows through each moisture permeable tube (43).

  The plurality of moisture permeable tubes (43) are provided at intervals of about several mm (for example, 1 mm to 3 mm). The moisture permeable tubes (43) are aligned in the width direction of the air passage (50) (left and right in FIG. 3) to form a vertical lattice (60a). The vertical lattice (60a) is provided in a plurality of rows (two rows in the example shown in FIG. 3) along the air flow direction of the air passage (50). Each moisture permeable tube (43) is formed by forming a membrane that does not transmit a liquid absorbent but allows water vapor to pass, that is, a so-called moisture permeable membrane, into a tubular shape. As the moisture permeable membrane, for example, a hydrophobic porous membrane made of a fluororesin such as PTFE (polytetrafluoroethylene, tetrafluoroethylene resin) can be used. The diameter of each moisture permeable tube (43) is, for example, about 1 mm.

  Each of the plurality of heat transfer tubes (48) is a straight tube extending in a straight line, and the moisture permeable tube (43) crosses the air passage (50) in the width direction between the pair of refrigerant headers (47). ) In such a manner that the axial directions thereof are parallel to each other in a direction orthogonal to. Both ends of each heat transfer tube (48) are connected to a pair of refrigerant headers (47), respectively, and the pair of refrigerant headers (47) communicate with each other via each heat transfer tube (48). The refrigerant supplied from the refrigerant circuit (35) to one refrigerant header (47) is branched from the refrigerant header (47) and sent to a plurality of heat transfer tubes (48). Flows inside. Then, the refrigerant flowing through the plurality of heat transfer tubes (48) is sent to the other refrigerant header (47) to join, and is discharged from the refrigerant header (47) to the refrigerant circuit (35). Thus, the refrigerant circulating through the refrigerant circuit (35) flows through each heat transfer tube (48).

  The plurality of heat transfer tubes (48) are provided at intervals of about several mm (for example, 1 mm to 3 mm). The heat transfer tubes (48) are aligned in the height direction (vertical direction in FIG. 3) of the air passage (50) to form a horizontal lattice (60b). The horizontal grid (60b) is provided in a plurality of rows (two rows in the example shown in FIG. 3) along the air flow direction of the air passage (50) corresponding to the vertical grid (60a). Each heat transfer tube (48) is a resin tube made of a resin such as PEEK (polyetheretherketone), and has flexibility. The diameter of each heat transfer tube (48) is, for example, about 1 mm.

  The vertical lattice (60a) formed by the moisture permeable tube (43) and the horizontal lattice (60b) formed by the heat transfer tube (48) are arranged adjacent to each other in the length direction of the air passage (50). The adjacent vertical lattice (60a) and horizontal lattice (60b) constitute a network structure (60) in which a plurality of moisture permeable tubes (43) and a plurality of heat transfer tubes (48) are assembled in a lattice shape. . A plurality of (two in the example shown in FIG. 3) network structures (60) are provided along the air flow direction of the air passage (50) according to the number of vertical lattices (60a) and horizontal lattices (60b). Yes.

  In this network structure (60), as shown in FIGS. 3 and 4, a plurality of moisture permeable tubes (43) and a plurality of heat transfer tubes (48) are orthogonal to each other at a plurality of locations. ing. In the network structure (60), air in the air passage (50) flows between the lattices of the moisture permeable tube (43) and the heat transfer tube (48). Each heat transfer tube (48) exchanges heat between the liquid absorbent in the moisture permeable tube (43) and the internal heat medium at the contact point with the moisture permeable tube (43). Therefore, the liquid absorbent flowing in each moisture permeable tube (43) is given the hot or cold heat of the refrigerant in the heat transfer tube (48) at a plurality of locations. Further, each moisture permeable tube (43) is in contact with the air flowing through the air passage (50) except for the contact portion with the heat transfer tube (48), and the air flowing through the air passage (50) and the internal liquid absorption. Give water to and from the agent.

  The density of the moisture permeable tube (43) and the heat transfer tube (48) constituting the network structure (60), that is, the size of the mesh (interstitial space) defined by the moisture permeable tube (43) and the heat transfer tube (48) is It is set in consideration of the relationship between the pressure loss of the air sent to the air passage (50) by the pump (31) and the humidity control capacity of the air passage (50) with respect to the air.

  In the air supply side module (40a) constituted by the humidity control module (40), the second refrigerant header (47b) of the heat transfer member (46a) is connected to the fourth port of the four-way switching valve (37), The first refrigerant header (47a) of the heat transfer member (46a) is connected to the expansion valve (38). On the other hand, in the exhaust side module (40b) constituted by the humidity control module (40), the first refrigerant header (47a) of the heat transfer member (46) is connected to the third port of the four-way switching valve (37). The second refrigerant header (47b) of the heat transfer member (46) is connected to the expansion valve (38).

-Operation of humidity control device-
Next, the operation of the humidity control apparatus (10) will be described. The humidity control apparatus (10) selectively performs a dehumidifying operation for dehumidifying the air supply to the room and a humidifying operation for humidifying the air supply to the room.

<Dehumidifying operation>
First, the dehumidifying operation of the humidity control apparatus (10) will be described with reference to FIGS.

  During the dehumidifying operation, the four-way switching valve (37) of the refrigerant circuit (35) is set to the first state (that is, the state indicated by the solid line in FIG. 2). Further, during the dehumidifying operation, the compressor (36) is operated, and the opening degree of the expansion valve (38) is appropriately adjusted. In the refrigerant circuit (35) during the dehumidifying operation, a vapor compression refrigeration cycle is performed by circulating the refrigerant. In the refrigerant circuit (35) during the dehumidifying operation, the heat transfer member (46b) of the exhaust side module (40b) serves as a condenser, and the heat transfer member (46a) of the supply side module (40a) serves as an evaporator. .

  The refrigerant flow in the refrigerant circuit (35) will be described in detail. The high-temperature and high-pressure gas refrigerant discharged from the compressor (36) passes through the four-way switching valve (37) and is supplied to the exhaust-side module (40b) as a heating heat medium. The refrigerant supplied to the heat transfer member (46b) of the exhaust side module (40b) passes through each moisture permeable tube at a plurality of contact points between each heat transfer tube (48) and each moisture permeable tube (43) shown in FIG. (43) The heat is dissipated and condensed in the liquid absorbent flowing inside, and then discharged from the exhaust side module (40b). The refrigerant discharged from the exhaust side module (40b) is reduced in pressure when passing through the expansion valve (38) to become a low-temperature and low-pressure refrigerant in a gas-liquid two-phase state, and serves as a cooling heat medium. ). The refrigerant that has flowed into the heat transfer member (46a) of the air supply side module (40a) passes through each moisture permeable tube at a plurality of contact points between each heat transfer tube (48) and each moisture permeable tube (43) shown in FIG. (43) The liquid absorbent flowing inside absorbs heat and evaporates, and is then discharged from the air supply side module (40a). The refrigerant discharged from the supply side module (40a) passes through the four-way switching valve (37) and is sucked into the compressor (36). The compressor (36) compresses and discharges the sucked refrigerant.

  Further, during the dehumidifying operation, the pump (31) of the absorbent circuit (30) is operated, and the liquid absorbent circulates in the absorbent circuit (30).

  The liquid absorbent discharged from the pump (31) is supplied to the absorbent passage (41b) of the exhaust side module (40b). The liquid absorbent supplied to the absorbent passage (41b) passes through the heat transfer tube (48) at a plurality of contact points between the moisture permeable tubes (43) and the heat transfer tubes (48) shown in FIG. Heated by flowing refrigerant. At this time, exhaust (that is, indoor air discharged outside the room) flows through the air passage (50) of the exhaust module (40b). In this exhaust side module (40b), a part of the water contained in the liquid absorbent becomes water vapor, which passes through the moisture permeable tube (43) and is given to the exhaust flowing through the air passage (50). The water vapor imparted to the exhaust is discharged to the outside together with the exhaust. Thus, in the exhaust side module (40b), a part of the water contained in the liquid absorbent in the absorbent passage (41b) passes through each moisture permeable tube (43) and is given to the exhaust. Therefore, in the exhaust side module (40b), the concentration of the liquid absorbent gradually increases while passing through the moisture permeable tube (43).

  The high concentration liquid absorbent supplied from the exhaust side module (40b) is supplied to the absorbent passage (41a) of the air supply side module (40a). The liquid absorbent supplied to the absorbent passage (41a) passes through the heat transfer tube (48) at a plurality of contact points between the moisture permeable tubes (43) and the heat transfer tubes (48) shown in FIG. It is cooled by the flowing refrigerant. At this time, air supply (that is, outdoor air supplied to the room) flows in the air passage (50) of the air supply side module (40a). In the air supply side module (40a), water vapor contained in the air supply passes through each moisture permeable tube (43) and is absorbed by the liquid absorbent flowing through the moisture permeable tube (43). The supply air dehumidified while passing through the air passage (50) of the supply-side module (40a) is supplied to the room thereafter. Thus, in the air supply side module (40a), a part of the water vapor contained in the air supply in the air passage (50) is absorbed by the liquid absorbent through each moisture permeable tube (43). Therefore, in the supply side module (40a), the concentration of the liquid absorbent gradually decreases while passing through the moisture permeable tube (43). The low concentration liquid absorbent discharged from the supply side module (40a) is sucked into the pump (31) and sent out toward the exhaust side module (40b).

<Humidification operation>
The humidification operation of the humidity control apparatus (10) will be described with reference to FIG.

  During the humidifying operation, the four-way switching valve (37) of the refrigerant circuit (35) is set to the second state (that is, the state indicated by the broken line in FIG. 2). Further, during the humidifying operation, the compressor (36) is operated, and the opening degree of the expansion valve (38) is appropriately adjusted. In the refrigerant circuit (35) during the humidifying operation, a vapor compression refrigeration cycle is performed by circulating the refrigerant. Further, in the refrigerant circuit (35) during the humidifying operation, the heat transfer member (46a) of the supply side module (40a) serves as a condenser, and the heat transfer member (46b) of the exhaust side module (40b) serves as an evaporator. .

  The refrigerant flow in the refrigerant circuit (35) will be described in detail. The high-temperature and high-pressure gas refrigerant discharged from the compressor (36) passes through the four-way switching valve (37) and is supplied to the supply-side module (40a) as a heating medium. The refrigerant supplied to the heat transfer member (46a) of the air supply side module (40a) passes through each moisture permeability at a plurality of contact points between each heat transfer pipe (48) and each moisture transmission pipe (43) shown in FIG. It dissipates heat to the liquid absorbent flowing in the pipe (43), condenses, and then is discharged from the air supply side module (40a). The refrigerant discharged from the supply side module (40a) is reduced in pressure when passing through the expansion valve (38) to become a low-temperature and low-pressure refrigerant in a gas-liquid two-phase state, and the exhaust-side module (40b) is used as a cooling heat medium. ). The refrigerant that has flowed into the heat transfer member (46b) of the exhaust side module (40b) passes through each moisture permeable tube (at each of the contact points between each heat transfer tube (48) and each moisture permeable tube (43) shown in FIG. 43) The liquid absorbent flowing inside absorbs heat and evaporates, and is then discharged from the exhaust side module (40b). The refrigerant discharged from the exhaust side module (40b) passes through the four-way switching valve (37) and is sucked into the compressor (36). The compressor (36) compresses and discharges the sucked refrigerant.

  Further, during the humidifying operation, the pump (31) of the absorbent circuit (30) is operated, and the liquid absorbent circulates in the absorbent circuit (30).

  The liquid absorbent discharged from the pump (31) is supplied to the absorbent passage (41b) of the exhaust side module (40b). The liquid absorbent supplied to the absorbent passage (41b) passes through each heat transfer tube (48) at a plurality of contact points between each moisture permeable tube (43) and each heat transfer tube (48) shown in FIG. It is cooled by the flowing refrigerant. At this time, exhaust (that is, indoor air exhausted to the outside) flows in the air passage (50) of the exhaust side module (40b). In the exhaust side module (40b), water vapor contained in the exhaust passes through the moisture permeable tube (43) and is absorbed by the liquid absorbent flowing through the absorbent passage (41b). The exhaust gas deprived of water vapor is then discharged outside the room. Thus, in the exhaust side module (40b), a part of the water vapor contained in the exhaust of the air passage (50) passes through each moisture permeable tube (43) and is absorbed by the liquid absorbent. Therefore, in the exhaust side module (40b), the concentration of the liquid absorbent gradually decreases while passing through the moisture permeable tube (43).

  The low concentration liquid absorbent flowing out from the exhaust side module (40b) is supplied to the absorbent passage (41a) of the air supply side module (40a). The liquid absorbent supplied to the absorbent passage (41a) flows through each heat transfer tube (48) at a plurality of contact points between each moisture permeable tube (43) and each heat transfer tube (48) shown in FIG. Heated by the refrigerant. At this time, supply air (that is, outdoor air supplied to the room) flows through the air passage (50) of the supply side module (40a). In this air supply side module (40a), a part of the water contained in the liquid absorbent becomes water vapor, passes through the moisture permeable tube (43), and is given to the air supplied through the air passage (50). The air supply humidified while passing through the air passage (50) of the air supply side module (40a) is then supplied into the room. Thus, in the air supply side module (40a), a part of the water contained in the liquid absorbent in the absorbent passage (41a) passes through each moisture permeable tube (43) and is given to the air supply. Therefore, in the supply side module (40a), the concentration of the liquid absorbent gradually increases while passing through the moisture permeable tube (43). The high-concentration liquid absorbent discharged from the supply side module (40a) is sucked into the pump (31) and sent out toward the exhaust side module (40b).

-Operation of humidity control module-
Operation | movement of the humidity control module (40) which comprises an air supply side module (40a) and an exhaust side module (40b) is demonstrated. The humidity control module (40) selectively performs a moisture absorption operation for causing the liquid absorbent to absorb water vapor and a moisture release operation for releasing the water vapor from the liquid absorbent. During the dehumidifying operation described above, the air supply side module (40a) performs a moisture absorption operation, and the exhaust side module (40b) performs a moisture release operation. Moreover, at the time of the humidification operation mentioned above, the exhaust side module (40b) performs a moisture absorption operation, and the air supply side module (40a) performs a moisture release operation.

<Hygroscopic operation>
The moisture absorption operation of the humidity control module (40) will be described with reference to FIG.

  During the moisture absorption operation, a relatively high concentration liquid absorbent is supplied to the absorbent passage (41) of the humidity control module (40). A part of the water vapor contained in the air in the air passage (50) passes through the plurality of moisture permeable tubes (43) shown in FIG. 3 and is absorbed by the liquid absorbent.

  When the liquid absorbent absorbs water vapor, heat of absorption is generated. For this reason, if no measures are taken, the temperature of the liquid absorbent gradually rises due to the generated heat of absorption, and the amount of water vapor absorbed by the liquid absorbent decreases as the temperature rises. Moreover, when the temperature of the air which flows through an air path (50) is higher than the temperature of a liquid absorbent, the temperature of a liquid absorbent rises also by heat exchange with air.

  In contrast, in the humidity control module (40) during the moisture absorption operation, the heat transfer member (46) functions as an evaporator, and the liquid flowing in each moisture permeable tube (43) constituting the absorbent passage (41). The absorbent is intermittently cooled by the refrigerant in the heat transfer tube (48) at a plurality of contact points between the moisture permeable tube (43) and the heat transfer tube (48). As a result, the amount of heat that the liquid absorbent rises in temperature due to the action of absorption heat while flowing in the moisture permeable tube (43) is absorbed by the heat medium flowing in the heat transfer tube (48). Therefore, even if absorption heat is generated when the liquid absorbent absorbs water vapor, an increase in the temperature of the liquid absorbent flowing in the moisture permeable tube (43) can be suppressed.

<Damping action>
The moisture release operation of the humidity control module (40) will be described with reference to FIG.

  During the moisture release operation, a relatively low concentration liquid absorbent is supplied to the absorbent passage (41) of the humidity control module (40). And a part of the water | moisture content contained in a liquid absorbent becomes water vapor | steam, permeate | transmits each moisture permeable tube (43) shown in FIG. 3, and is provided to the air of an air path (50).

  When water is released from the liquid absorbent, it takes heat away from the surroundings when the liquid water vaporizes. For this reason, if no measures are taken, the temperature of the liquid absorbent gradually decreases, and the amount of water vapor released from the liquid absorbent decreases as the temperature decreases. Moreover, when the temperature of the air which flows through an air path (50) is lower than the temperature of a liquid absorbent, the temperature of a liquid absorbent falls also by heat exchange with air.

  On the other hand, in the humidity control module (40) during the moisture release operation, the heat transfer member (46) functions as a condenser and flows through each moisture permeable tube (43) constituting the absorbent passage (41). The liquid absorbent is intermittently heated by the refrigerant in the heat transfer tube (48) at a plurality of contact points between the moisture permeable tube (43) and the heat transfer tube (48). As a result, the amount of heat that the liquid absorbent cools down due to the vaporization of moisture while flowing in the moisture permeable tube (43) is quickly compensated by the refrigerant flowing in the heat transfer tube (48). Therefore, even if heat is taken away from the surroundings in the process of vaporization of the water contained in the liquid absorbent, the temperature drop of the liquid absorbent flowing in the moisture permeable tube (43) can be suppressed.

-Effect of Embodiment 1-
According to the first embodiment, the plurality of moisture permeable tubes (43) and the plurality of heat transfer tubes (48) installed in the air passage (50) form a network structure (60). In this network structure (60), each moisture permeable tube (43) and each heat transfer tube (48) intersect each other in a state where they are in contact with each other at a plurality of locations, so that liquid absorption flowing into the moisture permeable tube (43) is absorbed. Moisture is exchanged between the air flowing through the air passage (50) and the liquid absorbent in the moisture permeable tube (45) while the heat medium or the cold heat of the heat transfer medium in the heat transfer tube (48) is applied to the agent at multiple locations. The Therefore, the temperature change of the liquid absorbent that occurs when the liquid absorbent transfers air and moisture can be suppressed, and as a result, the humidity control module (40) can be downsized. Thereby, compactness can be achieved also as a humidity control apparatus (10) provided with the humidity control module (40).

  Further, according to the first embodiment, since the liquid absorbent and the heat medium exchange heat in the air passage (50) through which air and the liquid absorbent exchange moisture, moisture absorption as disclosed in Patent Document 1 is performed. Compared to cooling or heating the liquid absorbent at a position distant from the head and moisture release section, there is almost no heat loss of the liquid absorbent that occurs between the time when the liquid absorbent is cooled or heated and before the exchange of air and moisture. The liquid absorbent need not be excessively cooled or heated in anticipation of temperature changes of the liquid absorbent due to the absorption or release of water vapor. Therefore, in the humidity control module (40), it is possible to reduce energy required to cause the liquid absorbent to absorb moisture or release moisture. Thereby, also as a humidity control apparatus (10) provided with the humidity control module (40), energy efficiency can be improved.

-Modification of Embodiment 1-
In the humidity control module (40) of the present embodiment, each heat transfer tube (48) may be a copper capillary tube. The copper capillary tube has high thermal conductivity and is suitable for the heat transfer tube (48). Therefore, the heat medium flowing in the heat transfer tube (48) and the liquid absorbent flowing in the moisture permeable tube (43) are sufficient. Heat exchange.

<< Embodiment 2 of the Invention >>
The humidity control apparatus (10) of the second embodiment includes a humidity control module (40) having a configuration different from that of the humidity control module (40) of the first embodiment. In each of the following embodiments, the humidity control device (10) is configured in the same manner as in the first embodiment except that the configuration of the humidity control module (40) is different from that in the first embodiment. Only the wet module (40) will be described, and the same components will be left to the description of the first embodiment based on FIGS. 1 to 4, and detailed description thereof will be omitted.

  The humidity control module (40) of the present embodiment will be described with reference to FIGS. In the humidity control module (40) of the present embodiment, as shown in FIG. 5, each network structure (60) has a plurality of moisture permeable tubes (43) and a plurality of heat transfer tubes (48) in a plain weave shape. It is assembled and configured.

  As shown in FIGS. 5 and 6, each moisture permeable tube (43) constituting the network structure (60) is a meandering tube, and a plurality of heat transfer tubes (48) constituting the network structure (60). The shape meanders between the two. The adjacent moisture permeable tubes (43) are in contact with the heat transfer tubes (48) on the opposite sides at the intersections with the individual heat transfer tubes (48), and have a positional relationship with the heat transfer tubes (48). The air passage (50) alternates in the air flow direction. Each of the moisture permeable tubes (43) is in contact with a part of the outer peripheral surface of each heat transfer tube (48) along the circumferential direction thereof.

  Each of the heat transfer tubes (48) constituting the network structure (60) is also a meandering tube, as shown in FIGS. 5 and 7, and a plurality of moisture permeable tubes ( 43) has a meandering shape. Adjacent heat transfer tubes (48) are in contact with the moisture permeable tubes (43) on opposite sides at the intersections with the individual moisture permeable tubes (43). The relationship is alternated in the air flow direction of the air passage (50). And each of these heat exchanger tubes (48) is contacting a part of outer peripheral surface of each moisture permeable tube (43) along the circumferential direction.

-Effect of Embodiment 2-
According to the second embodiment, each moisture permeable tube (43) and each heat transfer tube (48) are meandering tubes, and each moisture permeable tube (43) contacts along the outer peripheral surface of the heat transfer tube (48). Since each heat transfer tube (48) is in contact with the outer peripheral surface of the moisture permeable tube (43), both the moisture permeable tube (43) and the heat transfer tube (48 )) Are simply in contact at the intersection, the moisture permeation tube (43) and the heat transfer tube (48) are in contact with each other along the circumferential direction. The contact area between the wet tube (43) and the heat transfer tube (48) is increased, and the heat exchange rate between the liquid absorbent flowing in the moisture permeable tube (43) and the refrigerant flowing in the heat transfer tube (48) is improved. Can do.

-Modification of Embodiment 2-
The humidity control module (40) of this modification will be described with reference to FIG. In the humidity control module (40) of the present embodiment, as shown in FIG. 8, each heat transfer tube (48) constituting the network structure (60) is a straight tube extending linearly, and each moisture permeable tube (43) Only the serpentine tube may be used. In this case, each heat transfer tube (48) may be a copper capillary tube. The adjacent moisture permeable tubes (43) are in contact with the heat transfer tubes (48) on the same side at the intersections with the individual heat transfer tubes (48), and extend parallel to each other and swell in the same direction. May be present.

  In addition, each moisture permeable tube (43) constituting the network structure (60) may be a straight tube extending linearly, and only each heat transfer tube (48) may be a serpentine tube. Also in this case, the adjacent heat transfer tubes (48) are in contact with the heat transfer tubes (48) on the same side at the intersections with the individual moisture permeable tubes (43) and swell in the same direction in parallel with each other. It may have a shape.

<< Embodiment 3 of the Invention >>
The humidity control module (40) of the third embodiment will be described with reference to FIG. As shown in FIG. 9, the humidity control module (40) of the present embodiment is a meandering tube instead of the plurality of heat transfer tubes (48) constituting each horizontal lattice (60b) in the first embodiment. A heat transfer tube (48) is provided.

  The heat transfer tube (48) of the present embodiment extends from the vicinity of the upper end of the air passage (50) to the vicinity of the lower end while meandering left and right in the width direction of the air passage (50). The heat transfer tube (48) has a plurality of horizontal lattice portions (48a) and a plurality of folded portions (48b). Each horizontal lattice portion (48a) extends in a straight line in a direction orthogonal to each of the moisture permeable tubes (43) in a region where a plurality of moisture permeable tubes (43) extend, and constitutes a horizontal lattice (60b). . Each folded portion (48b) connects the ends of the adjacent horizontal lattice portions (48a). Moreover, the humidity control module (40) of this embodiment is not provided with the refrigerant header (47), and the air passage (50) is partitioned by a frame-like member (51) having a depth.

  In the humidity control module (40) of the present embodiment, a network structure (60) is formed by the plurality of moisture permeable tubes (43) and one heat transfer tube (48). In the network structure (60), the moisture permeable tubes (43) and the heat transfer tubes (48) are orthogonal to each other at a plurality of locations. The heat transfer tube (48) exchanges heat between the liquid absorbent in the moisture permeable tube (43) and the internal refrigerant at the contact point with the moisture permeable tube (43). Therefore, the liquid absorbent flowing in each moisture permeable tube (43) is given the hot or cold heat of the refrigerant in the heat transfer tube (48) at a plurality of locations. Further, each moisture permeable tube (43) is in contact with the air flowing through the air passage (50) except for the contact portion with the heat transfer tube (48), and the air flowing through the air passage (50) and the internal liquid absorption. Give water to and from the agent.

-Effect of Embodiment 3-
Also according to the third embodiment, the humidity control module (40) can be reduced in size by suppressing the temperature change of the liquid absorbent, and the humidity control device (10) can be downsized, and the humidity control module (40). The energy required for absorbing or releasing moisture in the liquid absorbent can be reduced, and the energy efficiency of the humidity control apparatus (10) can also be improved.

-Modification of Embodiment 3-
The humidity control module (40) of this modification will be described with reference to FIG. As shown in FIG. 10, the humidity control module (40) of this embodiment includes a plurality of moisture permeable tubes (43) and a plurality of horizontal lattice portions (48a) in the heat transfer tubes (48). The moisture permeable tube (43) and the heat transfer tube (48) may be assembled in a plain weave shape.

  According to this modification, the moisture permeable tube (43) and the heat transfer tube (48) are in contact with the outer peripheral surfaces of the moisture permeable tube (43) and the heat transfer tube (48) along the circumferential direction. The contact area of the liquid can be increased, and the heat exchange rate between the liquid absorbent flowing in the moisture permeable tube (43) and the refrigerant flowing in the heat transfer tube (48) can be improved.

<< Other Embodiments >>
As shown in FIG. 11, in the humidity control apparatus (10) of each embodiment described above, the air supply side module (40a) and the exhaust side module (40b) may be arranged in separate units.

  Specifically, the humidity control apparatus (10) of the present modification includes an outdoor unit (15) and an indoor unit (17). The outdoor unit (15) includes a pump (31) of the absorbent circuit (30), a compressor (36) of the refrigerant circuit (35), a four-way switching valve (37) and an expansion valve (38), and an exhaust side module. (40b) is housed. The outdoor unit (15) is provided with an outdoor fan (16) for supplying outdoor air to the exhaust side module (40b). On the other hand, the air supply side module (40a) is accommodated in the indoor unit (17). The indoor unit (17) is provided with an indoor fan (18) for supplying room air to the air supply side module (40a).

  During the dehumidifying operation, in the humidity control apparatus (10) of this variation, the indoor air dehumidified in the air supply side module (40a) is sent back to the room, and the outdoor air humidified in the exhaust side module (40b) is discharged to the outside of the room. . On the other hand, during the humidification operation, the humidity control apparatus (10) of the present modified example sends the indoor air humidified in the air supply side module (40a) back to the room and the outdoor air dehumidified in the exhaust side module (40b) to the outside. Discharge.

  As mentioned above, although preferable embodiment and its modification of this invention were described, the technical scope of this invention is not limited to the range as described in the said embodiment and its modification. Those skilled in the art will appreciate that the above-described embodiment and its modifications are examples, and that various modifications can be made to the combination of each component and each processing process, and such modifications are also within the scope of the present invention. Is understood.

  As described above, the present invention is useful for a humidity control module that adjusts the humidity of air using a liquid absorbent and a humidity control apparatus including the same, and in particular, by suppressing temperature changes of the liquid absorbent. It is suitable for a humidity control module and a humidity control apparatus including the humidity control module that are required to be downsized.

10 Humidity control device
27 Air supply fan (air supply means)
28 Exhaust fan (air supply means)
30 Absorbent circuit
35 Refrigerant circuit (heat medium circuit)
40 Humidity control module
40a Supply side module
40b Exhaust side module
42 Absorbent header
43 Breathable tube
47 Refrigerant header (heat medium header)
48 Heat transfer tube
50 Air passage
60 Reticulated structure

Claims (10)

A humidity control module that humidifies or dehumidifies air using a liquid absorbent,
The liquid absorbent is constituted by a film that allows water vapor to permeate without permeating, and a moisture permeable tube (43) through which the liquid absorbent flows,
A heat transfer tube (48) for allowing a heat medium for heating or cooling to flow inside, and for exchanging heat between the liquid absorbent in the moisture permeable tube (43) and the internal heat medium;
The moisture permeable tube (43) and the heat transfer tube (48) are installed, and include an air passage (50) through which air for transferring and receiving moisture with the liquid absorbent flows,
The humidity control module, wherein the moisture permeable tube (43) and the heat transfer tube (48) form a network structure (60) that intersects with each other at a plurality of locations. The humidity control module according to claim 1,
The humidity control module is characterized in that the moisture permeable tube (43) and the heat transfer tube (48) constituting the network structure (60) extend in directions orthogonal to each other, and a plurality of them are provided at intervals. In the humidity control module according to claim 1 or 2,
A humidity control module, wherein a plurality of the network structures (60) are provided along the air flow direction of the air passage (50). In the humidity control module according to claim 2 or 3,
The moisture permeable tube (43) constituting the network structure (60) is a meandering tube meandering between a plurality of heat transfer tubes (48) constituting the network structure (60), and the heat transfer tube (48) A humidity control module, wherein the humidity control module is in contact with a part of the outer peripheral surface of the slab along the circumferential direction. In the humidity control module described in any one of Claims 2-4,
The heat transfer pipe (48) constituting the network structure (60) is a meandering pipe meandering between a plurality of moisture permeable pipes (43) constituting the network structure (60), and the moisture permeable pipe (43 The humidity control module is in contact with a part of the outer peripheral surface of the component along the circumferential direction. In the humidity control module according to claim 5,
The humidity control module, wherein the heat transfer tube (48) is a resin tube. In the humidity control module described in any one of Claims 1-5,
The humidity control module, wherein the heat transfer tube (48) is a copper capillary tube. In the humidity control module according to claim 2,
The humidity control module, wherein the moisture permeable tube (43) and the heat transfer tube (48) are straight tubes extending linearly. In the humidity control module described in any one of Claims 2-8,
Both ends of the plurality of moisture permeable tubes (43) are respectively connected to a pair of absorbent headers (42) arranged to face each other,
Both ends of the plurality of heat transfer tubes (48) are respectively connected to a pair of heat medium headers (47) arranged to face each other,
The humidity control module, wherein the pair of absorbent headers (42) and the pair of heat medium headers (47) partition the air passage (50). The humidity control module (40) according to any one of claims 1 to 9,
An absorbent circuit (30) for supplying a liquid absorbent to the moisture permeable tube (43) of the humidity control module (40);
A heat medium circuit (35) for supplying a heat medium for heating or cooling to the heat transfer tube (48) of the humidity control module (40);
Air supply means (27, 28) for supplying air to the air passage (50) of the humidity control module (40),
A humidity control apparatus for dehumidifying or humidifying air flowing in an air passage (50) of the humidity control module (40).

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