JP6458885B2 - Humidity control device - Google Patents

Description

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

  As an apparatus for adjusting the humidity in the room, there is a type in which a liquid having hygroscopicity is used as a liquid absorbent as disclosed in Patent Document 1.

  The humidity control apparatus of Patent Literature 1 includes a dehumidifying unit (processing device) that dehumidifies the room and a regenerating unit (reproducing device) that regenerates the liquid absorbent used for dehumidification. The dehumidifying unit (processor) absorbs moisture in the air by passing the air to be treated through the cooled liquid absorbent and dehumidifies the air. The regeneration unit regenerates the liquid absorbent by passing the regeneration air through the liquid absorbent that has been used for dehumidification and then heated, thereby releasing the moisture of the liquid absorbent into the air.

  Furthermore, the dehumidification part of patent document 1 has a gas-liquid contact part (contactor) and a liquid tank. The cooled liquid absorbent comes into contact with the air to be treated in the gas-liquid contact portion, and is then stored in the liquid tank.

JP 2010-36093 A

  In the said patent document 1, a reproduction | regeneration part also has a gas-liquid contact part and a liquid tank. The heated liquid absorbent is regenerated in contact with the regenerating air at the gas-liquid contact portion of the regenerating portion, and then stored in the liquid tank of the regenerating portion.

  Thus, in the said patent document 1, the liquid tank is provided separately in the dehumidification part and the reproduction | regeneration part, and a humidity control apparatus will enlarge. Moreover, since there are two liquid tanks, the total amount of the liquid absorbent possessed by the humidity control device is relatively large, and the cost of the humidity control device is increased.

  This invention is made | formed in view of this point, The objective is to suppress the increase in the quantity of the liquid absorbent which a humidity control apparatus holds, and to suppress the enlargement of a humidity control apparatus.

The first invention is a liquid dehumidifying part (21) for dehumidifying the air to be treated by absorbing the water in the air to be treated by the liquid absorbent, and releasing the moisture of the liquid absorbent to the regeneration air. Regenerated by the regeneration unit (31) for regenerating the liquid absorbent, and the liquid absorbent and the regeneration unit (31) used for dehumidification of the air to be treated by the liquid dehumidification unit (21). one liquid tank for storing the said liquid absorbent (24), and sends the liquid absorbent agent stored in the liquid tank (24) the liquid dehumidification unit (21) and the reproducing section (31), respectively A pump ( 37 ), and the liquid dehumidification part (21) includes a dehumidification side gas-liquid contact part (23) for contacting the liquid absorbent and the air to be treated, and the dehumidification side gas-liquid contact. A dehumidifying-side liquid receiving part (26) for receiving the liquid absorbent in contact with the air to be treated below the part (23), The regeneration unit (31) includes a regeneration side gas-liquid contact unit (33) for bringing the liquid absorbent into contact with the regeneration air, and the regeneration air below the regeneration side gas-liquid contact unit (33). A second connection pipe for connecting the regeneration-side liquid receiving part (34) and the dehumidifying-side liquid receiving part (26) with the regeneration-side liquid receiving part (34) for receiving the liquid absorbent in contact with the liquid (17) and a liquid feeding part (18) for sending the liquid absorbent from the dehumidification side liquid receiving part (26) to the liquid tank (24), and are regenerated by the regenerating part (31). The liquid absorbent flows from the regeneration side liquid receiving part (34) into the dehumidified side liquid receiving part (26) through the second connection pipe (17) and is then used for dehumidification of the air to be treated. The liquid absorbent and the dehumidified liquid receiver (26) are mixed, and the liquid tank (24) is mixed with the liquid absorbent after being mixed via the liquid feeder (18). Is input, the liquid tank (24) is a humidity control apparatus characterized that you located below the dehumidifier side liquid receiving part (26).

Here, a liquid tank is not provided in each of the liquid dehumidifying part (21) and the regenerating part (31), but one liquid tank (common to the liquid dehumidifying part (21) and the regenerating part (31) ( 24 ) is provided. Thereby, the size of the humidity control apparatus (10) becomes smaller than the case where a liquid tank is provided in each of the liquid dehumidifying part (21) and the regenerating part (31). Therefore, the cost of the humidity control device (10) can be suppressed. Then, the liquid absorbent in the liquid tank (24) is positively sent to the liquid dehumidifying part (21) and the regenerating part (31) without any delay by the pump ( 37 ).

  Further, here, the liquid absorbent having a sufficiently mixed temperature and uniform temperature is stored in the liquid tank (24) as compared with the case where the liquid absorbent is mixed in the liquid tank (24). Therefore, temperature unevenness in the liquid tank (24) is less likely to occur.

  According to a second aspect of the present invention, a liquid dehumidifier (21) for dehumidifying the air to be treated by absorbing the water in the air to be treated by the liquid absorbent, and releasing the moisture of the liquid absorbent to the regeneration air. Regenerated by the regeneration unit (31) for regenerating the liquid absorbent, and the liquid absorbent and the regeneration unit (31) used for dehumidification of the air to be treated by the liquid dehumidification unit (21). One liquid tank (24) for storing the liquid absorbent and the liquid absorbent stored in the liquid tank (24) are sent to the liquid dehumidifying part (21) and the regenerating part (31), respectively. A liquid dehumidifying part (21), a dehumidifying side gas-liquid contact part (23) for contacting the liquid absorbent and the air to be treated, and the dehumidifying side gas-liquid contact. A dehumidifying-side liquid receiving part (26) for receiving the liquid absorbent in contact with the air to be treated under the part (23). The part (31) includes a regeneration side gas-liquid contact part (33) for contacting the liquid absorbent and the regeneration air, and the regeneration air below the regeneration side gas-liquid contact part (33). A second connection pipe (34) for connecting the regeneration-side liquid receiver (34) and the dehumidifying-side liquid receiver (26). 17) and a liquid feeding part (18) for sending the liquid absorbent from the regeneration side liquid receiving part (34) to the liquid tank (24), and the liquid dehumidifying part (21) The liquid absorbent used to dehumidify the air to be treated flows from the dehumidification side liquid receiver (26) into the regeneration side liquid receiver (34) via the second connection pipe (17), The regenerated liquid absorbent is mixed with the regenerated side liquid receiving part (34), and the mixed liquid absorbent is passed through the liquid feeding part (18) into the liquid tank (24). The Is input, the liquid tank (24) is a humidity control apparatus, characterized in that located below the playback side liquid receiving part (34).

  Here, a liquid tank is not provided in each of the liquid dehumidifying part (21) and the regenerating part (31), but one liquid tank (common to the liquid dehumidifying part (21) and the regenerating part (31) ( 24) is provided. Thereby, the size of the humidity control apparatus (10) becomes smaller than the case where a liquid tank is provided in each of the liquid dehumidifying part (21) and the regenerating part (31). Therefore, the cost of the humidity control device (10) can be suppressed. Then, the liquid absorbent in the liquid tank (24) is positively sent to the liquid dehumidifying part (21) and the regenerating part (31) without any delay by the pump (37).

  Further, here, the liquid absorbent having a sufficiently mixed temperature and uniform temperature is stored in the liquid tank (24) as compared with the case where the liquid absorbent is mixed in the liquid tank (24). Therefore, temperature unevenness in the liquid tank (24) is less likely to occur.

A third invention is characterized in that, in the first invention or the second invention , the liquid tank (24) is located closer to the liquid dehumidifying part (21) than the regenerating part (31). It is a humidity control device.

The circulation amount of the liquid absorbent is greater in the liquid dehumidifying part (21) than in the regenerating part (31). Here, since the liquid tank (24) is located closer to the liquid dehumidifying part (21), the length of the pipe for sending the liquid absorbent in the liquid tank (24) to the liquid dehumidifying part (21) The length can be made shorter than the pipe for sending to the regeneration unit (31). Therefore, the power of the pump ( 37 ) can be reduced .

According to a fourth invention, in any one of the first to third inventions, the liquid dehumidification unit is located upstream of the liquid dehumidification unit (21) in the flow direction of the air to be treated. A humidity control apparatus, further comprising a cooling / dehumidifying unit (48) for cooling and dehumidifying the air to be treated before being dehumidified in (21).

  Here, the air to be treated is cooled and dehumidified by the cooling and dehumidifying section (48), and then further dehumidified by the liquid dehumidifying section (21) using the liquid absorbent. Therefore, the amount of dehumidification in the liquid dehumidification part (21) is smaller than in the case where the air to be treated is dehumidified only by the liquid dehumidification part (21). Therefore, the amount of the liquid absorbent required for dehumidification in the liquid dehumidifying part (21) can be smaller than that in the case of dehumidifying only with the liquid dehumidifying part (21). In addition, the change in the concentration of the liquid absorbent in the liquid dehumidifying part (21) is smaller than that in the case of dehumidifying only with the liquid dehumidifying part (21). Even if stored in 24), the effect on the dehumidification performance by mixing liquid absorbents with different concentrations is small. That is, even if the liquid absorbent from each of the liquid dehumidifying part (21) and the regenerating part (31) is stored in one liquid tank (24), there is a problem in terms of performance of the humidity control apparatus (10). There is nothing.

  According to the present invention, the size of the humidity control device (10) is smaller than when a liquid tank is provided in each of the liquid dehumidification unit (21) and the regeneration unit (31). Therefore, the cost of the humidity control device (10) can be suppressed.

FIG. 1 is a diagram schematically illustrating the configuration of the humidity control apparatus according to the first embodiment. FIG. 2 is a diagram schematically illustrating the configuration of the humidity control apparatus according to the second embodiment. FIG. 3 is a diagram schematically illustrating the configuration of the humidity control apparatus according to the third embodiment. FIG. 4 is a diagram schematically illustrating the configuration of the humidity control apparatus of the fourth embodiment. FIG. 5 is a diagram schematically illustrating the configuration of the humidity control apparatus of the fifth embodiment. FIG. 6 is a diagram schematically illustrating a configuration of a humidity control apparatus according to the sixth embodiment. FIG. 7 is a diagram schematically illustrating the configuration of the humidity control apparatus of the seventh embodiment. FIG. 8 is a diagram schematically illustrating a configuration of a humidity control apparatus according to a modification of the seventh embodiment.

  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
<Overview>
The humidity control apparatus (10) according to the first embodiment is an apparatus that dehumidifies an internal space (hereinafter, indoors) such as an office building or a house mainly using a liquid absorbent.

  As shown in FIG. 1, the humidity control apparatus (10) according to the first embodiment includes a dehumidification module (20) that dehumidifies air. The dehumidifying module (20) includes a liquid dehumidifying module (21) (corresponding to a liquid dehumidifying part) that dehumidifies using a liquid absorbent, and a refrigerant-cooled dehumidifying module (48) (cooling dehumidifying part) that dehumidifies using a refrigerant. Equivalent).

  Such a humidity control device (10) includes an absorbent circuit (15) through which a liquid absorbent circulates and a refrigerant circuit (40) through which a refrigerant circulates. The liquid dehumidifying module (21) is included in the equipment constituting the absorbent circuit (15). All the devices constituting the absorbent circuit (15) are installed in a space (for example, a machine room) different from the room. The equipment constituting the refrigerant circuit (40) includes a compressor (42) and a heat radiation condenser (43) (corresponding to a heat radiation heat exchanger) in addition to the refrigerant cooling dehumidification module (48). The compressor (42) and the heat radiation condenser (43) are included in the outdoor unit (41) and are installed outdoors. Among the devices constituting the refrigerant circuit (40), the devices other than the compressor (42) and the heat dissipation condenser (43) are separate from the room, as are the devices constituting the absorbent circuit (15). (For example, in a machine room).

-Liquid absorbent-
The liquid absorbent is a liquid that can absorb moisture (water vapor) in the air. In general, examples of the liquid absorbent used in the humidity control apparatus (10) include an aqueous lithium chloride solution and an aqueous lithium bromide solution. These are aqueous solutions having excellent moisture absorption performance but relatively high corrosivity. When these aqueous solutions are used, it is necessary to take separate measures for preventing corrosion in the humidity control device (10), and it is difficult to use these aqueous solutions safely.

  On the other hand, in this Embodiment 1, although the moisture absorption performance is inferior to the said aqueous solution, the liquid of a property with low corrosivity can be used as a liquid absorbent. The liquid can be used safely because it is less corrosive. An example of such a liquid is an ionic liquid. An ionic liquid is a salt composed of ions and has a property of being in a liquid state at 100 degrees Celsius or less.

<Configuration of humidity control device>
The humidity controller (10) includes the absorbent circuit (15), the refrigerant circuit (40), and a controller (50) for performing various controls in the circuits (15, 40).

-Absorbent circuit-
The absorbent circuit (15) includes the liquid dehumidifying module (21) and the regeneration module (31) (corresponding to the regeneration unit) as modules for transferring moisture between the liquid absorbent and the air. The absorbent circuit (15) further includes a pump (37), a flow rate adjustment valve (39), a liquid heating heat exchanger (44), and a liquid cooling heat exchanger (46). The absorbent circuit (15) is configured by connecting the modules (21, 31), the pump (37), and the like through connection pipes (15a to 15e).

-Liquid dehumidification module-
The liquid dehumidifying module (21) causes the liquid absorbent to absorb moisture in the air to be treated and dehumidifies the air to be treated. Specifically, the liquid dehumidification module (21) includes a dehumidification side liquid supply unit (22), a dehumidification side gas-liquid contact unit (23), and a liquid tank (24).

  The dehumidification side liquid supply part (22) is formed with, for example, a plurality of dripping ports arranged in the extending direction of the pipe part in the pipe part connected to one end of the connection pipe (15a). It has the structure made.

  The dehumidification side gas-liquid contact part (23) is comprised with the hydrophilic filler, and is located under the dehumidification side liquid supply part (22). When the outside air (OA) that is the air to be treated is supplied to the dehumidifying side gas-liquid contact part (23), the outside air (OA) comes into contact with the liquid absorbent dripped from the dehumidifying side liquid supply part (22). Let As a result, the amount of water contained in the outside air (OA) that has passed through the dehumidification-side gas-liquid contact portion (23) is less than that before passing, and is in a dehumidified state. That is, the concentration of the liquid absorbent after being dropped on the dehumidifying side gas-liquid contact part (23) and contacting the outside air (OA) is thinner than before being dropped on the dehumidifying side gas-liquid contact part (23). .

  The liquid tank (24) is closer to the liquid dehumidification module (21) than the regeneration module (31), and is specifically located below the dehumidification side gas-liquid contact portion (23). The liquid tank (24) also functions as a dehumidifying side liquid receiving part for receiving the liquid absorbent after contacting the outside air (OA) in the dehumidifying side gas-liquid contact part (23). Store liquid absorbent. That is, in the liquid type dehumidifying module (21) according to the first embodiment, the dehumidifying side liquid receiving portion and the liquid tank are not provided side by side. Thereby, compared with the case where a dehumidification side liquid receiving part and a liquid tank are provided, the cost increase of a humidity control apparatus (10) is suppressed.

-Playback module-
The regeneration module (31) regenerates the liquid absorbent by releasing the moisture of the liquid absorbent into the regeneration air. Specifically, the regeneration module (31) includes a regeneration-side liquid supply part (32), a regeneration-side gas-liquid contact part (33), and a regeneration-side liquid receiver (34).

  For example, the regeneration-side liquid supply unit (32) has a plurality of dripping ports for dripping the liquid absorbent in the pipe portion connected to one end of the connection pipe (15b) in the extending direction of the pipe portion. It has the structure made.

  The regeneration-side gas-liquid contact part (33) is made of a hydrophilic filler and is located below the regeneration-side liquid supply part (32). When the indoor air (RA) that is the regeneration air is supplied to the regeneration side gas-liquid contact part (33), the liquid absorbent that has been dropped from the regeneration side liquid supply part (32) Contact with. As a result, the amount of water contained in the dropped liquid absorbent is released into the regeneration air, and the concentration of the liquid absorbent that has passed through the regeneration-side gas-liquid contact portion (33) is determined by the regeneration-side gas-liquid contact portion (33 ) Is darker than before dripping.

  The regeneration side liquid receiver (34) is closer to the regeneration module (31) than the liquid dehumidification module (21), and is specifically located below the regeneration side gas-liquid contact part (33). The regeneration-side liquid receiver (34) receives the liquid absorbent regenerated in contact with the room air (RA) in the regeneration-side gas-liquid contact section (33). The regeneration side liquid receiving part (34) and the liquid tank (24) are connected by a connection pipe (15c), and the liquid absorbent received by the regeneration side liquid receiving part (34) (ie, the regenerated liquid absorption) The agent is sent to one liquid tank (24) through the connection pipe (15c).

  That is, the liquid tank (24) according to Embodiment 1 was used for dehumidification of the air to be treated (outside air (OA)) at the dehumidification side gas-liquid contact portion (23) of the liquid dehumidification module (21). The liquid absorbent and the liquid absorbent regenerated at the regeneration side gas-liquid contact portion (33) of the regeneration module (31) are mixed and stored. The concentration of the liquid absorbent used for dehumidification is lower than the concentration of the regenerated liquid absorbent. Therefore, the low concentration liquid absorbent used for dehumidification and the regenerated low concentration liquid absorbent are stored using one liquid tank (24) as a common tank.

  In particular, the connection pipe (15c) has a regeneration side liquid receiving part (34) and a liquid tank (24) with the bottom part of the regeneration side liquid receiving part (34) as a liquid inlet and the side part of the liquid tank (24) as a liquid outlet. ). The liquid outlet is below the liquid inlet. Therefore, it flows into the liquid tank (24) from the regeneration side liquid receiving part (34) using gravity (the weight of the liquid absorbent). Therefore, the regenerated liquid absorbent is not provided between the connecting pipe (15c) without the power of a pump or the like that actively sends the liquid absorbent from the regeneration side liquid receiver (34) to the liquid tank (24). And the liquid absorbent used for dehumidification can be collected in one liquid tank (24).

  In addition, it is more preferable that the liquid tank (24) itself is installed at a position lower than the regeneration side liquid receiving part (34). This is because the liquid absorbent is more easily moved by gravity from the regeneration-side liquid receiver (34) to the liquid tank (24).

-Pump-
The pump (37) is connected to the connection pipe (15d) and the connection pipe (15e). The pump (37) sends the liquid absorbent stored in the liquid tank (24) to the liquid dehumidification module (21) and the regeneration module (31) again. That is, it can be said that the pump (37) is for circulating the liquid absorbent between the liquid dehumidification module (21) and the regeneration module (31).

  Here, the connection pipe (15d) has one end connected to the liquid tank (24) and the other end connected to the input side of the pump (37). One end of the connection pipe (15e) is connected to the output side of the pump (37). The other end of the connecting pipe (15e) branches into two paths, one path is connected to the liquid cooling heat exchanger (46), and the other path is the liquid heating heat exchanger via the flow rate adjustment valve (39). Connected to (44).

−Flow adjustment valve−
The flow rate adjusting valve (39) is composed of an electromagnetic proportional valve, and adjusts the flow rate of the liquid absorbent by adjusting the opening degree. The liquid absorbent stored in the liquid tank (24) flows from the pump (37) and then branches to the liquid heating heat exchanger (44) as well as the liquid cooling heat exchanger (46). be able to. By adjusting the opening of the flow control valve (39), the amount of liquid absorbent supplied to the liquid cooling heat exchanger (46) and the amount of liquid absorbent supplied to the liquid heating heat exchanger (44) can be reduced. It is adjusted to a predetermined ratio.

-Liquid heating heat exchanger-
The liquid heating heat exchanger (44) is, for example, a plate type, and has an absorbent passage through which the liquid absorbent passes and a refrigerant passage through which the refrigerant passes, although not shown. The inlet side of the absorbent passage is connected to the connection pipe (15e), and the outlet side of the absorbent passage is connected to the regeneration-side liquid supply section (32) of the regeneration module (31) via the connection pipe (15b). The inlet side of the refrigerant passage is connected to the heat dissipation condenser (43) via the connection pipe (40c), and the outlet side of the refrigerant passage is connected to the expansion valve (45) via the connection pipe (40d). . The liquid heating heat exchanger (44) functions as a refrigerant condenser and regenerates in the regeneration module (31) by exchanging heat between the liquid absorbent passing through the absorbent passage and the refrigerant passing through the refrigerant passage. The liquid absorbent before being heated is heated by the refrigerant. The liquid absorbent after passing through the liquid heating heat exchanger (44) is sent to the regeneration module (31) and regenerated.

-Liquid cooling heat exchanger-
The liquid cooling heat exchanger (46) is, for example, a plate type and is not shown in the figure, but, like the liquid heating heat exchanger (44), the absorbent passage through which the liquid absorbent passes and the refrigerant pass through. And a refrigerant passage. The inlet side of the absorbent passage is connected to the connection pipe (15e), and the outlet side of the absorbent passage is connected to the dehumidification side liquid supply part (22) of the liquid dehumidification module (21) via the connection pipe (15a). The The inlet side of the refrigerant passage is connected to the expansion valve (45) via the connection pipe (40e), and the outlet side of the refrigerant passage is connected to the refrigerant cooling dehumidification module (48) via the connection pipe (40f). The The liquid cooling heat exchanger (46) functions as a refrigerant evaporator, and exchanges heat between the liquid absorbent passing through the absorbent passage and the refrigerant passing through the refrigerant passage. Specifically, in the liquid cooling heat exchanger (46), the liquid absorbent before being used for dehumidification in the liquid dehumidification module (21) is cooled by the refrigerant. The liquid absorbent after passing through the liquid cooling heat exchanger (46) is sent to the liquid dehumidification module (21) and used for dehumidification.

-Refrigerant circuit-
The refrigerant circuit (40) includes a compressor (42), a heat dissipation condenser (43), a liquid heating heat exchanger (44), an expansion valve (45), a liquid cooling heat exchanger (46), and a refrigerant cooling dehumidification module. (48) is configured by being connected in series in this order by connection pipes (40a to 40f). Below, the component apparatus of refrigerant circuit (40) other than the liquid heating heat exchanger (44) and liquid cooling heat exchanger (46) mentioned above is demonstrated.

-Compressor-
The compressor (42) is located downstream of the refrigerant cooling dehumidification module (48) in the refrigerant flow direction via the connection pipe (40a), and compresses and discharges the refrigerant. The compressor (42) is a variable capacity type, and the rotation speed (operation frequency) is changed by an inverter circuit (not shown).

−Heat dissipation condenser−
The heat radiation condenser (43) is, for example, a fin-and-tube type, and the refrigerant inlet is connected to the discharge side of the compressor (42) via the connection pipe (40b), and the refrigerant outlet is connected to the connection pipe (40c). ) Is connected to the inlet of the refrigerant passage in the liquid heating heat exchanger (44). That is, the heat radiation condenser (43) is located downstream of the refrigerant cooling dehumidification module (48) in the refrigerant flow direction. The heat dissipation condenser (43) condenses the refrigerant by releasing the heat of the refrigerant discharged from the compressor (42) through the refrigerant cooling dehumidification module (48) to the heat dissipation fluid. The refrigerant after heat dissipation further dissipates heat to the liquid absorbent and condenses in the liquid heating heat exchanger (44).

  Here, the radiating fluid is other than indoor air (RA), and examples thereof include outside air (OA) and water. In the first embodiment, the heat dissipation fluid is outside air (OA), and the heat dissipation condenser (43) is an air-refrigerant heat exchanger that exchanges heat between the outside air (OA) and the refrigerant. .

  In addition, a fan (43a) for supplying outside air (OA), which is a heat-dissipating fluid, is installed in the vicinity of the heat dissipation condenser (43). The fan (43a) is operated when the heat radiation of the refrigerant is required by the heat radiation condenser (43), which will be described in “-Supply Control Unit”.

-Expansion valve-
The expansion valve (45) is an electronic expansion valve. The expansion valve (45) is connected to the outlet side of the refrigerant passage in the liquid heating heat exchanger (44) through the connection pipe (40d), and in the liquid cooling heat exchanger (46) through the connection pipe (40e). It is connected to the inlet side of the refrigerant passage. The expansion valve (45) depressurizes the refrigerant circulating in the refrigerant circuit (40) by changing the opening degree.

-Refrigerant-cooled dehumidification module-
The refrigerant cooling dehumidification module (48) is, for example, a fin-and-tube type, and dehumidifies by cooling the air to be treated (outside air (OA)) with a refrigerant. In particular, the refrigerant-cooled dehumidifying module (48) is located upstream of the liquid dehumidifying module (21) in the flow direction of outside air (OA). The refrigerant-cooled dehumidifying module (48) cools and dehumidifies the air to be treated (outside air (OA)) before being dehumidified by the liquid dehumidifying module (21). That is, in the first embodiment, the air to be treated (outside air (OA)) is dehumidified by both the liquid dehumidification module (21) and the refrigerant cooling dehumidification module (48), and then is supplied indoors as supply air (SA). To be supplied.

  A drain pan (48a) is installed below the refrigerant-cooled dehumidifying module (48). In the refrigerant-cooled dehumidification module (48), when the air to be treated (outside air (OA)) is cooled and dehumidified, moisture absorbed from the air is condensed on the surface of the refrigerant-cooled dehumidification module (48) and falls downward. To do. The drain pan (48a) is a tray for collecting the condensed water. The drain pan (48a) is connected to the drain discharge pipe (48b), and discharges condensed water to the outside of the humidity control apparatus (10) through the drain discharge pipe (48b).

  Thus, the drain pan (48a) is provided separately from the liquid tank (24) in the liquid dehumidifying module (21). If condensed water is mixed into the liquid tank (24), the concentration of the liquid absorbent in the liquid tank (24) will be lower than when it is not mixed, and the liquid absorbent will be regenerated by the regeneration module (31). Necessary energy increases. However, since the drain pan (48a) and the liquid tank (24) are separately provided here, the possibility that the above-described problem occurs is reduced.

  Furthermore, a filter (49) is located between the refrigerant-cooled dehumidifying module (48) and the liquid dehumidifying module (21). The filter (49) prevents the liquid absorbent from splashing from the liquid dehumidifying module (21) side to the refrigerant-cooled dehumidifying module (48) side, and condensed water from the refrigerant-cooled dehumidifying module (48) side. Prevents splashing to the liquid dehumidification module (21) side. By this filter (49), the possibility that the liquid absorbent and the condensed water are mixed is reliably reduced.

  By the way, the dew condensation water is discharged to the outside through the drain pan (48a) and the drain discharge pipe (48b). Therefore, a separate means for releasing the condensation heat when the refrigerant-cooled dehumidifying module (48) cools and dehumidifies the outside air (OA) is required. In the first embodiment, the heat radiation condenser (43) described above exists as the means for releasing the condensation heat. In particular, the heat-dissipating condenser (43) radiates heat to a heat-dissipating fluid other than the room air (RA) as described above in order to recover the heat of vaporization corresponding to the dew condensation water discharged outdoors. Accordingly, an excessive increase in the refrigerant condensing temperature (condensation pressure) can be suppressed, and an excessive increase in the condensing temperature (condensing pressure) can be judged as abnormal, and the situation where the humidity controller (10) stops operating can be avoided.

  Thus, the liquid cooling heat exchanger (46) and the refrigerant cooling type dehumidifying module (48) are connected to one refrigerant circuit (40) together with the liquid heating heat exchanger (44). In the first embodiment, the refrigerant circuit (40) that can be said to be a heat pump heat source is not complicatedly provided by a combination of a plurality of circuits, and the configuration of the refrigerant circuit (40) is simplified.

  And the dehumidification module (20) of the humidity control apparatus (10) which concerns on this Embodiment 1 has a refrigerant | coolant cooling dehumidification module (48) and a liquid dehumidification module (21) as above-mentioned. Therefore, even if a liquid with a relatively low hygroscopic performance such as an ionic liquid is used as the liquid absorbent, and even if the air conditioning load is relatively high, the air to be treated is more fully accommodated by the two modules (48, 21). Supplied indoors in a dehumidified state. Since there are two modules (48, 21) that dehumidify the air to be treated, the ratio of the dehumidification amount in the refrigerant-cooled dehumidification module (48) to the dehumidification amount in the liquid dehumidification module (21) It can be adjusted at the control stage, and it can be said that the degree of freedom in design is great.

  On the other hand, the regeneration side of the humidity control apparatus (10) is only the liquid absorbent regeneration module (31), and there is no module using other than the liquid absorbent, such as the refrigerant-cooled dehumidification module. That is, it can be said that the configuration on the regeneration side is simplified compared to the dehumidification side.

-Controller-
The controller (50) is a microcomputer composed of a memory, a CPU, and the like, and includes various devices (compressor (42), pump (37), flow rate adjustment valve (39), humidity control device (10), The fan (43a) and the expansion valve (45)) are electrically connected. When the CPU reads and executes the program stored in the memory, the controller (50) controls the operation of various connected devices.

  Specifically, the controller (50) according to the first embodiment controls the operation of the fan (43a) based on the refrigerant condensing temperature, the opening control of each valve (39, 45) based on the air conditioning load, and the pump (37). The operation control is performed. Below, the supply control part (51) which is a functional part which performs operation control of a fan (43a) among the functional parts which a controller (50) has is demonstrated.

−Supply control section−
When the refrigerant condensing temperature in the refrigerant circuit (40) exceeds a predetermined value, the supply control unit (51) operates the fan (43a) to turn the outside air (OA), which is a radiating fluid, into the radiating condenser (43). Supply. In this case, the heat dissipation condenser (43) releases the heat of the refrigerant to the supplied outside air (OA).

  On the other hand, when the refrigerant condensing temperature in the refrigerant circuit (40) is equal to or lower than a predetermined value, the supply control unit (51) stops the operation of the fan (43a) and external air (OA) to the heat radiation condenser (43) Stop supplying. In this case, in the heat dissipation condenser (43), the heat of the refrigerant is not released to the outside air (OA).

  If the fan (43a) is operated when the condensation temperature of the refrigerant is equal to or lower than the predetermined value, the refrigerant is discharged from the outside air (43) even though the refrigerant condensation temperature is relatively low. OA) will dissipate heat. Then, the degree of heating of the liquid absorbent in the liquid heating heat exchanger (44) becomes small, and the liquid absorbent cannot be sufficiently regenerated. Therefore, the supply control unit (51) performs control so that the outside air (OA) is not supplied to the heat dissipation condenser (43) when the condensation temperature of the refrigerant is equal to or lower than a predetermined value. By this control, it is possible to avoid insufficient regeneration of the liquid absorbent, and thus it is possible to suppress a decrease in the dehumidifying capacity of the humidity control apparatus (10).

  Also, if the air conditioning load is relatively small and the amount of heat (condensation heat) generated by the refrigerant-cooled dehumidification module (48) is not significant, the heat generated on the dehumidification module (20) side is converted to regeneration air in the regeneration module (31). The heat dissipation can be sufficiently processed, and the condensation temperature of the refrigerant becomes relatively low. Therefore, when the condensation temperature of the refrigerant is equal to or lower than the predetermined value, in the humidity control apparatus (10), the fan (43a) is stopped and the power consumption in the fan (43a) is reduced.

<Operation of humidity control device>
Here, the dehumidifying operation of the humidity control apparatus (10) according to the first embodiment will be described.

  In the refrigerant circuit (40), the compressor (42) operates, the heat dissipation condenser (43) and the liquid heating heat exchanger (44) function as a refrigerant condenser, the liquid cooling heat exchanger (46) and The refrigerant-cooled dehumidifying module (48) functions as a refrigerant evaporator.

  The refrigerant compressed by the compressor (42) is condensed by releasing heat to the heat dissipation fluid (outside air (OA)) in the heat dissipation condenser (43), and then absorbed in the liquid heating heat exchanger (44). Dissipates heat to the agent and further condenses. The refrigerant that has flowed out of the liquid heating heat exchanger (44) is decompressed by the expansion valve (45) and flows into the liquid cooling heat exchanger (46).

  In the liquid cooling heat exchanger (46), the refrigerant absorbs heat from the liquid absorbent and cools the liquid absorbent. Thereafter, the refrigerant flows into the refrigerant-cooled dehumidifying module (48), absorbs moisture from the air to be treated (outside air (OA)) passing through the module (48), evaporates, and cools and dehumidifies the air. The refrigerant that has passed through the refrigerant-cooled dehumidifying module (48) is sucked into the compressor (42).

  In the absorbent circuit (15), the pump (37) operates and the flow rate adjustment valve (39) is adjusted to a predetermined opening. In the liquid dehumidification module (21), the liquid absorbent is dropped from the dehumidification side liquid supply unit (22) to the dehumidification side gas-liquid contact unit (23). The dehumidified side gas-liquid contact section (23) is supplied with air to be treated (outside air (OA)) that has been cooled and dehumidified by the refrigerant-cooled dehumidifying module (48), and the dropped liquid absorbent is taken from the air. Absorbs moisture and dehumidifies the air. The air after being dehumidified by both the refrigerant-cooled dehumidifying module (48) and the liquid dehumidifying module (21) is supplied indoors as supply air (SA).

  The liquid absorbent that has absorbed moisture from the air to be treated (outside air (OA)) has a reduced concentration and is stored in the liquid tank (24) below the dehumidifying side gas-liquid contact part (23). The After passing through the connection pipe (15d), the liquid absorbent in the liquid tank (24) branches to the liquid heating heat exchanger (44) side and the liquid cooling heat exchanger (46) side in the connection pipe (15e). Flowing.

  The liquid absorbent that has flowed to the liquid heating heat exchanger (44) side is heated by the refrigerant in the heat exchanger (44), and then flows into the regeneration module (31). The liquid absorbent that has flowed into the regeneration module (31) is dropped from the regeneration side liquid supply part (32) to the regeneration side gas-liquid contact part (33). Regeneration air (room air (RA)) is supplied to the regeneration-side gas-liquid contact portion (33), and the dropped liquid absorbent releases moisture to the air. As a result, the liquid absorbent is in a high concentration state and is regenerated. The regenerated liquid absorbent is once received by the regenerating side liquid receiving part (34) below the regenerating side gas-liquid contact part (33), and then the liquid tank (24) through the connection pipe (15c). It is stored in. That is, in the liquid tank (24), the liquid absorbent having a high concentration in the regeneration module (31) and the liquid absorbent having a low concentration in the liquid dehumidifying module (21) are put and mixed. .

  Note that the air used for regenerating the liquid absorbent is discharged outdoors as exhaust air (EA).

  The liquid absorbent that has flowed to the liquid cooling heat exchanger (46) side is cooled by the refrigerant in the heat exchanger (46) and then flows into the liquid dehumidification module (21). The liquid absorbent that has flowed into the liquid dehumidification module (21) is dropped again from the dehumidification side liquid supply unit (22) to the dehumidification side gas-liquid contact unit (23).

<About the liquid absorbent in the liquid tank>
As described above, in the liquid tank (24), the liquid absorbent that has been regenerated and has a high concentration and the liquid absorbent that has been reduced in concentration by being used for dehumidification are placed and mixed. As described above, the mixed liquid absorbent circulates in the absorbent circuit (15). However, in the first embodiment, there is a low possibility that the dehumidifying ability is lowered due to the mixing. This is due to the following reason.

  In the dehumidifying module (20), as described above, the air to be treated (outside air (OA)) is dehumidified in two stages by the two modules, the liquid dehumidifying module (21) and the refrigerant cooling dehumidifying module (48). It is the composition to do. In particular, since the liquid dehumidifying module (21) is located downstream in the flow direction of the air to be treated, the outside air (OA) that has been previously cooled and dehumidified by the refrigerant cooling dehumidifying module (48) is further dehumidified. . Therefore, the dehumidifying amount of the liquid dehumidifying module (21) is lower than that in the case where the refrigerant cooling dehumidifying module (48) is not provided, and the concentration of the liquid absorbent in the liquid dehumidifying module (21) is Only about 1% or less changes before and after the dropping.

  In addition, since the air to be treated (outside air (OA)) is dehumidified over two stages, the amount of liquid absorbent used by the liquid dehumidifying module (21) in the dehumidifying operation is determined by the refrigerant-cooled dehumidifying module ( 48) is not provided, and it is less than when dehumidifying only with a liquid dehumidifying module. Therefore, the amount of the liquid absorbent whose concentration is changed in the above-described degree in the liquid dehumidification module (21) naturally enters the liquid tank (24).

  In view of the above, even if a liquid absorbent that has been reconstituted in a liquid tank (24) and a liquid absorbent that has been thinned by dehumidification are mixed in the liquid tank (24), the concentration change caused by the mixing is mixed. It can be said that the degree is very small. The dehumidifying capability in the present embodiment 1 in which the mixed liquid absorbent is used for dehumidification of the liquid dehumidifying module (21) is that the liquid absorbent immediately after being regenerated by the regenerating module (31) is replaced with the liquid dehumidifying module ( Compared with the dehumidification capacity when used directly for dehumidification in 21), it is similar.

  Therefore, instead of providing a dedicated liquid tank on each of the liquid dehumidification module (21) side and the regeneration module (31) side, as in the first embodiment, the liquid dehumidification module (21) and the regeneration module (31) The common liquid tank (24) can be provided without increasing the size. Since one liquid tank (24) whose size is not increased is provided, the size of the humidity control apparatus (10) can be reduced, and the manufacturing cost of the humidity control apparatus (10) is also one for the liquid tank (24). It can be reduced because it only takes one.

<Effect>
In the first embodiment, the liquid absorbent used for dehumidification in the liquid dehumidification module (21) and the liquid absorbent regenerated in the regeneration module (31) are mixed in one liquid tank (24). Stored. That is, the liquid dehumidification module (21) and the regeneration module (31) are not provided with a liquid tank, but one liquid tank (24 common to the liquid dehumidification module (21) and the regeneration module (31). ) Is provided. Thereby, the size of the humidity control apparatus (10) becomes smaller than the case where a liquid tank is provided in each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, the cost of the humidity control device (10) can be suppressed. Then, the liquid absorbent in the liquid tank (24) is positively sent to the liquid dehumidification module (21) and the regeneration module (31) without any delay by the pump (37).

  By the way, in this Embodiment 1, it is possible to improve dehumidification efficiency by increasing the circulation amount of a liquid absorbent in the liquid dehumidification module (21) rather than the regeneration module (31). In this Embodiment 1, since the liquid tank (24) is located near the liquid dehumidification module (21), the liquid absorbent in the liquid tank (24) is sent to the liquid dehumidification module (21). The length of the connecting pipe (15d, 15e, 15a) can be made shorter than the connecting pipe (15d, 15e, 15b) for sending the liquid absorbent to the regeneration module (31). Therefore, the power of the pump (37) can be reduced.

  Moreover, in this Embodiment 1, the liquid tank (24) serves as the function as a dehumidification side liquid receiving part of a liquid type dehumidification module (21). Thereby, since it is not necessary to provide a dehumidification side liquid receiving part separately from the liquid tank (24), the structure of the humidity control apparatus (10) can be simplified accordingly.

  In Embodiment 1, the air to be treated (outside air (OA)) is further dehumidified by the liquid dehumidification module (21) using the liquid absorbent after being cooled and dehumidified by the refrigerant cooling dehumidification module (48). Is done. Therefore, the amount of dehumidification in the liquid dehumidification module (21) is smaller than in the case where the air to be treated (outside air (OA)) is dehumidified only by the liquid dehumidification module (21). Therefore, the amount of liquid absorbent required for dehumidification in the liquid dehumidification module (21) can be smaller than that in the case of dehumidification only with the liquid dehumidification module (21). In addition, the change in the concentration of the liquid absorbent in the liquid dehumidification module (21) is smaller than that in the case of dehumidification only with the liquid dehumidification module (21). Even if it is mixed and stored in 24), the influence on the dehumidification performance by the mixing is small. That is, even if the liquid dehumidifying module (21) and the regenerating module (31) are mixed and stored in one liquid tank (24), the performance of the humidity control device (10) There is no problem.

  In the first embodiment, one pump (37) is connected to the liquid outlet of the liquid tank (24), and the liquid dehumidification module (21) is connected from the pump (37) via the connection pipe (15e). In addition, the liquid absorbent is branched and flowed to each of the regeneration modules (31). As described above, the liquid absorbent can be sent to the liquid dehumidification module (21) and the regeneration module (31) without using a plurality of pumps, and the humidity control apparatus (10 ) Manufacturing cost and power consumption can be reduced. Moreover, since the number of pumps (37) is small, the time required for maintenance of the humidity control apparatus (10) can be reduced accordingly.

<< Embodiment 2 >>
The structure of the humidity control apparatus (10) of this Embodiment 2 is shown in FIG. In FIG. 2, the configuration of the refrigerant circuit (40) is the same as that of FIG. 1, but the configuration of the absorbent circuit (15) is slightly different. In FIG. 2, the same reference numerals as those in FIG. 1 are given to the components corresponding to those in FIG. Below, only the part from which a structure differs is demonstrated.

  The liquid absorbent is the same as in the first embodiment.

  The absorbent circuit (15) consists of a liquid dehumidification module (21), a regeneration module (31), a pump (37), a flow rate adjustment valve (39), a liquid heating heat exchanger (44) and a liquid cooling heat exchanger (46 ) Are connected by connecting pipes (15a, 15b, 15d, 15e). Among these, the pump (37), the flow rate adjusting valve (39), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46) are the pump (37), the flow rate adjusting valve (39) according to the first embodiment. ), Liquid heating heat exchanger (44) and liquid cooling heat exchanger (46).

  The liquid dehumidification module (21) has the same dehumidification side liquid supply part (22) and dehumidification side gas-liquid contact part (23) as in the first embodiment, and the regeneration module (31) is the same as in the first embodiment. It has the same reproduction | regeneration side liquid supply part (32) and the reproduction | regeneration side gas-liquid contact part (33).

  Neither the liquid dehumidification module (21) nor the regeneration module (31) has a liquid receiver dedicated to each module (21, 31). Instead, one liquid tank (24) is installed below the liquid dehumidification module (21) and the regeneration module (31).

  The liquid tank (24) contains both the liquid absorbent after being used for dehumidification at the dehumidification side gas-liquid contact section (23) and the liquid absorbent regenerated at the regeneration side gas-liquid contact section (33). It is located below both gas-liquid contact parts (23, 33) so that it can be received. And a liquid tank (24) mixes and stores the liquid absorbent after being utilized for dehumidification, and the regenerated liquid absorbent. That is, the liquid tank (24) serves as a liquid receiving part on the dehumidifying side and a liquid receiving part on the regeneration side. Therefore, in the second embodiment, the regeneration side liquid receiving part (34) of FIG. 1 and the connection pipe (15c) connecting the regeneration side liquid receiving part (34) and the liquid tank (24) are not provided.

  The operation of the humidity control apparatus (10) according to the second embodiment is the same as that of the first embodiment.

  The humidity control apparatus (10) according to the second embodiment has the following effects in addition to the effects of the first embodiment.

  In the second embodiment, the liquid tank (24) is positioned below the liquid dehumidification module (21) and the regeneration module (31). Thereby, the force flowing into the liquid tank (24) by gravity acts on the liquid absorbent from each of the liquid dehumidifying module (21) and the regeneration module (31). Therefore, it is not necessary to provide a pump for allowing the liquid absorbent to flow from the liquid dehumidifying module (21) and the regeneration module (31) into the liquid tank (24) as shown in FIG.

<< Embodiment 3 >>
The structure of the humidity control apparatus (10) of this Embodiment 3 is shown in FIG. In FIG. 3, the configuration of the refrigerant circuit (40) is the same as that of FIG. 1, but the configuration of the absorbent circuit (15) is slightly different. In FIG. 3, the same reference numerals as those in FIG. 1 are given to the components corresponding to those in FIG. Below, only the part from which a structure differs is demonstrated.

  The liquid absorbent is the same as in the first embodiment.

  The absorbent circuit (15) connects the liquid dehumidification module (21), the regeneration module (31), the two pumps (37a, 37b), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46). It is comprised by connecting by piping (15a-15c, 15f-15i). Among these, the liquid dehumidification module (21), the regeneration module (31), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46) are the liquid dehumidification module (21) according to the first embodiment, This is the same as the regeneration module (31), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46).

  Also in the third embodiment, as in the first embodiment, a pump (37a, 37b) is provided from one liquid tank (24) located below the dehumidification-side gas-liquid contact portion (23) of the liquid dehumidification module (21). ), The liquid absorbent in the liquid tank (24) is sent to the liquid heating heat exchanger (44) and the liquid cooling heat exchanger (46), respectively. However, in the third embodiment, unlike the first embodiment, two pumps (37a, 37b) are provided in one liquid tank (24) instead of providing the flow rate adjusting valve (39) of FIG. It is connected.

  That is, in the third embodiment, a pump (37a) is provided corresponding to the regeneration module (31), and a pump (37b) is provided corresponding to the liquid dehumidification module (21). The input side of the pump (37a) is connected to the liquid tank (24) via the connection pipe (15f), and the output side of the pump (37a) is connected to the liquid heating heat exchanger (44) via the connection pipe (15g). ) Is connected to the inlet of the absorbent passage. The input side of the pump (37b) is connected to the liquid tank (24) via the connection pipe (15h), and the output side of the pump (37b) is connected to the liquid cooling heat exchanger (46 ) Is connected to the inlet of the absorbent passage.

  Thereby, the liquid absorbent in the liquid tank (24) is sent to the regeneration module (31) through the liquid heating heat exchanger (44) by the pump (37a), and the liquid cooling heat exchanger by the pump (37b). It is sent to the liquid dehumidification module (21) via (46).

  The humidity control apparatus (10) according to the third embodiment having the above-described configuration has the same effects as those of the first embodiment except for the effect when the number of pumps (37) is one.

<< Embodiment 4 >>
<Configuration>
The structure of the humidity control apparatus (10) of this Embodiment 4 is shown in FIG. The humidity control apparatus (10) according to Embodiment 4 includes an absorbent circuit (15) and a refrigerant circuit (40). Since the humidity control apparatus (10) of the fourth embodiment is significantly different in configuration from the first to third embodiments, the configuration and operation will be described below.

  The liquid absorbent is the same as in the first embodiment.

-Absorbent circuit-
The absorbent circuit (15) consists of two liquid dehumidification modules (21a, 21b), one regeneration module (31), one pump (37), three flow control valves (39a-39c), liquid heating heat The exchanger (44) and the liquid cooling heat exchanger (46) are configured by being connected by connection pipes (15a to 15g).

  The liquid dehumidification module (21a, 21b) includes a dehumidification side liquid supply part (22a, 22b), a dehumidification side gas-liquid contact part (23a, 23b), and a dehumidification side liquid receiver (25a, 25b), respectively. Have.

  The dehumidification side liquid supply unit (22a, 22b) is connected to the liquid cooling heat exchanger (46) via the connection pipes (15a, 15f) and the flow rate adjusting valves (39b, 39c). The dehumidification side liquid supply part (22a, 22b) supplies the liquid absorbent cooled by the liquid cooling heat exchanger (46) to the corresponding dehumidification side gas-liquid contact part (23a, 23b).

  Each dehumidification side gas-liquid contact part (23a, 23b) makes external air (OA) as to-be-processed air contact a liquid absorbent, and dehumidifies this air. The dehumidified air is supplied indoors as supply air (SA).

  Each dehumidification side liquid receiving part (25a, 25b) is located under each dehumidification side gas-liquid contact part (23a, 23b). Each dehumidification side liquid receiving part (25a, 25b) contacts the to-be-processed air (outside air (OA)) in each dehumidification side gas-liquid contact part (23a, 23b), and receives the liquid absorbent used for dehumidification. Each dehumidifying side liquid receiving part (25a, 25b) and liquid tank (35) are connected by connecting pipes (15c, 15g), and the liquid absorbent received by each dehumidifying side liquid receiving part (25a, 25b) (That is, the liquid absorbent used for dehumidification) is sent to one liquid tank (35) through each of the connection pipes (15c, 15g).

  The regeneration module (31) includes a regeneration-side liquid supply part (32), a regeneration-side gas-liquid contact part (33), and a liquid tank (35). That is, in the fourth embodiment, the liquid tank (35) is installed on the regeneration module (31) side.

  The regeneration side liquid supply unit (32) is connected to the liquid heating heat exchanger (44) via the connection pipe (15b), and the liquid absorbent heated by the liquid heating heat exchanger (44) is regenerated on the regeneration side. It supplies to a gas-liquid contact part (33).

  The regeneration-side gas-liquid contact section (33) regenerates the liquid absorbent by bringing the liquid absorbent into contact with indoor / outdoor air (RA) as regeneration air. The regenerated air is discharged outdoors as exhaust air (EA).

  The liquid tank (35) is located below the regeneration-side gas-liquid contact portion (33). The liquid tank (35) functions as a regeneration side liquid receiving part for receiving the liquid absorbent regenerated in the regeneration side gas-liquid contact part (33), and stores the liquid absorbent. Thus, in the fourth embodiment, the regeneration side liquid receiving part and the liquid tank are not provided side by side.

  In the liquid tank (35), not only the liquid absorbent that has been regenerated and increased in concentration, but also the liquid absorbent that has been used for dehumidification in each liquid dehumidification module (21a, 21b) and has been mixed and stored. Is done.

  The pump (37) has an input connected to the liquid tank (35) via the connection pipe (15d), and an output connected to the liquid heating heat exchanger (44) and the liquid cooling heat exchanger (via the connection pipe (15e). 46) is connected. By this pump (37), the liquid absorbent stored in the liquid tank (35) is sent to the regeneration module (31) via the liquid heating heat exchanger (44), and at the same time, the liquid cooling heat exchanger (46) Are sent to each liquid dehumidification module (21a, 21b).

  The connection pipe (15e) has one end connected to the output side of the pump (37) and the other end branched into two paths. The two paths are a path connected to the liquid heating heat exchanger (44) via the flow rate adjustment valve (39a) and a path connected to the liquid cooling heat exchanger (46).

  The flow rate adjusting valve (39a) is located on the connecting pipe (15e) between the branch point to the two paths and the liquid heating heat exchanger (44). The flow rate adjustment valve (39a) adjusts the supply amount of the liquid absorbent to the regeneration module (31). The flow rate adjusting valve (39b) is located between the liquid dehumidification module (21a) and the junction of the connection pipes (15a, 15f) in the connection pipe (15a). The flow rate adjusting valve (39b) adjusts the supply amount of the liquid absorbent to the liquid dehumidifying module (21a). The flow regulating valve (39c) is located between the liquid dehumidification module (21b) and the junction of the connection pipes (15a, 15f) in the connection pipe (15f). The flow rate adjustment valve (39c) adjusts the supply amount of the liquid absorbent to the liquid dehumidification module (21b).

  The liquid heating heat exchanger (44) and the liquid cooling heat exchanger (46) are the same as the liquid heating heat exchanger (44) and the liquid cooling heat exchanger (46) according to the first embodiment. That is, the liquid heating heat exchanger (44) heats the liquid absorbent before being supplied to the regeneration module (31) using the refrigerant flowing through the refrigerant circuit (40). The liquid cooling heat exchanger (46) cools the liquid absorbent before being supplied to the liquid dehumidification modules (21a, 21b) using the refrigerant flowing through the refrigerant circuit (40).

-Refrigerant circuit-
In the first embodiment, the refrigerant circuit (40) does not include the heat-radiating condenser (43) and the refrigerant-cooled dehumidifying module (48). In the fourth embodiment, the fan (43a) is not provided. That is, in the fourth embodiment, since the refrigerant-cooled dehumidifying module (48) is not provided, heat radiating means for balancing the amount of heat generation (condensation heat) of the module (48) (specifically, heat radiation condensation) (43) and fan (43a)) are not required.

  Specifically, the refrigerant circuit (40) includes a compressor (42), a liquid heating heat exchanger (44), an expansion valve (45), and a liquid cooling heat exchanger (46) by connecting pipes (40a to 40d). They are connected in series in this order. The liquid heating heat exchanger (44) heats the liquid absorbent by exchanging heat between the refrigerant and the liquid absorbent, and functions as a refrigerant condenser. The liquid cooling heat exchanger (46) cools the liquid absorbent by exchanging heat between the refrigerant and the liquid absorbent, and functions as an evaporator of the refrigerant.

  In the fourth embodiment, since the fan (43a) is not provided, the operation of the fan (43a) by the controller (50) is not performed. The controller (50) controls the operation of the compressor (42) and the opening degree of the flow rate adjustment valve (39a). Further, the controller (50) adjusts the supply amount of the liquid absorbent to the liquid dehumidifying modules (21a, 21b) by controlling the opening degree of the flow rate adjusting valves (39b, 39c).

<Operation of humidity control device>
The refrigerant compressed by the compressor (42) dissipates heat to the liquid absorbent and condenses in the liquid heating heat exchanger (44). The refrigerant that has flowed out of the liquid heating heat exchanger (44) is decompressed by the expansion valve (45) and flows into the liquid cooling heat exchanger (46). In the liquid cooling heat exchanger (46), the refrigerant cools and evaporates the liquid absorbent. Thereafter, the refrigerant is sucked into the compressor (42).

  In the absorbent circuit (15), the pump (37) operates, and the flow rate adjustment valves (39a to 39c) are adjusted to a predetermined opening degree.

  In each liquid dehumidification module (21a, 21b), the liquid absorbent is dropped from each dehumidification side liquid supply part (22a, 22b) to the corresponding dehumidification side gas-liquid contact part (23a, 23b). The dropped liquid absorbent absorbs moisture from the air to be treated (outside air (OA)) and dehumidifies the air. The air dehumidified by each liquid dehumidification module (21a, 21b) is supplied indoors as supply air (SA).

  The liquid absorbent that has absorbed moisture from the air to be treated (outside air (OA)) has a reduced concentration, and once it is received by each dehumidifying side liquid receiving part (25a, 25b), it is connected to the piping. It is sent to the liquid tank (35) via (15c, 15g) and stored. The liquid absorbent stored in the liquid tank (35) passes through the connecting pipe (15d) and then into the liquid heating heat exchanger (44) side and the liquid cooling heat exchanger (46) side in the connecting pipe (15e). Branch and flow.

  The liquid absorbent that has flowed to the liquid heating heat exchanger (44) side is heated by the refrigerant in the heat exchanger (44), and then flows into the regeneration module (31). The liquid absorbent that has flowed into the regeneration module (31) is dropped from the regeneration side liquid supply part (32) to the regeneration side gas-liquid contact part (33). Regeneration air (room air (RA)) is supplied to the regeneration-side gas-liquid contact portion (33), and the dropped liquid absorbent releases moisture to the air. As a result, the liquid absorbent is in a high concentration state and is regenerated. The liquid absorbent is stored in the liquid tank (35) below the regeneration-side gas-liquid contact portion (33).

  That is, the liquid tank (35) is filled with the liquid absorbent whose concentration is increased in the regeneration module (31) and the liquid absorbent whose concentration is reduced in each liquid dehumidification module (21a, 21b). Mixed.

  Note that the regeneration air is used for regeneration of the liquid absorber, and is then discharged outdoors as exhaust air (EA).

  The liquid absorbent that has flowed to the liquid cooling heat exchanger (46) side is cooled by the refrigerant in the heat exchanger (46), and then supplied to each of the liquid dehumidification modules (21a, 21b). The liquid absorbent that has flowed into each liquid dehumidifying module (21a, 21b) is dropped again from each dehumidifying side liquid supply section (22a, 22b) to each dehumidifying side gas-liquid contact section (23a, 23b).

<Effect>
In the fourth embodiment, the liquid absorbent used for dehumidification and the regenerated liquid absorbent are mixed and stored in one liquid tank (35). That is, each liquid dehumidification module (21a, 21b) and regeneration module (31) is not provided with a liquid tank, but is common to each liquid dehumidification module (21a, 21b) and regeneration module (31). One liquid tank (35) is provided. Thereby, the size of the humidity control apparatus (10) becomes smaller than the case where each liquid dehumidification module (21a, 21b) and the regeneration module (31) are provided with a liquid tank. Therefore, the cost of the humidity control apparatus (10) can be suppressed. The liquid absorbent in the liquid tank (35) is positively sent to the respective liquid dehumidification modules (21a, 21b) and the regeneration module (31) without delay by the pump (37).

  Moreover, although the humidity control apparatus (10) of this Embodiment 4 has several liquid type dehumidification modules (21a, 21b), the reproduction | regeneration module (31) is one. Therefore, when at least one of the liquid dehumidifying modules (21a, 21b) is operating, the regeneration module (31) is always operated. In the fourth embodiment, a liquid tank (35) is provided on the regeneration module (31) side, and the liquid tank (35) also functions as a regeneration-side liquid receiver. ing. Thereby, the structure of the humidity control apparatus (10) is simplified rather than the case where a liquid tank (35) is provided separately from each module (21a, 21b, 31). Moreover, since the liquid tank (35) is included in the regeneration module (31) that is always operated, the part that is always necessary for the humidity control device (10) to operate is one regeneration module that is always operating. It can be said that it is within (31).

<< Embodiment 5 >>
The structure of the humidity control apparatus (10) of this Embodiment 5 is shown in FIG. In FIG. 5, the configuration of the refrigerant circuit (40) is the same as that of FIG. 4, but the configuration of the absorbent circuit (15) is slightly different. In FIG. 5, the same reference numerals as those in FIG. 4 are given to the components corresponding to those in FIG. Below, only the part from which a structure differs is demonstrated.

  The liquid absorbent is the same as in the first embodiment.

  The absorbent circuit (15) includes a plurality of liquid dehumidification modules (21a, 21b), one regeneration module (31), one liquid tank (35), one pump (37), and a plurality of flow control valves (39a 39b, 39c), the liquid heating heat exchanger (44) and the liquid cooling heat exchanger (46) are connected by connecting pipes (15a to 15h). Among these, except for the regeneration module (31) and the liquid tank (35), they are the same as in the fourth embodiment.

  The regeneration module (31) has a regeneration-side liquid receiving portion (34) in addition to the regeneration-side liquid supply portion (32) and the regeneration-side gas-liquid contact portion (33) similar to those in the fourth embodiment.

  The regeneration side liquid receiving part (34) is located below the regeneration side gas-liquid contact part (33). The regeneration side liquid receiving part (34) receives the liquid absorbent regenerated by the regeneration side gas-liquid contact part (33). The regeneration side liquid receiving part (34) and the liquid tank (35) are connected by a connection pipe (15h), and the liquid absorbent received by the regeneration side liquid receiving part (34) (ie, the regenerated liquid absorption) The agent is sent to one liquid tank (35) through the connecting pipe (15h).

  The liquid tank (35) is not included in either the liquid dehumidification module (21a, 21b) or the regeneration module (31), and is separate from these modules (21a, 21b, 31). ). The tank unit (36) includes a connection pipe (15d) and a pump (37) in addition to the liquid tank (35). The liquid absorbent that has been used for dehumidification in each liquid dehumidification module (21a, 21b) flows into the liquid tank (35) through the connection pipe (15c, 15g) and the regeneration module (31) The liquid absorbent regenerated in Step 2 flows in through the connection pipe (15h). These liquid absorbents are mixed in the liquid tank (35) and sent to the modules (21a, 21b, 31) via the pump (37) and the connection pipe (15a).

  Thus, in the fifth embodiment, one liquid tank (35) common to the liquid dehumidifying modules (21a, 21b) and the regeneration module (31) is provided. Thereby, the size of the humidity control apparatus (10) becomes smaller than the case where each module (21a, 21b, 31) is provided with a liquid tank. Therefore, the cost of the humidity control device (10) can be reduced. In addition, the liquid absorbent in the liquid tank (35) is actively sent to each module (21a, 21b, 31) without delay by the pump (37).

  In the fifth embodiment, the tank unit (36) including the liquid tank (35) is provided separately from the modules (21a, 21b, 31). Thereby, the freedom degree of the installation place of a tank unit (36) improves, and a liquid tank (35) can be made into an optimal capacity | capacitance. Furthermore, the installation position of the tank unit (36) can be adjusted so that the path of the connecting pipe (15c, 15d, 15g, 15h) connected to the liquid tank (35) is minimized.

Embodiment 6
The structure of the humidity control apparatus (10) of this Embodiment 6 is shown in FIG. In FIG. 6, the configuration of the refrigerant circuit (40) is the same as that of FIGS. 1 to 3, but the configuration of the absorbent circuit (15) is slightly different. In FIG. 6, the same reference numerals as those in FIG. 1 are given to the components corresponding to those in FIG. Below, only the part from which a structure differs is demonstrated.

  The liquid absorbent is the same as in the first embodiment.

  The absorbent circuit (15) consists of a liquid dehumidification module (21), a regeneration module (31), a pump (37), a flow rate adjustment valve (39), a liquid heating heat exchanger (44) and a liquid cooling heat exchanger (46 ) Are connected by connecting pipes (15a, 15b, 16, 15d, 15e). Among these, the pump (37), the flow rate adjusting valve (39), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46) are the pump (37), the flow rate adjusting valve (39) according to the first embodiment. ), Liquid heating heat exchanger (44) and liquid cooling heat exchanger (46).

  The liquid dehumidifying module (21) has the same dehumidifying side liquid supply part (22) and dehumidifying side gas-liquid contact part (23) as in the first embodiment, and the regeneration module (31) is the same as in the first embodiment. It has the same reproduction | regeneration side liquid supply part (32) and the reproduction | regeneration side gas-liquid contact part (33).

  Further, in the sixth embodiment, the liquid dehumidification module (21) includes a dehumidification side liquid receiver (26) and a liquid tank (24). The regeneration module (31) has a regeneration-side liquid receiver (34). That is, the liquid dehumidifying module (21) and the regeneration module (31) have a liquid receiving part (26, 34) dedicated to each module (21, 31).

  The dehumidification side liquid receiving part (26) is located below the dehumidification side gas-liquid contact part (23). The dehumidification side liquid receiver (26) receives the liquid absorbent used for dehumidification in contact with the air to be treated (outside air (OA)) in the dehumidification side gas-liquid contact section (23).

  The regeneration side liquid receiving part (34) is located below the regeneration side gas-liquid contact part (33). The regeneration-side liquid receiver (34) receives the liquid absorbent regenerated in contact with the room air (RA) in the regeneration-side gas-liquid contact section (33).

  The liquid tank (24) is located closer to the liquid dehumidifying module (21) than the regeneration module (31), that is, below the dehumidifying side liquid receiving portion (26). The liquid tank (24) is connected to the dehumidification side liquid receiving part (26) and the regeneration side liquid receiving part (34) by a connection pipe (16) (corresponding to a first connection pipe). In the liquid tank (24), the liquid absorbent received by the liquid receiving portions (26, 34) is introduced and stored through the connection pipe (16).

  Specifically, the connecting pipe (16) has one end connected to the regeneration side liquid receiving part (34) (16a), one end connected to the dehumidifying side liquid receiving part (26) (16b), and The pipe (16c) is connected to the liquid tank (24) at one end. The other ends of these pipes (16a, 16b, 16c) are connected to each other, thereby forming the connection pipe (16).

  In such a connection pipe (16), the liquid absorbent used to dehumidify the air to be treated (outside air (OA)) in the liquid dehumidification module (21) and regenerated in the regeneration module (31) The liquid absorbent is introduced, and these liquid absorbents are mixed in the connection pipe (16). The liquid absorbent mixed in the connection pipe (16) flows into the liquid tank (24) through the connection pipe (16).

  That is, in the sixth embodiment, unlike the first to fifth embodiments, the mixing operation of the liquid absorbent is not performed in the liquid tank (24), but is performed in the connection pipe (16). .

<Effect>
In the sixth embodiment, the liquid absorbent used for dehumidification in the liquid dehumidification module (21) and the liquid absorbent regenerated in the regeneration module (31) are stored in one liquid tank (24). The That is, the liquid dehumidification module (21) and the regeneration module (31) are not provided with a liquid tank, but one liquid tank (24 common to the liquid dehumidification module (21) and the regeneration module (31). ) Is provided. Thereby, the size of the humidity control apparatus (10) becomes smaller than the case where a liquid tank is provided in each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, the cost of the humidity control device (10) can be suppressed. Then, the liquid absorbent in the liquid tank (24) is positively sent to the liquid dehumidification module (21) and the regeneration module (31) without any delay by the pump (37).

  In the sixth embodiment, the liquid absorbent used for dehumidification of the air to be treated (outside air (OA)) in the liquid dehumidification module (21) and the liquid absorbent regenerated in the regeneration module (31) Are mixed in the connecting pipe (16) and then flowed into the liquid tank (24). Thereby, compared with the case where the liquid absorbent is mixed in the liquid tank (24) as in the first embodiment, the liquid absorbent that has been sufficiently mixed and has a uniform temperature is stored in the liquid tank (24). Is done. Therefore, temperature unevenness in the liquid tank (24) is less likely to occur.

  It is conceivable to improve the dehumidifying efficiency by increasing the circulation amount of the liquid absorbent in the liquid dehumidifying module (21) than in the regeneration module (31). In this Embodiment 6, since the liquid tank (24) is located near the liquid dehumidification module (21), the liquid absorbent in the liquid tank (24) is sent to the liquid dehumidification module (21). The length of the connecting pipe (15d, 15e, 15a) can be made shorter than the connecting pipe (15d, 15e, 15b) for sending the liquid absorbent to the regeneration module (31). Therefore, the power of the pump (37) can be reduced.

  In the sixth embodiment, as in the first embodiment, the air to be treated (outside air (OA)) is cooled and dehumidified by the refrigerant-cooled dehumidifying module (48) and then liquid dehumidified using a liquid absorbent. The module (21) is further dehumidified. Therefore, the amount of dehumidification in the liquid dehumidification module (21) is smaller than in the case where the air to be treated (outside air (OA)) is dehumidified only by the liquid dehumidification module (21). Therefore, the amount of liquid absorbent required for dehumidification in the liquid dehumidification module (21) can be smaller than that in the case of dehumidification only with the liquid dehumidification module (21). In addition, the change in the concentration of the liquid absorbent in the liquid dehumidification module (21) is smaller than that in the case of dehumidification only with the liquid dehumidification module (21). Even if stored in 24), the effect on the dehumidification performance by mixing liquid absorbents with different concentrations is small. In other words, even if the liquid dehumidifying module (21) and the regenerating module (31) mixed with the liquid absorbent are stored in one liquid tank (24), the performance of the humidity control device (10) There will be no problem.

  In the sixth embodiment, similarly to the first embodiment, one pump (37) is connected to the liquid tank (24), and the liquid dehumidification is performed from the pump (37) through the connection pipe (15e). The liquid absorbent is branched and flowed to each of the module (21) and the regeneration module (31). As described above, the liquid absorbent can be sent to the liquid dehumidification module (21) and the regeneration module (31) without using a plurality of pumps, and the humidity control apparatus (10 ) Manufacturing cost and power consumption can be reduced. Moreover, since the number of pumps (37) is small, the time required for maintenance of the humidity control apparatus (10) can be reduced accordingly.

<< Embodiment 7 >>
The configuration of the humidity control apparatus (10) of the seventh embodiment is shown in FIG. In FIG. 7, the configuration of the refrigerant circuit (40) is the same as that of FIGS. 1 to 3 and 6, but the configuration of the absorbent circuit (15) is slightly different. In FIG. 7, the same reference numerals as those in FIG. 1 are given to the components corresponding to those in FIG. Below, only the part from which a structure differs is demonstrated.

  The liquid absorbent is the same as in the first embodiment.

  The absorbent circuit (15) consists of a liquid dehumidification module (21), a regeneration module (31), a pump (37), a flow rate adjustment valve (39), a liquid heating heat exchanger (44) and a liquid cooling heat exchanger (46 ) Are connected by connecting pipes (15a, 15b, 17, 18, 15d, 15e). Among these, the pump (37), the flow rate adjusting valve (39), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46) are the pump (37), the flow rate adjusting valve (39) according to the first embodiment. ), Liquid heating heat exchanger (44) and liquid cooling heat exchanger (46).

  The liquid dehumidifying module (21) has the same dehumidifying side liquid supply part (22) and dehumidifying side gas-liquid contact part (23) as in the first embodiment, and the regeneration module (31) is the same as in the first embodiment. It has the same reproduction | regeneration side liquid supply part (32) and the reproduction | regeneration side gas-liquid contact part (33).

  Furthermore, in the seventh embodiment, the liquid dehumidification module (21) includes a dehumidification side liquid receiver (26) and a liquid tank (24). The regeneration module (31) has a regeneration-side liquid receiver (34). That is, the liquid dehumidifying module (21) and the regeneration module (31) have a liquid receiving part (26, 34) dedicated to each module (21, 31).

  The dehumidification side liquid receiving part (26) is located below the dehumidification side gas-liquid contact part (23). The dehumidification side liquid receiver (26) receives the liquid absorbent used for dehumidification in contact with the air to be treated (outside air (OA)) in the dehumidification side gas-liquid contact section (23).

  The regeneration side liquid receiving part (34) is located below the regeneration side gas-liquid contact part (33). The regeneration-side liquid receiver (34) receives the liquid absorbent regenerated in contact with the room air (RA) in the regeneration-side gas-liquid contact section (33).

  These liquid receiving portions (26, 34) are connected by a connection pipe (17) (corresponding to a second connection pipe). Specifically, one end of the connection pipe (17) is connected to the regeneration side liquid receiving part (34), and the other end of the connection pipe (17) is connected to the dehumidification side liquid receiving part (26).

  The liquid tank (24) is located closer to the liquid dehumidifying module (21) than the regeneration module (31), that is, below the dehumidifying side liquid receiving portion (26). The liquid tank (24) is connected to the dehumidification side liquid receiving part (26) by a connection pipe (18) (corresponding to a liquid feed part) different from the connection pipe (17). In the liquid tank (24), the liquid absorbent received by the liquid receiving portions (26, 34) is introduced and stored through the connection pipes (17, 18).

  Specifically, the liquid absorbent regenerated by the regeneration module (31) flows from the regeneration side liquid receiver (34) into the dehumidification side liquid receiver (26) through the connection pipe (17). In the dehumidification side liquid receiving part (26), the liquid absorbent and the liquid absorbent dripped from the dehumidification side gas-liquid contact part (23) (that is, the liquid used for dehumidification of the air to be treated (outside air (OA)) The liquid absorbent mixed in the dehumidifying side liquid receiving section (26) flows into the liquid tank (24) through the connection pipe (18).

  That is, in the seventh embodiment, unlike the first to fifth embodiments, the liquid absorbent mixing operation is not performed in the liquid tank (24), but in the dehumidification side liquid receiver (26). Done.

<Effect>
In the seventh embodiment, the liquid absorbent used for dehumidification in the liquid dehumidification module (21) and the liquid absorbent regenerated in the regeneration module (31) are stored in one liquid tank (24). The That is, the liquid dehumidification module (21) and the regeneration module (31) are not provided with a liquid tank, but one liquid tank (24 common to the liquid dehumidification module (21) and the regeneration module (31). ) Is provided. Thereby, the size of the humidity control apparatus (10) becomes smaller than the case where a liquid tank is provided in each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, the cost of the humidity control device (10) can be suppressed. Then, the liquid absorbent in the liquid tank (24) is positively sent to the liquid dehumidification module (21) and the regeneration module (31) without any delay by the pump (37).

  In the seventh embodiment, the liquid absorbent regenerated by the regeneration module (31) flows from the regeneration side liquid receiving part (34) into the dehumidifying side liquid receiving part (26) through the connection pipe (17). Then, the liquid absorbent used for dehumidification of the air to be treated is mixed with the dehumidifying side liquid receiver (26). The liquid absorbent after mixing flows into the liquid tank (24) through the connection pipe (18). Thereby, compared with the case where the liquid absorbent is mixed in the liquid tank (24) as in the first embodiment, the liquid absorbent that has been sufficiently mixed and has a uniform temperature is stored in the liquid tank (24). Is done. Therefore, temperature unevenness in the liquid tank (24) is less likely to occur.

  It is conceivable to improve the dehumidifying efficiency by increasing the circulation amount of the liquid absorbent in the liquid dehumidifying module (21) than in the regeneration module (31). In the seventh embodiment, since the liquid tank (24) is located closer to the liquid dehumidification module (21), the liquid absorbent in the liquid tank (24) is used as the liquid dehumidification module. The length of the connecting pipe (15d, 15e, 15a) for sending to (21) can be shorter than the connecting pipe (15d, 15e, 15b) for sending the liquid absorbent to the regeneration module (31) . Therefore, the power of the pump (37) can be reduced.

  In the seventh embodiment, similarly to the first embodiment, the air to be treated (outside air (OA)) is cooled and dehumidified by the refrigerant-cooled dehumidifying module (48), and then liquid dehumidified using a liquid absorbent. The module (21) is further dehumidified. Therefore, the amount of dehumidification in the liquid dehumidification module (21) is smaller than in the case where the air to be treated (outside air (OA)) is dehumidified only by the liquid dehumidification module (21). Therefore, the amount of liquid absorbent required for dehumidification in the liquid dehumidification module (21) can be smaller than that in the case of dehumidification only with the liquid dehumidification module (21). In addition, the change in the concentration of the liquid absorbent in the liquid dehumidification module (21) is smaller than that in the case of dehumidification only with the liquid dehumidification module (21). Even if stored in 24), the effect on dehumidification performance by mixing liquid absorbents with different concentrations is small. In other words, even if the liquid dehumidifying module (21) and the regenerating module (31) mixed with the liquid absorbent are stored in one liquid tank (24), the performance of the humidity control device (10) There will be no problem.

  In the seventh embodiment, similarly to the first embodiment, one pump (37) is connected to the liquid tank (24), and the liquid dehumidification is performed from the pump (37) through the connection pipe (15e). The liquid absorbent is branched and flowed to each of the module (21) and the regeneration module (31). As described above, the liquid absorbent can be sent to the liquid dehumidification module (21) and the regeneration module (31) without using a plurality of pumps, and the humidity control apparatus (10 ) Manufacturing cost and power consumption can be reduced. Moreover, since the number of pumps (37) is small, the time required for maintenance of the humidity control apparatus (10) can be reduced accordingly.

<< Other Embodiments >>
The refrigerant cooling type dehumidifying module (48) only needs to be able to cool and dehumidify the air to be treated. Therefore, the medium used when cooling and dehumidifying the air to be treated may be water or the like instead of the refrigerant.

  A plurality of reproduction modules (31) may be provided.

  For example, in Embodiments 1 to 3, a heat exchanger for sensible heat treatment may be separately installed on the upstream side of the refrigerant-cooled dehumidification module (48). The heat exchanger for sensible heat treatment may perform sensible heat treatment on the outside air (OA), which is the air to be treated, using a heat source (for example, underground heat) different from the refrigerant-cooled dehumidification module (48).

  The heat dissipating fluid radiated by the heat dissipating condenser (43) may be water other than indoor air (RA), and may be water. In this case, the heat dissipating condenser (43) is composed of a heat exchanger of refrigerant and water, and a water circulation circuit having a pump for supplying water to the heat dissipating condenser (43) instead of the fan (43a). It may be provided separately.

  The heat dissipation condenser (43) and the fan (43a) are not essential and may not be provided.

  Even if the heat dissipating condenser (43) is provided, the condition for stopping the supply of the heat dissipating fluid to the heat dissipating condenser (43) is not limited to the case where the condensation temperature of the refrigerant is equal to or lower than a predetermined value. For example, when the latent heat load is equal to or lower than a predetermined load, the supply control unit (51) generates heat (condensation heat) in the refrigerant-cooled dehumidification module (48) to be processed by the heat dissipation condenser (43). The operation of the fan (43a) may be stopped by determining that it does not exist. In this case, when the latent heat load exceeds the predetermined load, the supply control unit (51) has a heat generation (condensation heat) amount in the refrigerant-cooled dehumidification module (48) to be processed by the heat dissipation condenser (43). Then, the fan (43a) is operated. Whether or not the latent heat load exceeds a predetermined load may be determined based on whether or not the dew point temperature of the outside air (OA) is higher than the evaporation temperature of the refrigerant. That is, the amount of heat generation (condensation heat) in the refrigerant-cooled dehumidification module (48) is such that the heat generation amount of the two dehumidification modules (21, 48) cannot be processed only by the heat radiation of the regeneration module (31). In some cases, the fan (43a) is operated to radiate heat in the heat radiating condenser (43).

  In the seventh embodiment, the case where the regenerated liquid absorbent and the liquid absorbent used for dehumidification are mixed in the dehumidification side liquid receiver (26) has been described. As shown in FIG. 8, it may be in the regeneration side liquid receiver (34). Specifically, in FIG. 8, the connection pipe (18) (corresponding to the liquid feeding section) is connected to the dehumidification side liquid receiving section (26) and the regeneration side liquid receiving section (34) (17) (second This is a separate pipe from the connection pipe), and connects the regeneration side liquid receiving part (34) and the liquid tank (24). The liquid absorbent used to dehumidify the air to be treated in the dehumidifying side liquid receiving part (26) is transferred from the dehumidifying side liquid receiving part (26) to the regeneration side liquid receiving part (34) via the connection pipe (17). After flowing in, it is mixed with the regenerated liquid absorbent in the regeneration side liquid receiver (34). The mixed liquid absorbent flows into the liquid tank (24) through the connection pipe (18). Also by this, similarly to the said Embodiment 7, rather than the case where the liquid absorbent is mixed in the liquid tank (24), the liquid absorbent is sufficiently mixed in the liquid tank.

  In FIG. 8, the liquid tank (24) is installed in the regeneration module (31), but may be installed in the liquid dehumidification module (21) as in the seventh embodiment.

  7 and 8, the case where the liquid feeding part (18) is configured by piping has been described. However, the liquid feeding unit may have any configuration as long as it sends the liquid absorbent to the liquid tank (24), and may not be limited to the pipe. For example, the liquid feeding unit may be configured such that a hole is formed in the bottom of the dehumidifying side liquid receiving unit (26) in FIG. 7 and the liquid absorbent is dropped from the hole to the liquid tank (24). it can. Further, in FIG. 8, the liquid feeding part has a structure in which a hole is formed at the bottom of the regeneration side liquid receiving part (34), and the liquid absorbent is dropped from the hole to the liquid tank (24). it can.

  As described above, the present invention has an effect that the size of the humidity control device can be made smaller than when a liquid tank is provided in each of the liquid dehumidifying unit and the regenerating unit. Therefore, the present invention is useful as a humidity control apparatus that can be installed in places where it is difficult to install a large-size humidity control apparatus.

10 Humidity control device
15c Connection piping (Piping)
16 Connection piping (first connection piping)
17 Connection piping (second connection piping)
18 Connection piping (liquid feeding part)
21 Liquid dehumidification module (Liquid dehumidification part)
22 Dehumidifying side gas-liquid contact area
24,35 liquid tank
26 Dehumidifying liquid receiver
31 Playback module (playback unit)
32 Regeneration side gas-liquid contact area
34 Regeneration side liquid receiver
37,37a, 37b pump
48 Refrigerant cooling dehumidification module (cooling dehumidification part)

Claims (4)

A liquid dehumidifying part (21) for absorbing moisture in the air to be treated by the liquid absorbent and dehumidifying the air to be treated;
A regeneration unit (31) for regenerating the liquid absorbent by releasing the moisture of the liquid absorbent into regeneration air;
One liquid tank ( 24 ) that stores the liquid absorbent used for dehumidification of the air to be treated in the liquid dehumidifying section (21) and the liquid absorbent regenerated in the regeneration section (31) )When,
A pump ( 37 ) for sending the liquid absorbent stored in the liquid tank ( 24 ) to each of the liquid dehumidification part (21) and the regeneration part (31) ,
The liquid dehumidifying part (21)
A dehumidifying side gas-liquid contact portion (23) for contacting the liquid absorbent and the air to be treated;
A dehumidifying side liquid receiving part (26) for receiving the liquid absorbent in contact with the air to be treated below the dehumidifying side gas-liquid contact part (23);
Have
The playback unit (31)
A regeneration-side gas-liquid contact portion (33) for bringing the liquid absorbent into contact with the regeneration air;
A regeneration side liquid receiving portion (34) for receiving the liquid absorbent in contact with the regeneration air below the regeneration side gas-liquid contact portion (33);
Have
A second connection pipe (17) connecting the regeneration side liquid receiving part (34) and the dehumidifying side liquid receiving part (26);
A liquid feeding part (18) for sending the liquid absorbent from the dehumidifying side liquid receiving part (26) to the liquid tank (24), and
The liquid absorbent regenerated in the regeneration unit (31) flows from the regeneration side liquid receiving unit (34) into the dehumidification side liquid receiving unit (26) through the second connection pipe (17). Thereafter, the liquid absorbent used for dehumidification of the air to be treated and the dehumidification side liquid receiver (26) are mixed,
The liquid absorbent after mixing is introduced into the liquid tank (24) via the liquid feeding section (18),
The liquid tank (24) is located below the dehumidifying side liquid receiving part (26).
A humidity control apparatus characterized by that.   A liquid dehumidifying part (21) for absorbing moisture in the air to be treated by the liquid absorbent and dehumidifying the air to be treated;
  A regeneration unit (31) for regenerating the liquid absorbent by releasing the moisture of the liquid absorbent into regeneration air;
  One liquid tank (24) storing the liquid absorbent used for dehumidification of the air to be treated in the liquid dehumidifying part (21) and the liquid absorbent regenerated in the regenerating part (31) )When,
  A pump (37) for sending the liquid absorbent stored in the liquid tank (24) to the liquid dehumidifying part (21) and the regenerating part (31), respectively;
With
  The liquid dehumidifying part (21)
A dehumidifying side gas-liquid contact portion (23) for contacting the liquid absorbent and the air to be treated;
A dehumidifying side liquid receiving part (26) for receiving the liquid absorbent in contact with the air to be treated below the dehumidifying side gas-liquid contact part (23);
Have
  The playback unit (31)
A regeneration-side gas-liquid contact portion (33) for bringing the liquid absorbent into contact with the regeneration air;
A regeneration side liquid receiving portion (34) for receiving the liquid absorbent in contact with the regeneration air below the regeneration side gas-liquid contact portion (33);
Have
  A second connection pipe (17) connecting the regeneration side liquid receiving part (34) and the dehumidifying side liquid receiving part (26);
  A liquid feeding part (18) for sending the liquid absorbent from the regeneration side liquid receiving part (34) to the liquid tank (24), and
  The liquid absorbent used for dehumidifying the air to be treated in the liquid dehumidifying part (21) is supplied from the dehumidifying side liquid receiving part (26) to the regeneration side via the second connection pipe (17). After flowing into the liquid receiving part (34), it is mixed with the regenerated liquid absorbent and the regenerating side liquid receiving part (34),
  The liquid absorbent after mixing is introduced into the liquid tank (24) via the liquid feeding section (18),
  The liquid tank (24) is located below the regeneration-side liquid receiver (34).
A humidity control apparatus characterized by that. In claim 1 or claim 2 ,
The humidity control apparatus, wherein the liquid tank (24) is located closer to the liquid dehumidifying part (21) than the regenerating part (31). In any one of Claims 1-3 ,
Cooling dehumidification that is located upstream of the liquid dehumidifying part (21) in the flow direction of the air to be treated and cools and dehumidifies the air to be treated before being dehumidified by the liquid dehumidifying part (21) Part (48),
A humidity control apparatus further comprising:

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