JP7137054B2 - Humidity control device - Google Patents

Description

The present disclosure relates to a humidity control device.

2. Description of the Related Art As disclosed in Japanese Unexamined Patent Application Publication No. 2002-100000, there is a type of apparatus for adjusting indoor humidity that uses a hygroscopic liquid as a liquid absorbent.

The humidity control apparatus of Patent Document 1 includes a dehumidifying section (processing machine) that dehumidifies the interior of the room, and a regenerating section (regenerating machine) that regenerates the liquid absorbent used for dehumidification. The dehumidifying section (processing machine) passes the air to be processed through a cooled liquid absorbent to absorb moisture in the air and dehumidify the air. The regenerating unit regenerates the liquid absorbent by passing regenerating air through the liquid absorbent that has been heated after it has been used for dehumidification, thereby releasing moisture in the liquid absorbent into the air.

JP 2010-36093 A

In Patent Document 1, the liquid absorbent in contact with the air to be treated in the dehumidification section and the liquid absorbent in contact with the regeneration air in the regeneration section are mixed at a predetermined ratio, and the liquid absorbent after mixing is Supplied to the dehumidification section or regeneration section. Insufficient mixing affects the operating efficiency of the humidity control system.

An object of the present disclosure is to suppress uneven mixing of the liquid absorbent in contact with the air to be treated in the dehumidification section and the liquid absorbent in contact with the regeneration air in the regeneration section.

A first aspect of the present disclosure comprises a liquid dehumidifying section (21) for dehumidifying the air to be treated by causing the liquid absorbent to absorb moisture in the air to be treated; the liquid absorbent used for dehumidification of the air to be treated in the liquid dehumidifying section (21) and the liquid absorbent in the regenerating section (31) a first pump (37) for sending a mixed liquid mixed with the regenerated liquid absorbent to the liquid dehumidifying section (21) and the regenerating section (31), respectively; and the liquid dehumidifying section (21). accelerating section (24, 26, 16c, 51, 15c , 15d, 27a, 27b, 28, 29, 37, 38).

As a result, the mixed liquid whose mixing unevenness is suppressed by the promotion section is sent to each of the liquid dehumidifying section and the regeneration section.

A second aspect of the present disclosure is the first aspect, further comprising a liquid tank (25) for storing the mixed liquid, the mixed liquid flowing into and being stored in the liquid tank (25), The promoting part (24, 26, 16c, 51) is provided upstream of the liquid tank (25) in the direction in which the mixture flows into the liquid tank (25). It is a humidity control device.

In the second aspect, since the promoting section is provided before the mixed liquid flows into the liquid tank, the mixed liquid whose mixing unevenness is suppressed by the promoting section is stored in the liquid tank.

A third aspect of the present disclosure is a humidity control apparatus according to the second aspect, characterized in that the promotion part (24, 26) is configured by a container separate from the liquid tank (25). be.

As a result, the mixed liquid whose mixing unevenness is suppressed by the promoting section separate from the liquid tank surely flows into the liquid tank.

A fourth aspect of the present disclosure is, in the first aspect or the second aspect, a dehumidifying side pipe ( 16b), the regeneration side pipe (16a) through which the liquid absorbent regenerated in the regeneration section (31) flows, the dehumidification side pipe (16b) and the regeneration side pipe (16a) are connected to the The humidity control apparatus further comprises a mixing pipe (16c) through which the mixed liquid flows, wherein the mixing pipe (16c) also serves as the promoting section.

In the fourth aspect, the liquid absorbent used for dehumidification and the regenerated liquid absorbent are mixed while flowing through the promoting section, which is a mixing pipe. As a result, there is no need to separately provide a promotion unit such as a container, so that the humidity control apparatus can be made inexpensive and compact.

A fifth aspect of the present disclosure is, in the first aspect or the second aspect, a dehumidifying side pipe ( 16b), the regeneration side pipe (16a) through which the liquid absorbent regenerated in the regeneration section (31) flows, the dehumidification side pipe (16b) and the regeneration side pipe (16a) are connected to the a mixing pipe (16c) through which the mixed liquid flows; and a second pump (51) connected to the mixing pipe (16c) and provided in common with or separately from the first pump (37), The second pump (51) is a humidity control device characterized in that it also serves as the promotion section.

In the fifth aspect, the liquid absorbent used for dehumidification and the regenerated liquid absorbent are agitated by the acceleration section composed of the second pump, thereby suppressing uneven mixing.

A sixth aspect of the present disclosure is, in the first aspect, further provided with a liquid tank (25) for storing the mixed liquid, and the promoting section (15c, 15d, 27a, 27b) includes the liquid dehumidifying section ( At least one of the liquid absorbent used for dehumidifying the air to be treated in 21) and the liquid absorbent regenerated in the regenerating section (31) is dispersed and dispersed in the liquid tank (25). It is a dehumidifier characterized by flowing into.

In the sixth aspect, the dispersion of the liquid absorbent in the promoting section promotes mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent, and the mixed liquid is stored in the liquid tank.

A seventh aspect of the present disclosure, in the first aspect or the sixth aspect, further comprises a liquid tank (25) for storing the mixed liquid, and the promoting section (27a, 27b, 28, 29) The humidity control device is provided in the liquid tank (25).

As a result, it is possible to reduce the size of the humidity control apparatus because it is not necessary to provide a separate acceleration unit outside the liquid tank.

An eighth aspect of the present disclosure is the first aspect, further comprising a liquid tank (25) for storing the mixed liquid, and the promoting part (37, 38) flows out of the liquid tank (25). The dehumidifier is characterized by comprising pumps (37, 38) for returning at least part of the liquid mixture to the liquid tank (25).

As a result, the liquid mixture circulates within the liquid tank, and the mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted within the liquid tank.

FIG. 1 is a diagram schematically showing the configuration of the humidity control apparatus of Embodiment 1. FIG. FIG. 2 is a diagram schematically showing the configuration of a humidity control apparatus according to a modification of Embodiment 1. FIG. FIG. 3 is a diagram schematically showing the configuration of the humidity control apparatus of Embodiment 2. FIG. FIG. 4 is a view showing only the vicinity of the liquid tank in the humidity control apparatus according to Modification 1 of Embodiment 2. As shown in FIG. FIG. 5 is a diagram schematically showing the configuration of a humidity control apparatus according to Modification 2 of Embodiment 2. As shown in FIG. FIG. 6 is a diagram schematically showing the configuration of a humidity control apparatus according to Modification 3 of Embodiment 2. As shown in FIG. FIG. 7 is a diagram schematically showing the configuration of the humidity control apparatus of Embodiment 3. FIG. FIG. 8 is a diagram schematically showing the configuration of a humidity control apparatus according to Modification 1 of Embodiment 3. FIG. FIG. 9 is a diagram schematically showing the configuration of a humidity control apparatus according to Modification 2 of Embodiment 3. FIG. 10 is a diagram schematically showing the configuration of a humidity control apparatus according to Modification 3 of Embodiment 3. FIG. 11 is a diagram schematically showing the configuration of a humidity control apparatus according to Modification 4 of Embodiment 3. FIG. FIG. 12 is a diagram showing only the vicinity of the liquid tank in the humidity control apparatus according to the fourth embodiment. FIG. 13 is a diagram showing only the vicinity of the liquid tank according to the modification of the fourth embodiment. 14 is a diagram schematically showing the configuration of a humidity control apparatus according to Embodiment 5. FIG. FIG. 15 is a diagram showing only the vicinity of the liquid tank according to the modification of the fifth embodiment.

<<Embodiment 1>>
<Overview>
A humidity control device (10) according to Embodiment 1 is a device that dehumidifies an internal space (hereinafter referred to as a room) of an office building, a house, or the like, mainly using a liquid absorbent.

As shown in FIG. 1, the humidity control device (10) includes a dehumidification module (20) for dehumidifying air. The dehumidifying module (20) includes a liquid dehumidifying module (21) (corresponding to a liquid dehumidifying section) that dehumidifies using a liquid absorbent, and a refrigerant cooling type dehumidifying module (48) that dehumidifies using a refrigerant.

The 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 dehumidification module (21) is included in equipment that constitutes the absorbent circuit (15). All the devices that make up the absorbent circuit (15) are installed in a space separate from the room (for example, a machine room). Devices that make up the refrigerant circuit (40) include the refrigerant cooling dehumidification module (48), the compressor (42), and the condenser for heat release (43). The compressor (42) and the heat radiation condenser (43) are included in the outdoor unit (41) and installed outdoors. Among the devices constituting the refrigerant circuit (40), the devices other than the compressor (42) and the heat radiation condenser (43) are placed in a separate space from the room in the same way as the devices constituting the absorbent circuit (15). (e.g. machine room).

- liquid absorbent -
The liquid absorbent is a liquid capable of absorbing moisture (water vapor) in the air. In Embodiment 1, an ionic liquid having a higher viscosity than liquid absorbents commonly used in humidity control devices (lithium chloride aqueous solution, lithium bromide aqueous solution, calcium chloride, etc.) is used as the liquid absorbent. Specifically, the viscosity of the liquid absorbent is approximately 3 to 20 times the viscosity of general liquid absorbents. Although the liquid absorbent according to Embodiment 1 is inferior to general liquid absorbents in hygroscopic performance, it has low corrosive properties and can be used safely. Note that an ionic liquid is a salt composed of ions, and has the property of being in a liquid state at 100 degrees Celsius or less.

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

- Absorbent circuit -
The absorbent circuit (15) has the liquid dehumidification module (21) and the regeneration module (31) (corresponding to the regeneration section) as modules for transferring moisture between the liquid absorbent and air. Furthermore, the absorbent circuit (15) has a pump (37) (corresponding to the first pump), a flow control 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), etc. by connecting pipes (15a-15f).

－Liquid dehumidification module－
The liquid dehumidification module (21) dehumidifies the air to be treated by causing the liquid absorbent to absorb moisture in the air to be treated. The liquid dehumidification module (21) has a dehumidification side liquid supply section (22), a dehumidification side gas-liquid contact section (23), a dehumidification side liquid receiving section (24), and a liquid tank (25).

In the dehumidification side liquid supply part (22), for example, a pipe portion connected to one end of the connection pipe (15a) is provided with a plurality of drip ports for dripping the liquid absorbent arranged in the extending direction of the pipe portion. It has a configured configuration.

The dehumidification side gas-liquid contact portion (23) is made of a hydrophilic filler and is located below the dehumidification side liquid supply portion (22). The dehumidification side gas-liquid contact portion (23), when supplied with outside air (OA) as air to be treated, contacts the outside air (OA) with the liquid absorbent dripped from the dehumidification side liquid supply portion (22). Let As a result, the amount of moisture contained in the outside air (OA) that has passed through the dehumidification side gas-liquid contact portion (23) is less than before the passage, and is in a dehumidified state. That is, the concentration of the liquid absorbent after being dropped on the dehumidifying side gas-liquid contact portion (23) and coming into contact with the outside air (OA) is lower than before being dropped on the dehumidifying side gas-liquid contact portion (23). .

The dehumidification side liquid receiving portion (24) is positioned below the dehumidification side gas-liquid contact portion (23). The dehumidification side liquid receiving portion (24) receives the liquid absorbent used for dehumidification by coming into contact with the outside air (OA) at the dehumidification side gas-liquid contact portion (23). The dehumidification side liquid receiving portion (24) is connected to a later-described regeneration side liquid receiving portion (34) by a connection pipe (15c), and the regenerated liquid absorbent also flows thereinto. That is, the liquid absorbent used for dehumidification and the regenerated liquid absorbent flow into the dehumidification side liquid receiving section (24) and are mixed in the liquid receiving section (24). Here, the concentration of the liquid absorbent used for dehumidification is lower than the concentration of the regenerated liquid absorbent. Accordingly, the low-concentration liquid absorbent used for dehumidification and the regenerated low-concentration liquid absorbent are mixed in the dehumidification side liquid receiving section (24).

The liquid tank (25) is connected to the dehumidification side liquid receiver (24) through a connecting pipe (15d). The liquid tank (25) stores the liquid absorbent (hereinafter, mixed liquid) that has been mixed in the dehumidification side liquid receiving portion (24).

That is, in the present embodiment, a dehumidification side configured by a container separate from the liquid tank (25) is arranged upstream of the liquid tank (25) in the direction of inflow of the mixed liquid into the liquid tank (25). A liquid receiver (24) is provided. The dehumidification-side liquid receiving portion (24) corresponds to an acceleration portion that promotes mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent.

－Playback module－
The regeneration module (31) regenerates the liquid absorbent by releasing water in the liquid absorbent into the regeneration air. The regeneration module (31) has a regeneration side liquid supply section (32), a regeneration side gas-liquid contact section (33), and a regeneration side liquid receiving section (34).

The regeneration side liquid supply part (32) has, for example, a pipe portion connected to one end of the connection pipe (15b), and a plurality of drip ports for dripping the liquid absorbent are formed in a line in the extending direction of the pipe portion. It has a configured configuration.

The regeneration-side gas-liquid contact portion (33) is made of a hydrophilic filler and positioned below the regeneration-side liquid supply portion (32). When indoor air (RA), which is regeneration air, is supplied to the regeneration-side gas-liquid contact portion (33), the room air (RA) is supplied to the liquid absorbent dripped from the regeneration-side liquid supply portion (32). come into contact with As a result, the amount of water contained in the dripped 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) changes to ) is darker than it was before it was dropped into the

The regeneration-side liquid receiving portion (34) is positioned below the regeneration-side gas-liquid contact portion (33). The regeneration-side liquid receiver (34) receives the liquid absorbent regenerated by coming into contact with the room air (RA) in the regeneration-side gas-liquid contact section (33). The regeneration side liquid receiver (34) and the dehumidification side liquid receiver (24) are connected by the connecting pipe (15c) as already described, and the liquid received by the regeneration side liquid receiver (34) is absorbed. The agent (that is, the regenerated liquid absorbent) is sent to the dehumidification side liquid receiver (24) through the connecting pipe (15c).

In particular, the connection pipe (15c) has a liquid inlet at the bottom of the regeneration side liquid receiver (34) and an upper portion of the dehumidification side liquid receiver (24) as a liquid outlet, and connects the regeneration side liquid receiver (34) and the dehumidification side. It connects the liquid receiver (24). The connection pipe (15d) has a liquid inlet at the bottom of the dehumidification side liquid receiver (24) and a liquid outlet at the side of the liquid tank (25), and connects the dehumidification side liquid receiver (24) and the liquid tank (25). connected. In each connecting pipe (15c, 15d), the liquid outlet is below the liquid inlet. Therefore, the liquid absorbent flows from the regeneration side liquid receiver (34) to the dehumidification side liquid receiver (24) and from the dehumidification side liquid receiver (24) to the liquid tank (25) by gravity (the weight of the liquid absorbent itself). It is designed to flow in using Therefore, even if power such as a pump for positively feeding the liquid absorbent is not provided between the connection pipes (15c, 15d), the regenerated liquid absorbent and the liquid absorbent used for dehumidification can be transferred to the dehumidifying side. It can flow into the liquid receiver (24) and the liquid tank (25) in order.

-pump-
The pump (37) is connected to the connection pipe (15e) and the connection pipe (15f). The pump (37) sends the mixed liquid stored in the liquid tank (25) again to the liquid dehumidification module (21) and the regeneration module (31). That is, the pump (37) is for circulating the liquid absorbent between the liquid dehumidification module (21) and the regeneration module (31).

Here, the connecting pipe (15e) has one end connected to the liquid tank (25) and the other end connected to the input side of the pump (37). One end of the connection pipe (15f) is connected to the output side of the pump (37). The other end of the connecting pipe (15f) branches into two paths, one path is connected to the liquid cooling heat exchanger (46) and the other path is connected to the liquid heating heat exchanger via the flow control valve (39). (44).

－Flow control valve－
The flow rate control valve (39) is composed of an electromagnetic proportional valve, and adjusts the flow rate of the liquid absorbent by adjusting the degree of opening. After exiting the pump (37), the mixed liquid stored in the liquid tank (25) branches and flows not only to the liquid cooling heat exchanger (46) but also to the liquid heating heat exchanger (44). can be done. By adjusting the degree of 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) are adjusted. Adjusted to a given ratio.

－Liquid Heating Heat Exchanger－
The liquid heating heat exchanger (44) is of a plate type, for example, and has an absorbent passage through which the liquid absorbent passes and a refrigerant passage through which the refrigerant passes, though not shown. The inlet side of the absorbent passage is connected to the connection pipe (15f), and the outlet side of the absorbent passage is connected to the regeneration side liquid supply section (32) of the regeneration module (31) through the connection pipe (15b). The inlet side of the refrigerant passage is connected to the heat dissipation condenser (43) through the connecting pipe (40c), and the outlet side of the refrigerant passage is connected to the expansion valve (45) through the connecting pipe (40d). . The liquid heating heat exchanger (44) functions as a refrigerant condenser, and heat-exchanges between the liquid absorbent passing through the absorbent passage and the refrigerant passing through the refrigerant passage, thereby regenerating the refrigerant in the regeneration module (31). A refrigerant heats the liquid absorbent before it is applied. After passing through the liquid heating heat exchanger (44), the liquid absorbent is sent to the regeneration module (31) and regenerated.

－Liquid cooling heat exchanger－
The liquid cooling heat exchanger (46) is, for example, of a plate type and, although not shown, has an absorbent passage through which the liquid absorbent passes and a refrigerant passage through which the refrigerant passes, similarly to the liquid heating heat exchanger (44). and a coolant passage. The inlet side of the absorbent passage is connected to the connection pipe (15f), and the outlet side of the absorbent passage is connected to the dehumidification side liquid supply section (22) of the liquid dehumidification module (21) via the connection pipe (15a). be. 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). be. 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 is cooled by the refrigerant before it is used for dehumidification in the liquid dehumidification module (21). After passing through the liquid cooling heat exchanger (46), the liquid absorbent is sent to the liquid dehumidification module (21) and used for dehumidification.

-Refrigerant circuit-
A refrigerant circuit (40) includes a compressor (42), a heat release 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) are connected in series in this order by connecting pipes (40a-40f). Components of the refrigerant circuit (40) other than the liquid heating heat exchanger (44) and the liquid cooling heat exchanger (46) described above will be described below.

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

－Condenser for heat dissipation－
The heat radiation condenser (43) is, for example, of a fin-and-tube type. ) to the inlet of the refrigerant passage in the liquid heating heat exchanger (44). That is, the heat radiation condenser (43) is positioned downstream of the refrigerant cooling dehumidification module (48) in the refrigerant flow direction. The heat radiation condenser (43) releases the heat of the refrigerant discharged from the compressor (42) after passing through the refrigerant cooling dehumidification module (48) to the heat radiation fluid to condense the refrigerant. After releasing the heat, the refrigerant further releases heat to the liquid absorbent and condenses in the liquid heating heat exchanger (44).

The heat-dissipating fluid is other than indoor air (RA), and includes, for example, outside air (OA) and water. In the present embodiment, the case where the heat releasing fluid is outside air (OA) and the heat releasing condenser (43) is an air-refrigerant heat exchanger that exchanges heat between the outside air (OA) and the refrigerant is taken as an example.

A fan (43a) is installed near the heat radiation condenser (43) for supplying outside air (OA), which is a heat radiation fluid, to the heat radiation condenser (43). The fan (43a) operates when the heat radiation condenser (43) needs to release heat from the refrigerant.

－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 a connection pipe (40d), and to the refrigerant passage in the liquid cooling heat exchanger (46) through a connection pipe (40e). It is connected to the inlet side of the refrigerant passage. The expansion valve (45) reduces the pressure of the refrigerant circulating in the refrigerant circuit (40) by changing the degree of opening.

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

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

Thus, the drain pan (48a) is provided separately from the liquid tank (25) in the liquid dehumidification module (21). If the liquid tank (25) were mixed with condensed water, the concentration of the liquid absorbent in the liquid tank (25) would be lower than in the case where the liquid absorbent was not mixed. The required energy increases. However, since the drain pan (48a) and the liquid tank (25) are separately provided here, the possibility of occurrence of the above-described problems is reduced.

Additionally, a filter (49) is positioned between the refrigerant cooled dehumidification module (48) and the liquid dehumidification module (21). The filter (49) prevents the liquid absorbent from scattering from the liquid dehumidification module (21) side to the refrigerant cooling dehumidification module (48) side, and also prevents the condensation water from flowing out from the refrigerant cooling dehumidification module (48) side. Prevents scattering to the liquid dehumidification module (21) side. This filter (49) reliably reduces the possibility of mixing the liquid absorbent and the condensed water.

By the way, the condensed water is discharged to the outside through the drain pan (48a) and the drain discharge pipe (48b). Therefore, means for releasing heat of condensation when the refrigerant cooling dehumidification module (48) cools and dehumidifies the outside air (OA) is separately required. As means for releasing the heat of condensation, there is the above-described heat radiation condenser (43). The heat radiation condenser (43) radiates heat to a heat radiation fluid other than the indoor air (RA), as described above, in order to recover the heat of vaporization corresponding to the condensed water discharged to the outdoors. Therefore, an excessive rise in the condensation temperature (condensation pressure) of the refrigerant is suppressed, and a situation in which the humidity control device (10) stops operating due to an excessive rise in the condensation temperature (condensation pressure) being judged as abnormal can be avoided.

Thus, the liquid cooling heat exchanger (46) and the refrigerant cooled dehumidification module (48) are connected together with the liquid heating heat exchanger (44) into one refrigerant circuit (40).

-controller-
The controller (50) is a microcomputer comprising a memory, a CPU, etc., and controls various devices (compressor (42), pump (37), flow control valve (39), The fan (43a) and the expansion valve (45) are electrically connected. The controller (50) controls the operation of various connected devices by the CPU reading out and executing the programs stored in the memory.

Specifically, the controller (50) controls the operation of the fan (43a) based on the condensation temperature of the refrigerant, controls the opening of each valve (39, 45) based on the air conditioning load, and controls the operation of the pump (37). . For example, the controller (50) compares the condensing temperature of the refrigerant in the refrigerant circuit (40) with a predetermined value, and controls the operation of the fan (43a) according to the difference.

<Operation of humidity control device>
In the refrigerant circuit (40), the compressor (42) operates, the radiating condenser (43) and the liquid heating heat exchanger (44) function as refrigerant condensers, and the liquid cooling heat exchanger (46) and The refrigerant cooled dehumidification module (48) functions as a refrigerant evaporator.

The refrigerant compressed by the compressor (42) is condensed by radiating heat to the heat radiation fluid (outside air (OA)) in the heat radiation condenser (43), and then absorbed by the liquid heating heat exchanger (44). Heat is released to the agent to further condense. The refrigerant that has flowed out of the liquid heating heat exchanger (44) is depressurized 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. The refrigerant then flows into the refrigerant-cooled dehumidification 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. After passing through the refrigerant cooling dehumidification module (48), the refrigerant is sucked into the compressor (42).

In the absorbent circuit (15), the pump (37) operates and the flow control valve (39) is adjusted to a predetermined degree of opening. In the liquid dehumidification module (21), the liquid absorbent is dripped from the dehumidification side liquid supply section (22) to the dehumidification side gas-liquid contact section (23). The air to be treated (outside air (OA)) that has been cooled and dehumidified by the refrigerant-cooled dehumidification module (48) is supplied to the dehumidification-side gas-liquid contact portion (23), and the dripped liquid absorbent is removed from the air. It dehumidifies the air by absorbing moisture. The air after being dehumidified by both the refrigerant cooling dehumidification module (48) and the liquid dehumidification 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 the dehumidification side liquid receiving section (24) below the dehumidification side gas-liquid contact section (23) flow into After passing through the connecting pipe (15d), the liquid absorbent in the dehumidification side liquid receiver (24) flows into the liquid tank (25) and is stored therein. The liquid absorbent in the liquid tank (25) branches and flows through the connecting pipe (15e) to the liquid heating heat exchanger (44) side and the liquid cooling heat exchanger (46) side.

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) drips from the regeneration side liquid supply section (32) to the regeneration side gas-liquid contact section (33). Regeneration air (indoor air (RA)) is supplied to the regeneration side gas-liquid contact portion (33), and the dripped liquid absorbent releases moisture into the air. As a result, the liquid absorbent becomes highly concentrated and is regenerated. The regenerated liquid absorbent is temporarily received by the regeneration side liquid receiving portion (34) located below the regeneration side gas-liquid contact portion (33), and then sent to the dehumidification side liquid receiving portion through the connecting pipe (15c). (24) is stored. That is, the liquid absorbent on the dehumidifying side (24) contains the liquid absorbent whose concentration has been increased by the regeneration module (31) and the liquid absorbent whose concentration has been reduced by the liquid dehumidification module (21). mixed. Accordingly, the liquid absorbent (that is, mixed liquid) mixed in the dehumidification side liquid receiving portion (24) flows into and is stored in the liquid tank (25).

The air used to regenerate 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) drops again from the dehumidification side liquid supply section (22) to the dehumidification side gas-liquid contact section (23).

<Regarding the function of the dehumidification side liquid receiving portion as a promoting portion>
As already described, the liquid absorbent according to the first embodiment has a viscosity (approximately 3 to 20 times) higher than the viscosity of general liquid absorbents such as lithium chloride. Therefore, when the liquid absorbent used for dehumidification and the regenerated liquid absorbent are mixed, there is a risk of uneven mixing that cannot occur when using a general liquid absorbent. There is Mixing unevenness can be one factor that reduces the operating efficiency of the humidity control apparatus.

In contrast, in Embodiment 1, as described above, the liquid absorbent used for dehumidification and the regenerated liquid absorbent are mixed upstream of the liquid tank (25) in the flow direction of the liquid absorbent. dehumidification side liquid receiver (24) located on the side. That is, the liquid absorbent used for dehumidification and the regenerated liquid absorbent are temporarily flowed into the dehumidification side liquid receiving portion (24) and mixed, and the mixed liquid is flowed into the liquid tank (25) and stored. be.

As a result, the mixed liquid of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is in a more uniform state than when mixed in the liquid tank (25). Therefore, even if a highly viscous liquid absorbent is used, the mixed liquid with reduced mixing unevenness is supplied to each of the regeneration module (31) and the liquid dehumidification module (21). ) can avoid a decrease in operating efficiency.

<effect>
In Embodiment 1, the mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted in the dehumidification side liquid receiving section (24), which is a promotion section. As a result, the mixed liquid with reduced mixing unevenness is sent to each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, uneven mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent can be prevented from affecting the operating efficiency of the humidity control device (10).

In particular, since the promotion part is composed of the dehumidification side liquid receiving part (24) located upstream in the direction of inflow of the liquid absorbent into the liquid tank (25), the mixed liquid in which uneven mixing is suppressed It flows into the tank (25) and is stored.

In particular, the dehumidification-side liquid receiver (24), which is a promotion section, is a container provided separately from the liquid tank (25). As a result, the mixed liquid stored in the liquid tank (25) has reduced density unevenness and temperature unevenness due to uneven mixing.

<Modification of Embodiment 1>
FIG. 2 shows a humidity control device (10) according to a modification of the first embodiment. In FIG. 2, in the liquid dehumidification module (21) of FIG. 1, a mixing vessel (26) is provided between the dehumidifying side liquid receiver (24) and the liquid tank (25). In addition, in FIG. 2, the configuration other than the vicinity of the mixing container (26) is the same as in FIG. 1, so the same reference numerals as in FIG.

The mixing vessel (26) is connected to the regeneration side liquid receiver (34) by a connection pipe (15c), and is connected to the dehumidification side liquid receiver (24) by a connection pipe (15g). The liquid absorbent used for dehumidification and the regenerated liquid absorbent flow into the mixing container (26) through the connecting pipes (15c, 15g). In the mixing container (26), these liquid absorbents that have flowed in are mixed. The mixed liquid absorbent (that is, mixed liquid) flows into the liquid tank (25) through the connecting pipe (15h).

Therefore, the mixing container (26) functions as an facilitating section that promotes mixing of the liquid absorbents that have flowed into each other.

The humidity control apparatus (10) according to this modification has the same effects as those of the first embodiment.

<<Embodiment 2>>
Embodiment 2 exemplifies a case where the liquid absorbent is mixed in a pipe instead of a container such as the dehumidification side liquid receiver (24).

FIG. 3 shows the configuration of the humidity control apparatus (10) according to Embodiment 2. As shown in FIG. In FIG. 3, the configuration of the refrigerant circuit (40) is the same as in FIG. 1, but the configuration of the absorbent circuit (15) is slightly different. In FIG. 3, the same symbols as in FIG. 1 are given to the configurations corresponding to those in FIG. Only the different parts of the configuration will be described below.

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

The absorbent circuit (15) comprises a liquid dehumidification module (21), a regeneration module (31), a pump (37), a flow control valve (39), a liquid heating heat exchanger (44) and a liquid cooling heat exchanger (46). ) are connected by connecting pipes (15a, 15b, 16, 15e, 15f). The regeneration module (31), the liquid tank (25), the pump (37), the flow control valve (39), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46) are the regeneration units according to the first embodiment. Similar to module (31), liquid bath (25), pump (37), flow control valve (39), liquid heating heat exchanger (44) and liquid cooling heat exchanger (46).

The liquid dehumidification module (21) has a dehumidification side liquid supply section (22) and a dehumidification side gas-liquid contact section (23) similar to those of the first embodiment. Furthermore, the liquid dehumidifying module (21) has a dehumidifying side liquid receiving portion (24) positioned below the dehumidifying side gas-liquid contact portion (23). Unlike the dehumidifying side liquid receiving portion (24) according to the first aspect, only the liquid absorbent used for dehumidification in contact with the air to be treated (outside air (OA)) flows into the dehumidifying side gas-liquid contact portion (23). .

The dehumidification side liquid receiver (24), the regeneration side liquid receiver (34) and the liquid tank (25) are connected by a connecting pipe (16). The liquid absorbent received by each of the liquid receivers (24, 34) flows into the liquid tank (25) through the connecting pipe (16) and is stored therein.

Specifically, the connection pipe (16) includes a regeneration side pipe (16a) having one end connected to the regeneration side liquid receiver (34) and a dehumidification side pipe (16a) having one end connected to the dehumidification side liquid receiver (24). 16b) and a mixing pipe (16c) consisting of a corrugated pipe with one end connected to the liquid tank (25). The other ends of these pipes (16a, 16b, 16c) are connected to form the connection pipe (16).

In such a connection pipe (16), the liquid absorbent used for dehumidification of the air to be treated (outside air (OA)) in the liquid dehumidification module (21) flows through the dehumidification side pipe (16b), and the regeneration module The liquid absorbent regenerated in (31) flows through the regeneration side pipe (16a). These liquid absorbents are joined and mixed in the mixing pipe (16c). In particular, the mixing pipe (16c) consists of a corrugated pipe. Therefore, when the liquid absorbent used for dehumidification and the regenerated liquid absorbent are mixed at the connecting portion of the other ends of the pipes (16a, 16b, 16c), they are stirred while flowing in the mixing pipe (16c). be. The liquid absorbent (mixed liquid) sufficiently mixed in the mixing pipe (16c) flows into the liquid tank (25).

That is, in Embodiment 2, unlike Embodiment 1, the liquid absorbent is not mixed and stirred in the dehumidification side liquid receiving section (24), but the mixing pipe ( 16c).

<effect>
In Embodiment 2, the mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted by the mixing pipe (16c) serving as the promoting section. As a result, the mixed liquid with reduced mixing unevenness is sent to each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, uneven mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent can be prevented from affecting the operating efficiency of the humidity control device (10).

In particular, since the promotion section is composed of the mixing pipe (16c) located upstream in the direction of inflow of the liquid absorbent into the liquid tank (25), the mixed liquid with reduced mixing unevenness is supplied to the liquid tank (25) ) and stored.

In particular, the liquid absorbent used for dehumidification and the regenerated liquid absorbent are mixed while flowing through the mixing pipe (16c), which is the promotion section. As a result, there is no need to separately provide a promotion section composed of a mixing container as in the first embodiment, so that the humidity control apparatus (10) can be made inexpensive and compact.

<Modification 1 of Embodiment 2>
FIG. 4 schematically shows only the vicinity of the liquid tank (25) in the humidity control apparatus (10) according to Modification 1 of Embodiment 2. As shown in FIG. In FIG. 4, the mixing pipe (16c) is not composed of a corrugated pipe, but instead, a pump (51) (corresponding to a second pump) is connected in the middle of the mixing pipe (16c).

In the connection pipe (16) of FIG. 4, the liquid absorbent used for dehumidification flows through the dehumidifying side pipe (16b), and the regenerated liquid absorbent flows through the regeneration side pipe (16a). These liquid absorbents flow through the mixing pipe (16c) when mixed at the connection between the other ends of the pipes (16a, 16b, 16c). At this time, the pump (51) operates to cause the mixed liquid absorbent (mixed liquid) to flow through the mixing pipe (16c) while being stirred. The liquid absorbent (mixed liquid) sufficiently mixed in the mixing pipe (16c) flows into the liquid tank (25).

That is, in Modification 1 of Embodiment 2, the liquid absorbent is mixed and stirred on the mixing pipe (16c) to which the pump (51) corresponding to the promoting section is connected.

In Modification 1, the pump (51), which is the promotion unit, is provided separately from the pump (37) for sending the mixture to the modules (21, 31). there is

According to Modification 1, as in Embodiment 2, the mixed liquid with reduced mixing unevenness flows into and is stored in the liquid tank (25), and each module (21, 31) contains a mixed liquid. It is possible to send a mixed liquid with suppressed unevenness. In particular, the acceleration section is composed of a pump (51), and the liquid absorbent used for dehumidification and the regenerated liquid absorbent are agitated by the pump (51), thereby suppressing uneven mixing.

<Modification 2 of Embodiment 2>
FIG. 5 shows a humidity control device (10) according to Modification 2 of Embodiment 2. As shown in FIG. In FIG. 5, liquid receivers (24, 34) are not provided in each module (21, 31) of FIG. Instead, one liquid reservoir (25, 35) is provided in each module (21, 31).

Specifically, the liquid dehumidification module (21) has a dehumidification side liquid supply section (22), a dehumidification side gas-liquid contact section (23), and a dehumidification side liquid tank (25). The regeneration module (31) has a regeneration side liquid supply section (32), a regeneration side gas-liquid contact section (33), and a regeneration side liquid tank (35).

The dehumidification side liquid tank (25) is located below the dehumidification side gas-liquid contact portion (23), contacts the air to be treated (outside air (OA)), and receives and stores the liquid absorbent used for dehumidification. The regeneration side liquid tank (35) is located below the regeneration side gas-liquid contact portion (33) and receives and stores the regenerated liquid absorbent.

The regeneration side liquid tank (35) is connected to one end of the regeneration side pipe (16a) in the connection pipe (16), and the dehumidification side liquid tank (25) is connected to one end of the dehumidification side pipe (16b) in the connection pipe (16). It is connected to the. One end of the mixing pipe (16c) in the connection pipe (16) is connected to the first pump (37). The other ends of the pipes (16a, 16b, 16c) are connected to each other.

In such a connection pipe (16), the liquid absorbent used for dehumidification flows through the dehumidification side liquid tank (25) and the dehumidification side pipe (16b), and the regenerated liquid absorbent flows into the regeneration side liquid tank. (35) and flows through the regeneration side pipe (16a). These liquid absorbents are joined and mixed in the mixing pipe (16c). At this time, the pump (37) operates to cause the mixed liquid absorbent (mixed liquid) to flow through the pipes (16c, 15f) while being stirred. The liquid absorbent (mixed liquid) sufficiently mixed in the pipes (16c, 15f) is sent to each module (21, 31).

That is, in Modification 2 of Embodiment 2, each liquid tank (25, 35) contains liquid absorbent before being mixed (that is, liquid absorbent used for dehumidification or regenerated liquid absorbent). mixed. In Modified Example 2, the liquid absorbent is mixed and stirred on the pipe (16c) to which the pump (37) corresponding to the promotion section is connected. Unlike Modification 1 of Embodiment 2, only one pump (37) is provided on the humidity control apparatus (10), and functions not only as a promoting section but also as a pump for each module (21, 31). ) for the delivery of the mixed liquid.

According to Modified Example 2, the liquid mixture with less uneven mixing can be sent to each module (21, 31). In particular, the acceleration section is composed of a pump (37) (corresponding to a first pump), and the liquid absorbent used for dehumidification and the regenerated liquid absorbent are agitated by this pump (37) to cause uneven mixing. is suppressed.

<Modification 3 of Embodiment 2>
FIG. 6 shows a humidity control device (10) according to Modification 3 of Embodiment 2. As shown in FIG. In FIG. 6, one liquid tank (25, 35) is further provided in each module (21, 31) of FIG. One is provided.

Specifically, the liquid dehumidification module (21) includes a dehumidification side liquid supply section (22), a dehumidification side gas-liquid contact section (23), a dehumidification side liquid receiving section (24), and a dehumidification side liquid tank (25). ) and The regeneration module (31) has a regeneration-side liquid supply section (32), a regeneration-side gas-liquid contact section (33), a regeneration-side liquid receiving section (34), and a regeneration-side liquid tank (35).

The dehumidification side liquid receiver (24) is connected to one end of the dehumidification side pipe (16b) of the connection pipe (16), and the regeneration side liquid receiver (34) is connected to the regeneration side pipe (16a) of the connection pipe (16). connected to one end of the The mixing pipe (16c) in the connecting pipe (16) is formed of a corrugated pipe and connected to the other ends of the dehumidification side pipe (16b) and the regeneration side pipe (16a).

As a result, the liquid absorbent used for dehumidification in contact with the air to be treated (outside air (OA)) flows into the mixing pipe (16c) through the dehumidifying pipe (16b), Via (16a) the regenerated absorbent liquid enters. These liquid absorbents are mixed while flowing through the mixing pipe (16c). At that time, mixing is promoted because the mixing pipe (16c) is formed of a corrugated pipe.

Further, the mixing pipe (16c) is branched into two at the downstream end in the flow direction of the mixed liquid, and each end is connected to the dehumidification side liquid tank (25) and the regeneration side liquid tank (35). It is connected. Therefore, the liquid mixture sufficiently mixed in the mixing pipe (16c) flows into and is stored in each liquid tank (25, 35).

The dehumidification side liquid tank (25) is connected to the pump (37b), the liquid cooling heat exchanger (46) and the dehumidification side liquid supply section (22) in this order by pipes (15g, 15h, 15a). Therefore, the mixed liquid stored in the dehumidification side liquid tank (25) is sent to the dehumidification side liquid supply section (22) via the pump (37b) and the liquid cooling heat exchanger (46), and is processed. It is used to dehumidify the air (outside air (OA)).

The regeneration side liquid tank (35) is connected to the pump (37a), the liquid heating heat exchanger (44) and the regeneration side liquid supply section (32) in this order by pipes (15i, 15j, 15b). Therefore, the mixed liquid stored in the regeneration side liquid tank (35) is sent to the regeneration side liquid supply section (32) via the pump (37a) and the liquid heating heat exchanger (44) and is regenerated. be.

That is, in Modified Example 3 of Embodiment 2, the liquid absorbent is mixed and stirred in the mixing pipe (16c) that also serves as the promoting section. The humidity control apparatus (10) according to Modification 3 has the same effects as those of Embodiment 2 above.

<<Embodiment 3>>
In the third embodiment, the case where the mixing of the liquid absorbent is promoted by dispersing the liquid absorbent is exemplified.

FIG. 7 shows the configuration of a humidity control device (10) according to Embodiment 3. As shown in FIG. In FIG. 7, the configuration of the refrigerant circuit (40) is the same as in FIG. 1, but the configuration of the absorbent circuit (15) is slightly different. In FIG. 7, the same symbols as in FIG. 1 are given to the configurations corresponding to those in FIG. Only the different parts of the configuration will be described below.

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

The absorbent circuit (15) comprises a liquid dehumidification module (21), a regeneration module (31), a pump (37), a flow control valve (39), a liquid heating heat exchanger (44) and a liquid cooling heat exchanger (46). ) are connected by connecting pipes (15a, 15b, 15c, 15e, 15f). The regeneration module (31), the liquid tank (25), the pump (37), the flow control valve (39), the liquid heating heat exchanger (44), and the liquid cooling heat exchanger (46) are the regeneration units according to the first embodiment. Similar to module (31), liquid bath (25), pump (37), flow control valve (39), liquid heating heat exchanger (44) and liquid cooling heat exchanger (46).

The liquid dehumidification module (21) has a dehumidification side liquid supply section (22) and a dehumidification side gas-liquid contact section (23) similar to those of the first embodiment. The liquid dehumidification module (21) does not have a dehumidification side liquid receiver (24), but has a liquid tank (25) positioned below the dehumidification side gas-liquid contact section (23).

The liquid absorbent used for dehumidification in contact with the air to be treated (outside air (OA)) drips from the dehumidification side air-liquid contact portion (23) and flows into the liquid tank (25). Further, the liquid tank (25) is connected to the regeneration side liquid receiver (34) by a connecting pipe (15c).

The connection pipe (15c) is branched into three pipes (15ca, 15cb, 15cc) at the end connected to the liquid tank (25). In the vertical direction of the liquid tank (25), the pipe (15ca) is connected to the side part of the liquid tank (25) closest to the bottom of the liquid tank (25), and the pipe (15cb) is connected to the pipe (15ca). It is connected to the side part of the liquid tank (25) above the part. The pipe (15cc) is the side part of the liquid tank (25) that is above the connecting part of the pipe (15cb), that is, the liquid that is the highest among the connecting parts of the three pipes (15ca, 15cb, 15cc) It is connected to the side part of the tank (25).

As a result, the regenerated liquid absorbent flows into the liquid tank (25) from the regenerated liquid receiver (34) through the connecting pipe (15c). At this time, the liquid absorbent flows into the liquid tank (25) not through one inflow route, but through three pipes (15ca, 15cb, 15cc) branching into three inflow routes. Therefore, the liquid absorbent is dispersed in the liquid tank (25) and mixed with the liquid absorbent used for dehumidification.

That is, the regenerated liquid absorbent flows into the liquid tank (25) while being dispersed, thereby promoting mixing with the liquid absorbent used for dehumidification.

<effect>
In Embodiment 3, the mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted by the connecting pipe (15c), which is the promoting section. As a result, the mixed liquid with reduced mixing unevenness is sent to each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, uneven mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent can be prevented from affecting the operating efficiency of the humidity control device (10).

In particular, the connection pipe (15c) is branched into three pipes (15ca, 15cb, 15cc) at the connection end with the liquid tank (25), and the liquid tank (25) is dispersed while the regenerated liquid tank is dispersed. let it flow inside. The dispersion of the liquid absorbent promotes mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent, and the mixed liquid is stored in the liquid tank (25).

<Modification 1 of Embodiment 3>
FIG. 8 shows a humidity control device (10) according to Modification 1 of Embodiment 3. As shown in FIG. FIG. 8 differs from FIG. 7 only in the method of dispersing the regenerated liquid absorbent, and the rest of the configuration is the same as in FIG.

In FIG. 8, one end of the connection pipe (15c) is connected to the regeneration side liquid receiver (34) as in FIG. A dispersion portion (15cd) is formed at the end portion that is not connected to the dehumidification side liquid receiving portion (34). The dispersion part (15cd) is formed, for example, by forming a plurality of holes in the other end of the connecting pipe (15c), and the regenerated liquid absorbent is directed downward from the top of the liquid tank (25). Flow into the liquid tank (25) while being spread. This dispersal (15cd) serves as the facilitator.

Further, the liquid absorbent used for dehumidification drips into the liquid tank (25) from the dehumidification side gas-liquid contact portion (23) and flows into the liquid tank (25). As a result, the regenerated liquid absorbent is dispersed and mixed with the liquid absorbent used for dehumidification above the liquid tank (25). Therefore, the mixing of the liquid absorbent is promoted, and the sufficiently mixed liquid is stored in the liquid tank (25).

That is, in Modification 1 of Embodiment 3, the liquid absorbent mixing promotion operation is performed in the dispersing section (15cd) of the connection pipe (15c), which is the promotion section. The humidity control apparatus (10) according to Modification 1 has the same effects as those of Embodiment 3 above.

<Modification 2 of Embodiment 3>
FIG. 9 shows a humidity control apparatus (10) according to Modification 2 of Embodiment 3. As shown in FIG. FIG. 9 differs from FIG. 7 only in the method of dispersing the regenerated liquid absorbent, and the rest of the configuration is the same as in FIG.

In FIG. 9, one end of the connection pipe (15c) is connected to the regeneration side liquid receiving portion (34) as in FIG. The other end of the connection pipe (15c) is positioned above the liquid tank (25) and opens toward the liquid tank (25). In other words, the other end of the connection pipe (15c) is configured to drop the regenerated liquid absorbent from above the liquid tank (25) toward the liquid tank (25).

A distribution plate (27a) is provided below the other end of the connection pipe (15c), inside the liquid tank (25) and above the upper surface of the liquid absorbent in the liquid tank (25). The regenerated liquid absorbent dropped from the other end of the connecting pipe (15c) collides with the dispersion plate (27a). This distribution plate (27a) plays the role of a promotion section.

The regenerated liquid absorbent collides with the dispersion plate (27a) and is dispersed in all directions. Further, the liquid absorbent used for dehumidification is dripped into the liquid tank (25) from the dehumidification side gas-liquid contact portion (23). As a result, the regenerated liquid absorbent is dispersed and mixed with the liquid absorbent used for dehumidification above the liquid tank (25). Therefore, the mixing of the liquid absorbent is promoted, and the sufficiently mixed liquid is stored in the liquid tank (25).

That is, in Modification 2 of Embodiment 3, the operation of promoting mixing of the liquid absorbent is performed by the dispersing plate (27a), which is the promoting section. The humidity control device (10) according to Modification 2 has the same effect as that of Embodiment 3, and in addition, the humidity control device (10) can be made smaller because there is no need to provide a separate acceleration unit outside the liquid tank (25). There is an effect that the conversion can be achieved.

<Modification 3 of Embodiment 3>
FIG. 10 shows a humidity control device (10) according to Modification 3 of Embodiment 3. As shown in FIG. FIG. 10 differs from FIG. 7 in the method of dispersing the regenerated liquid absorbent. Note that the liquid dehumidification module (21) according to FIG. 23) and above the liquid tank (25). Other configurations are the same as those shown in FIG. 7 except for the configuration of the connecting pipe (15c).

In FIG. 10, one end of the connection pipe (15c) is connected to the regeneration side liquid receiver (34) as in FIG. The other end of the connection pipe (15c) is positioned above the liquid tank (25) and opens toward the liquid tank (25). In other words, the other end of the connection pipe (15c) is configured to drop the regenerated liquid absorbent from above the liquid tank (25) toward the liquid tank (25).

One end of a connection pipe (15d) is connected to the dehumidification side liquid receiver (24). The other end of the connection pipe (15d) is positioned above the liquid tank (25) and opens toward the liquid tank (25). In other words, the other end of the connection pipe (15d) is configured to drop the liquid absorbent used for dehumidification from above the liquid tank (25) toward the liquid tank (25).

In particular, in Modification 3, the liquid absorbent dripped from the openings at the other ends of the pipes (15c, 15d) collide with each other above the upper surface of the liquid absorbent in the liquid tank (25). The position of the opening at the other end of each pipe (15c, 15d) is adjusted. Each pipe (15c, 15d) adjusted in this way plays the role of a facilitator.

Collision between the liquid absorbent flowing out of the opening of the connecting pipe (15c) and the liquid absorbent flowing out of the opening of the connecting pipe (15d) accelerates the mixing of the liquid absorbent and the liquid tank (25). ) contains a well-mixed reservoir.

That is, in Modification 3 of Embodiment 3, the liquid absorbent mixing promotion operation is performed in the pipes (15c, 15d), which are the promotion units. The humidity control apparatus (10) according to Modification 3 has the same effects as those of Embodiment 3 above.

<Modification 4 of Embodiment 3>
FIG. 11 shows a humidity control device (10) according to Modification 4 of Embodiment 3. As shown in FIG. 11 differs from FIG. 7 only in the method of dispersing the regenerated liquid absorbent. Other configurations are the same as those shown in FIG. 7 except for the configuration of the connecting pipe (15c).

In FIG. 11, one end of the connecting pipe (15c) is connected to the regeneration side liquid receiver (34) as in FIG. The other end of the connection pipe (15c) is positioned above the liquid tank (25) and opens toward the liquid tank (25). In other words, the other end of the connection pipe (15c) is configured to drop the regenerated liquid absorbent from above the liquid tank (25) toward the liquid tank (25).

Below the other end of the connecting pipe (15c), inside the liquid tank (25) and above the upper surface of the liquid absorbent in the liquid tank (25), a punched plate-like member (27b ) is provided. The plate-like member (27b) is arranged so as to generally cover the upper portion of the liquid tank (25). In particular, the plate member (27b) is provided at a predetermined distance from the upper surface of the liquid absorbent in the liquid tank (25). The plate-like member (27b) serves as a promotion section.

Each liquid absorbent dripped from the other end of the connection pipe (15c) and the dehumidification side gas-liquid contact portion (23) passes through a plurality of through holes provided in the plate-like member (27b), and flows into the liquid tank. Flow into (25). The liquid absorbent that has passed through the through holes drips toward the bottom of the liquid tank (25) while being dispersed. That is, in Modification 4, not only the regenerated liquid absorbent but also the liquid absorbent used for dehumidification are dispersed. In the dripping process after passing through the plate member (27b), the regenerated liquid absorbent and the liquid absorbent used for dehumidification are mixed. Therefore, the mixing of the liquid absorbent is promoted, and the sufficiently mixed liquid is stored in the liquid tank (25).

That is, in Modification 4 of Embodiment 3, the operation of promoting mixing of the liquid absorbent is performed by the plate member (27b), which is the promoting portion. The humidity control apparatus (10) according to Modification 4 has the same effects as those of Embodiment 3, and in addition, the humidity control apparatus (10) can be made compact because there is no need to provide a separate promotion unit outside the liquid tank (25). There is an effect that the conversion can be achieved.

<<Embodiment 4>>
In Embodiment 4, the case where the mixing promotion of the liquid absorbent is performed inside the liquid tank (25) is exemplified. In Embodiment 4, if the liquid absorbent used for dehumidification and the regenerated liquid absorbent are each flowed into the liquid tank (25) in an unmixed state, the humidity can be controlled. The device (10) may be of any configuration. Therefore, the detailed configuration of the humidity control device (10) and the like is omitted here.

FIG. 12 shows only the liquid tank (25) of the humidity control apparatus (10) according to the fourth embodiment. As shown in FIG. 12, a promotion section (28) is provided in the liquid tank (25). Specifically, the promotion section (28) is composed of three partition plates (28a, 28b, 28c) that vertically partition the interior of the liquid tank (25). Each partition plate (28a, 28b, 28c) is positioned apart from each other by a predetermined distance. The partition plates (28a, 28b, 28c) have a contact portion and a non-contact portion with the inner wall of the liquid tank (25). In particular, the positions of the non-contact portions of the partition plates (28a, 28b, 28c) do not correspond in the vertical direction of the liquid tank (25). Therefore, the liquid absorbent flows along the partition plates (28a, 28b, 28c), and when it reaches the non-contact portion, it moves from the non-contact portion to the lower partition plate (28a, 28b, 28c). go.

In the course of the fluidization of the liquid absorbent in this way, mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted, and a well-mixed liquid absorbent is deposited at the bottom of the liquid tank (25) A liquid reservoir is stored.

<effect>
In Embodiment 4, the mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted in the promotion section (28). As a result, the mixed liquid with reduced mixing unevenness is sent to each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, uneven mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent can be prevented from affecting the operating efficiency of the humidity control device (10).

In particular, the promotion section (28) is provided inside the liquid tank (25). Therefore, since there is no need to provide a separate promotion section outside the liquid tank (25), the size of the humidity control apparatus (10) can be reduced.

<Modification of Embodiment 4>
FIG. 13 shows the liquid tank (25) of the humidity control apparatus (10) according to the modification of the fourth embodiment. 13 differs from that of FIG. 12 only in the configuration of the promoting portion provided inside the liquid tank (25), and the other configurations are the same as those of FIG.

As shown in FIG. 13, the promotion section is composed of one partition plate (29). The partition plate (29) is positioned above the upper surface of the liquid absorbent stored in the liquid tank (25) and covers the upper surface of the liquid absorbent. The partition plate (29) is formed with a through hole (29a) penetrating vertically.

When the liquid absorbent used for dehumidification and the regenerated liquid absorbent flow into the liquid tank (25), they flow along the partition plate (29) and pass through the through hole (29a) to the bottom of the liquid tank (25). moving to In the course of the fluidization of the liquid absorbent in this way, mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted, and a well-mixed liquid absorbent is deposited at the bottom of the liquid tank (25) A liquid reservoir is stored.

The humidity control apparatus (10) according to this modified example has the same effects as those of the fourth embodiment.

<<Embodiment 5>>
Embodiment 5 illustrates a case where the mixing of the liquid absorbent is promoted using a pump (37).

FIG. 14 shows the configuration of a humidity control apparatus (10) according to Embodiment 5. As shown in FIG. In FIG. 14, the circuit configuration around the pump (37) of the absorbent circuit (15) is slightly different from that in FIG. 7, but the other configurations are the same as in FIG. In FIG. 14, configurations corresponding to those in FIG. 7 are given the same reference numerals as in FIG. Only the different parts of the configuration will be described below.

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

In the absorbent circuit (15), the regeneration side liquid receiver (34) of the regeneration module (31) is connected to the liquid tank (25) through one connection pipe (15c), and the liquid tank (25) is connected to , is connected to the pump (37) by a connecting pipe (15e). The pump (37) is further connected to the connection pipe (15f) and sends the stored mixed liquid back to the liquid dehumidification module (21) and the regeneration module (31).

In particular, in Embodiment 5, the outlet of the pump (37) is connected to the liquid tank (25) by the connecting pipe (15k). As a result, part of the liquid mixture that has flowed out of the liquid tank (25) is returned to the liquid tank (25). Due to this operation, the liquid mixture in the liquid tank (25) circulates through the liquid tank (25), the connecting pipe (15e), the pump (37) and the connecting pipe (15k). Mixing with the liquid absorbent used for dehumidification is facilitated. That is, the pump (37) plays a role of a promotion section.

<effect>
In the fifth embodiment, the mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent is promoted by the pump (37), which is the promoting section. Specifically, the mixed liquid is circulated in the liquid tank (25) by the pump (37), and the liquid absorbent used for dehumidification and the regenerated liquid absorbent are mixed in the liquid tank (25). Promoted. As a result, the mixed liquid with reduced mixing unevenness is sent to each of the liquid dehumidification module (21) and the regeneration module (31). Therefore, uneven mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent can be prevented from affecting the operating efficiency of the humidity control device (10).

<Modification of Embodiment 5>
FIG. 15 shows the vicinity of the liquid tank (25) of the humidity control apparatus (10) according to the modification of the fifth embodiment. In FIG. 15, the connecting pipe (15k) connecting the outlet of the pump (37) and the liquid tank (25) is not provided in FIG. 14, but instead is provided with a pump ( 38) is provided separately from the pump (37). Other configurations are the same as those shown in FIG.

As shown in FIG. 15, the pump (38), which is a promotion section, is connected to the liquid tank (25) via connecting pipes (15m, 15n). When at least part of the mixed liquid stored in the liquid tank (25) flows out of the liquid tank (25) by the pump (38), the mixed liquid that has flowed out is re-liquidated through the connecting pipes (15m, 15n). It is returned to the bath (25). Due to this operation, the liquid mixture in the liquid tank (25) circulates through the liquid tank (25), the connecting pipe (15m), the pump (38) and the connecting pipe (15n). Mixing with the liquid absorbent used for dehumidification is facilitated.

The humidity control apparatus (10) according to this modification has the same effects as those of the fifth embodiment.

<<Other Embodiments>>
The acceleration unit is not limited to configurations other than those of Embodiments 1 to 5 as long as it promotes mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent.

For example, the promoting section may be means for relatively increasing the height difference between the regeneration side liquid receiving section (34) of the regeneration module (31) and the liquid tank (25). The regenerated liquid absorbent flows from the regeneration side liquid receiving portion (34) to the liquid tank (25) located below the liquid receiving portion (34). It rushes into the tank (25). This promotes mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent.

Further, the promoting portion is means for relatively increasing the height difference between the gas-liquid contact portion (23, 33) and the corresponding liquid receiving portion (24, 34) (or liquid tank (25, 35)). may The liquid absorbent flows down from the gas-liquid contact part (23, 33) to the liquid receiving part (24, 34) (or liquid tank (25, 35)) as water droplets. flows well. It is also possible to promote mixing by utilizing the falling water droplets. This means can be used, for example, in FIG. This means may be employed in both modules (21, 31) or may be employed in either one of the modules (21, 31).

Further, the acceleration section may be a control section that causes the humidity control device (10) to perform acceleration operation for promoting mixing of the liquid absorbent used for dehumidification and the regenerated liquid absorbent. The accelerated operation includes, for example, increasing the flow rate of the liquid absorbent circulating through the absorbent circuit (15).

The refrigerant cooling type dehumidification module (48) may cool and dehumidify the air to be treated. Therefore, the medium used when cooling and dehumidifying the air to be treated may be water instead of the refrigerant.

A plurality of liquid dehumidification modules (21) and regeneration modules (31) may be provided.

The heat radiation condenser (43) and the fan (43a) are not essential and may not be provided. The heat radiating fluid from which the heat radiating condenser (43) releases heat may be any fluid other than the indoor air (RA), and may be water.

In Embodiment 3 and its Modifications 1 to 4, the case where the dispersion target is only the regenerated liquid absorbent or both the regenerated liquid absorbent and the liquid absorbent used for dehumidification is exemplified. . However, the object to be dispersed may be only the liquid absorbent used for dehumidification.

As another example shown in FIGS. 12 and 13 shown in the fourth embodiment, a stirring member such as a propeller fan may be provided inside the liquid tank (25) as a promoting portion. In addition, the stirring member may stir the liquid mixture using a motor, a flow of the liquid absorbent (height difference), and a flow of air as the drive source.

The above-described Embodiments 1 to 5 and their modifications can be freely combined as appropriate.

Although embodiments and modifications have been described above, it will be appreciated that various changes in form and detail may be made without departing from the spirit and scope of the claims. Moreover, the embodiments and modifications described above may be appropriately combined or replaced as long as the functions of the object of the present disclosure are not impaired.

INDUSTRIAL APPLICABILITY As described above, the present disclosure is useful as a humidity control device capable of suppressing uneven mixing of liquid absorbents.

10 Humidity control equipment
15c,15d Connection pipe (promoting part)
16c Mixing pipe (facilitator)
21 Liquid dehumidification module (liquid dehumidification part)
24 Dehumidification side liquid receiving part (promoting part)
25 bath
26 Mixing vessel (facilitator)
27a dispersion plate (acceleration part)
28 Facilitator
29 Partition plate (facilitator)
31 Playback Module (playback section)
37, 38 Pump (1st pump, Accelerator)
51 Pump (Secondary pump, Accelerator)

Claims (8)

a liquid dehumidifying section (21) for dehumidifying the air to be treated by causing the liquid absorbent to absorb moisture in the air to be treated;
a regenerating section (31) for regenerating the liquid absorbent by releasing moisture of the liquid absorbent into regeneration air;
The liquid absorbent used for dehumidifying the air to be treated in the liquid dehumidifying section (21) and the liquid absorbent regenerated in the regenerating section (31) are mixed, a first pump (37) for sending to each of the liquid dehumidification section (21) and the regeneration section (31);
an acceleration section (24) for promoting mixing of the liquid absorbent used for dehumidifying the air to be treated in the liquid dehumidification section (21) and the liquid absorbent regenerated in the regeneration section (31); ,26,16c,51,15c,15d,27a,27b,28,29,37,38) and
A liquid tank (25) for storing the mixed liquid that has passed through the accelerating section (24, 26, 16c, 51, 15c, 15d, 27a, 27b, 28, 29, 37, 38) When
A humidity control device comprising: In claim 1,
The promotion part (24, 26, 16c, 51) is provided upstream of the liquid tank (25) in the direction in which the mixture flows into the liquid tank (25). humidity control device. In claim 2,
A humidity control apparatus, wherein the promoting section (24, 26) is constructed of a container separate from the liquid tank (25). In claim 1 or claim 2,
a dehumidifying side pipe (16b) through which the liquid absorbent used for dehumidifying the air to be treated in the liquid dehumidifying section (21) flows;
a regeneration side pipe (16a) through which the liquid absorbent regenerated in the regeneration section (31) flows;
further comprising a mixing pipe (16c) connected to the dehumidification side pipe (16b) and the regeneration side pipe (16a) through which the mixture flows,
The humidity control apparatus, wherein the mixing pipe (16c) also serves as the promotion section. In claim 1 or claim 2,
a dehumidifying side pipe (16b) through which the liquid absorbent used for dehumidifying the air to be treated in the liquid dehumidifying section (21) flows;
a regeneration side pipe (16a) through which the liquid absorbent regenerated in the regeneration section (31) flows;
a mixing pipe (16c) connected to the dehumidification side pipe (16b) and the regeneration side pipe (16a) through which the mixture flows;
a second pump (51) connected to the mixing pipe (16c) and shared with the first pump (37) or provided separately;
The humidity control apparatus, wherein the second pump (51) also serves as the promotion section. In claim 1,
The accelerating section (15c, 15d, 27a, 27b) includes the liquid absorbent used for dehumidifying the air to be treated in the liquid dehumidifying section (21) and the liquid absorbent regenerated in the regenerating section (31). and at least one of the liquid absorbents is dispersed and made to flow into the liquid tank (25). In claim 1 or claim 6,
A humidity control apparatus, wherein the accelerating section (27a, 27b, 28, 29) is provided in the liquid tank (25). In claim 1,
The acceleration unit (37, 38) is configured by pumps (37, 38) that return at least part of the liquid mixture that has flowed out of the liquid tank (25) back to the liquid tank (25). Characterized humidity control device.

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