WO2022259898A1

WO2022259898A1 - Humidity controlling device

Info

Publication number: WO2022259898A1
Application number: PCT/JP2022/021979
Authority: WO
Inventors: 伊織丸橋; 明広重田; 正宣広田; 大松井
Original assignee: パナソニックＩｐマネジメント株式会社
Priority date: 2021-06-08
Filing date: 2022-05-30
Publication date: 2022-12-15
Also published as: EP4354030A1; JP2022187736A; CN117501051A

Abstract

The present disclosure provides a humidity controlling device in which it is possible to achieve a quick startup and improve humidity control performance by carrying out moisture desorption from a humidity controlling means rapidly.　This humidity controlling device comprises: a housing 10; an air supply–side heat exchanging means 21 that is disposed within the housing 10 and that is provided to an air supply flow path 11 for supplying air to an air conditioning target space; an air discharge–side heat exchanging means 22 that is disposed within the housing 10 and that is provided to an air discharge flow path 12 for discharging air to the exterior; and a humidity controlling means 25 that is provided to the air supply flow path 11 and the air discharge flow path 12 and that forms a rotor shape that rotates in a prescribed direction by means of a humidity controlling means driving unit 26. The air discharge–side heat exchanging means 22 comprises an air discharge–side heat exchanging means entrance pipe 31 through which a cooling/heating medium flows into the heat exchanging means, and an air discharge–side heat exchanging means exit pipe 32 through which the cooling/heating medium flows out from the heat exchanging means. The air discharge–side heat exchanging means entrance pipe 31 is positioned below the air discharge–side heat exchanging means exit pipe 32.

Description

Humidity control device

The present disclosure relates to a humidity control device.

Patent Document 1 discloses a humidity control device. The humidity control apparatus of Patent Document 1 is provided with an air supply channel through which air flows into the room from the outside air and an exhaust channel through which air is discharged from the room into the outside air. After exchanging heat with the exhaust side, air is passed through the coil, and humidity is controlled by a disk-shaped single humidity control material that rotates in the same direction in the flow paths on the supply side and the exhaust side.

JP 2007-024377 A

The present disclosure provides a humidity control apparatus capable of quickly starting up and improving the performance of the amount of humidity control by quickly releasing moisture from the humidity control means.

This specification includes all the contents of Japanese Patent Application/Japanese Patent Application No. 2021-095894 filed on June 8, 2021.
A humidity control apparatus according to the present disclosure includes a housing, an air supply side heat exchange means provided in an air supply flow path that is disposed inside the housing and supplies air to an air-conditioned space, and Exhaust-side heat exchange means provided in an exhaust passage for exhausting air to the outside, and a rotor shape provided in the air supply passage and the exhaust passage and rotated in a predetermined direction by a humidity control means driving section. The exhaust-side heat exchange means includes an exhaust-side heat exchange means inlet pipe into which a cooling medium flows and an exhaust-side heat exchange means outlet pipe into which the cooling medium flows out. The exhaust-side heat exchanging means inlet pipe is positioned below the exhaust-side heat exchanging means outlet pipe.

In the humidity control apparatus according to the present disclosure, the air flowing through the exhaust channel passes through the exhaust-side heat exchange means inlet pipe with the highest temperature and is sent to the humidity control means. It can be heated by the hottest air at the moment it moves to Therefore, during the cooling operation in which the humidity needs to be discharged to the outside, the humidity control means can be quickly dehumidified and completely regenerated.

1 is a schematic cross-sectional view showing a humidity control device according to Embodiment 1. FIG. FIG. 2 is a configuration diagram showing an outline of exhaust-side heat exchange means and supply-air heat exchange means of the humidity control apparatus according to Embodiment 1. FIG. FIG. 3 is an explanatory diagram showing an example of paths of the cooling medium through the cooling medium pipes of the exhaust-side heat exchange means and the supply-side heat exchange means in the first embodiment. FIG. 4 is an explanatory diagram showing another example of paths of the cold medium through the cold medium pipes of the exhaust-side heat exchange means and the supply-side heat exchange means in the first embodiment.

(Knowledge, etc. on which this disclosure is based)
At the time when the inventors came up with the present disclosure, the humidity control device was equipped with an air supply channel for inflowing air from the outside air into the room and an exhaust channel for discharging the air from the room to the outside air. After heat is exchanged between the air supply side and the exhaust side by sensible heat exchange, it is a disk-shaped single humidity control material that rotates in the same direction in the flow path of the air supply side and the exhaust side by ventilating the coil. I was adjusting the humidity.

However, air is ventilated in the supply air channel and the exhaust channel, the sensible heat of both is exchanged through the total heat exchanger, and the supply air laminar flowed by the total heat exchanger is cooled by the cooling coil. The laminar flow of the exhaust heats the disk-shaped humidity control material via the heating coil, but the heating temperature is uniform, so the moisture release from the disk-shaped humidity control material is slow, and the amount of control is reduced. discovered and come to constitute the subject of the present disclosure in order to solve that problem.
Accordingly, the present disclosure provides a humidity control apparatus that can quickly start up and improve the performance of the amount of humidity control by performing the moisture release of the humidity control means quickly.

Hereinafter, embodiments will be described in detail with reference to the drawings. However, more detailed description than necessary may be omitted. For example, detailed descriptions of well-known matters or redundant descriptions of substantially the same configurations may be omitted. This is to avoid the following description from becoming more redundant than necessary and to facilitate understanding by those skilled in the art.
It should be noted that the accompanying drawings and the following description are provided to allow those skilled in the art to fully understand the present disclosure and are not intended to limit the claimed subject matter thereby.

(Embodiment 1)
Embodiment 1 will be described below with reference to the drawings.
[1-1. Constitution]
[1-1-1. Configuration of humidity control device]
FIG. 1 is a schematic cross-sectional view of a humidity control device 1 according to Embodiment 1. FIG. In the following description, directions such as front and back, left and right, and up and down are used based on the humidity control apparatus 1 shown in FIG.

The humidity control device 1 has a substantially rectangular parallelepiped housing 10 . Inside the housing 10, there are air supply passages 11 through which air introduced from the outside and supplied into the room, which is the space to be air-conditioned, so-called supply air flows, and air introduced from the room and discharged to the outside, so-called , and an exhaust passage 12 through which the exhaust flows are provided.
An outside air supply port 13 is provided at the upstream end of the air supply passage 11 . An indoor air supply port 14 is provided at the downstream end of the air supply channel 11 .
An indoor air circulation port 15 is provided at the upstream end of the exhaust flow path 12 . An outside air exhaust port 16 is provided at the downstream end of the exhaust passage 12 .

An air supply fan 17 is arranged in the air supply flow path 11 as a conveying means for supplying air. By operating the air supply fan 17, the air flows through the air supply passage 11 and is supplied to the room.
An exhaust fan 18 is arranged in the exhaust flow path 12 as a conveying means for exhaust. By operating the exhaust fan 18, the air flows through the exhaust flow path 12 and is discharged from the room.

A total heat exchanger 20 as a total heat exchange means is arranged above the air supply channel 11 and the exhaust channel 12 .
The total heat exchanger 20 of the present embodiment is a so-called orthogonal type total heat exchanger 20, and the air supply channel 11 and the exhaust channel 12 are orthogonal to each other. The total heat exchanger 20 is composed of, for example, a porous base material containing a hydrophilic resin or a flame-retardant agent, and rectangular plate-like base materials with linear flow paths are alternately laminated while changing the direction. By doing so, the total heat exchanger 20 in the shape of a quadrangular prism in which the air supply channel 11 and the exhaust channel 12 are perpendicular to each other is constructed.
The total heat exchanger 20 of the present embodiment has heat conductivity and moisture permeability. ) is configured to enable heat exchange of total heat.

In the air supply passage 11 , an air supply side heat exchange means 21 is arranged downstream of the total heat exchanger 20 . The air-supply side heat exchange means 21 heats, cools, etc. the air flowing through the air-supply flow path 11 .
An exhaust-side heat exchange means 22 is arranged downstream of the total heat exchanger 20 in the exhaust passage 12 . The exhaust-side heat exchange means 22 heats, cools, etc. the air flowing through the exhaust passage 12 .

The air supply side heat exchange means 21 and the exhaust side heat exchange means 22 are so-called fin-and-tube heat exchangers. shown) and
The air supply-side heat exchange means 21 and the exhaust-side heat exchange means 22 are connected in series and connected to a cooling medium circuit outside the housing 10 . A cold medium flows through the air supply side heat exchange means 21 and the exhaust side heat exchange means 22 via the cold medium circuit. In the air supply side heat exchange means 21 and the exhaust side heat exchange means 22, heat is exchanged between the air passing through the inside thereof and the cooling medium to heat and cool the air.

The air supply side heat exchange means 21 can be switched between heating, cooling, and neither heating nor cooling. Further, the exhaust side heat exchange means 22 can be switched between heating and cooling of the supply air side heat exchange means 21, and neither heating nor cooling.

A humidity control unit 24 is arranged downstream of the air supply side heat exchange means 21 and the exhaust side heat exchange means 22 . The humidity control unit 24 has a humidity control means 25 and a humidity control means driving section 26 such as an electric motor for rotating the humidity control means 25 . The humidity control means 25 is a humidity control means 25 that absorbs moisture when the temperature is low and releases moisture when the temperature is high.
When the low-temperature air flows into the humidity control means 25, the moisture in the air is absorbed and the air is dehumidified. Further, when high-temperature air flows into the humidity control means 25, the moisture adsorbed by the humidity control means 25 is released into the air, and the air is humidified.

The humidity control means 25 rotates in a predetermined direction by driving the humidity control means driving section 26 . A rotor-shaped portion of the humidity control means 25 continuously moves between the air supply channel 11 and the exhaust channel 12 . The humidity control unit 25 dehumidifies the air flowing through one of the air supply channel 11 and the exhaust channel 12 while humidifying the air flowing through the other. The humidity control unit 24 controls the humidity of the air flowing through the air supply channel 11 downstream of the total heat exchanger 20 and the air flowing through the exhaust channel 12 downstream of the total heat exchanger 20 .
In the present embodiment, two humidity control means 25 are arranged side by side in the width direction of the air supply side heat exchange means 21 and the exhaust side heat exchange means 22 .
The rotation directions of the humidity control means 25 may be opposite to each other or may be the same.

A partition member 27 is provided inside the housing 10 to separate the upper portion and the lower portion of the total heat exchanger 20 .
The partition member 27 has a function of separating the supply air passage 11 flowing through the total heat exchanger 20 and the air supply side heat exchange means 21 and the exhaust passage 12 flowing through the total heat exchanger 20 and the exhaust side heat exchange means 22. I have.

[1-1-2. Configuration of heat exchange means]
Next, the configurations of the exhaust side heat exchange means 22 and the intake side heat exchange means 21 will be described in detail.
FIG. 2 is a configuration diagram showing an outline of the exhaust side heat exchange means 22 and the intake side heat exchange means 21. As shown in FIG.
As shown in FIG. 2, inside the exhaust-side heat exchange means 22, a cooling medium pipe 30 through which a cooling medium from an outdoor unit (not shown) flows is provided.
The cold medium pipes 30 of the exhaust side heat exchange means 22 are composed of a plurality of cold medium pipes 30 extending in the width direction of the exhaust side heat exchange means 22 (perpendicular to the paper surface of FIG. 3 or 4).
An exhaust-side heat exchange means inlet pipe 31 and an exhaust-side heat exchange means outlet pipe 32 are connected to the cooling medium pipe 30 .
In the present embodiment, the exhaust-side heat exchange means inlet pipe 31 is connected to the cold/heat medium pipe 30 positioned at the bottom of the exhaust-side heat exchange means 22 . In addition, the exhaust-side heat exchange means outlet pipe 32 is connected to the cold/heat medium pipe 30 positioned at the top of the exhaust-side heat exchange means 22 in the present embodiment.

Similarly, the cold medium pipes 30 of the air supply side heat exchange means 21 are composed of a plurality of cold medium pipes 30 extending in the width direction of the air supply side heat exchange means 21 (perpendicular to the paper surface of FIG. 3 or 4). It is
An air supply side heat exchange means inlet pipe 33 and an air supply side heat exchange means outlet pipe 34 are connected to the cooling medium pipe 30 .
In the present embodiment, the air supply side heat exchange means inlet pipe 33 is connected to the cold/heat medium pipe 30 positioned at the bottom of the air supply side heat exchange means 21 . In the present embodiment, the air supply side heat exchanging means outlet pipe 34 is connected to the cold/heat medium piping 30 positioned at the top of the air supply side heat exchanging means 21 .

3 and 4 are explanatory diagrams showing examples of paths of the cold medium through the cold medium piping 30 of the exhaust-side heat exchange means 22 and the supply-side heat exchange means 21. FIG.
As shown in FIG. 3, for example, the cold medium that has flowed into the cold medium pipe 30 from the exhaust-side heat exchange means inlet pipe 31 flows from the cold medium pipe 30 arranged on the lower surface side of the exhaust-side heat exchange means 22 to the upper surface side. A path is configured so that the coolant flows through the cooling/heat medium pipes 30 that are arranged, and then flows again to the cold/heat medium pipes 30 that are arranged on the lower surface side.
Then, the cold medium that has flowed through the cold medium pipe 30 flows out from the exhaust-side heat exchanging means outlet pipe 32 connected to the cold medium pipe 30 positioned at the top.
That is, the exhaust-side heat exchange means inlet pipe 31 is connected to the cooling medium pipe 30 located at the lowest position of the exhaust-side heat exchange means 22, so that the exhaust-side heat exchange means 22 is connected from below. It is configured so that the hottest cooling medium is introduced.

Further, as shown in FIG. 4, for example, the cold medium that has flowed into the cold medium pipe 30 from the exhaust side heat exchange means inlet pipe 31 is sequentially It flows to the upper cold medium pipe 30, then returns to the cold medium pipe 30 arranged at the bottom on the upper surface side of the exhaust side heat exchange means 22, and from the cold medium pipe 30 on the upper surface side of the exhaust side heat exchange means 22. A path is configured so that the refrigerant flows to the cooling/heating medium pipe 30 in the upper direction.
Then, the cold medium that has flowed through the cold medium pipe 30 flows out from the exhaust-side heat exchanging means outlet pipe 32 connected to the cold medium pipe 30 positioned at the top.
In this case as well, the exhaust-side heat exchange means inlet pipe 31 is connected to the cooling medium pipe 30 located at the lowest position of the exhaust-side heat exchange means 22, so that the exhaust-side heat exchange means 22 is , the hottest cooling medium is introduced from below.

The configuration of the cold medium pipes 30 of the exhaust side heat exchange means 22 is the same as that of the cold medium pipes 30 of the air supply side heat exchange means 21 .
That is, the exhaust-side heat exchange means inlet pipe 31 is connected to the cooling medium pipe 30 located at the lowest position of the exhaust-side heat exchange means 22, so that the exhaust-side heat exchange means 22 is connected from below. It is configured so that the hottest cooling medium is introduced.

[1-2. action]
The operation of the humidity control apparatus 1 configured as above will be described.
In the humidity control apparatus 1 of Embodiment 1, the air supply fan 17, the exhaust fan 18, and the humidity control means drive unit 26 are driven, and air (supply air) flows through the air supply channel 11, and the exhaust channel 12 Air (exhaust air) flows through and the humidity control means 25 rotates around the rotation shaft.

When the air flowing through the air supply passage 11 and the air exhaust passage 12 flows into the total heat exchanger 20, the air exchanges total heat with each other and flows out, and the air supply side heat exchange means 21 and the exhaust side heat exchange means on the downstream side thereof. At 22 one is cooled and the other is heated and flows into humidity control means 25 .
When the cooled and low-temperature air flows into the humidity control means 25, the air flows out of the humidity control means 25 in a dehumidified state.
On the other hand, when the air heated to a high temperature flows into the humidity control means 25, the air flows out of the humidity control means 25 in a humidified state.
The air that has been humidity-conditioned by the humidity conditioning means 25 is supplied and exhausted to the space to be air-conditioned or to the outside.

For example, during cooling operation, a low temperature cold medium flows through the cold medium piping 30 of the air supply side heat exchange means 21, and a high temperature cold medium flows through the cold medium piping 30 of the exhaust side heat exchange means 22. .
Air introduced from the outside and flowing through the air supply passage 11 is cooled by the air supply side heat exchange means 21, moisture is absorbed (dehumidified) by the humidity control means 25, and the air is supplied to the air-conditioned space.

After absorbing moisture from the air in the air supply channel 11 , the humidity control means 25 rotates in a predetermined direction and moves from the air supply channel 11 to the exhaust channel 12 .
On the other hand, the air introduced from the air-conditioned space and flowing through the exhaust passage 12 is heated by the exhaust-side heat exchange means 22 to heat the humidity control means 25 . The humidity control means 25 heated by the air flowing through the exhaust flow path 12 releases moisture to regenerate, and moves from the exhaust flow path 12 to the air supply flow path 11 again due to its rotation. Moisture released to the exhaust passage 12 by the humidity control means 25 is discharged to the outside.

The cooling medium flowing through the exhaust-side heat exchange means 22 has the highest temperature at the exhaust-side heat exchange means inlet pipe 31, and flows from the exhaust-side heat exchange means inlet pipe 31 to the exhaust-side heat exchange means outlet pipe 32. The air flowing through the passage 12 is heated and circulated.
In the exhaust-side heat exchange means 22 , the exhaust-side heat exchange means inlet pipe 31 is located below the exhaust-side heat exchange means outlet pipe 32 . , the air having the highest temperature that has passed through the exhaust-side heat exchange means inlet pipe 31 starts heating the humidity control means 25 the moment the humidity control means 25 moves from the air supply channel 11 to the exhaust channel 12 .
That is, the moment the humidity control means 25 moves from the air supply channel 11 to the exhaust channel 12 by rotating in a predetermined direction, the humidity control means 25 is exposed to the air having the highest temperature among the air flowing through the exhaust channel 12 . will be heated.
As a result, during the cooling operation in which the humidity needs to be discharged to the outside, the humidity control means 25 quickly releases the moisture and completely regenerates, so that the start-up is quick and the performance of the humidity control amount can be improved. can.

Further, when the humidity is changed from dehumidification to humidification in the air-conditioned space, the heating and cooling of the air supply side heat exchange means 21 and the exhaust side heat exchange means 22 are switched, and the cooling medium piping of the air supply side heat exchange means 21 is switched. A high-temperature cold medium flows through 30 , and a low-temperature cold medium flows through the cold medium piping 30 of the exhaust-side heat exchange means 22 .
The air introduced from the air-conditioned space and flowing through the exhaust passage 12 is cooled by the exhaust-side heat exchanging means 22, has moisture absorbed (dehumidified) by the humidity control means 25, and is discharged to the outside.
After absorbing moisture from the air in the exhaust flow path 12 , the humidity control means 25 rotates in a predetermined direction and moves from the exhaust flow path 12 to the air supply flow path 11 .

On the other hand, the air introduced from the outside and flowing through the air supply passage 11 is heated by the air supply side heat exchange means 21 to heat the humidity control means 25 .
The humidity control means 25 heated by the air flowing through the air supply channel 11 releases and regenerates moisture, and moves from the air supply channel 11 to the exhaust channel 12 by its rotation again. The moisture released into the air supply passage 11 by the humidity control means 25 is supplied to the air-conditioned space.

The cold medium flowing through the air supply side heat exchange means 21 has the highest temperature at the air supply side heat exchange means inlet pipe 33 and reaches from the air supply side heat exchange means inlet pipe 33 to the air supply side heat exchange means outlet pipe 34. heat is applied to the air flowing through the air supply passage 11 and circulated.
In the air supply side heat exchange means 21 , the air supply side heat exchange means inlet pipe 33 is located below the air supply side heat exchange means outlet pipe 34 , so that the air flowing through the air supply flow path 11 passes through the air supply side heat exchange means 21 . The air having the highest temperature when passing through the air supply side heat exchange means inlet pipe 33 starts heating the humidity control means 25 at the moment the humidity control means 25 moves from the exhaust flow path 12 to the air supply flow path 11. do.

That is, at the moment when the humidity control means 25 moves from the exhaust flow path 12 to the air supply flow path 11 by rotating in a predetermined direction, the humidity control means 25 is exposed to the air having the highest temperature among the air flowing through the air supply flow path 11 . will be heated.
As a result, even during the heating operation in which it is necessary to supply humidity to the room, the humidity control means 25 likewise releases moisture quickly and regenerates completely, so that the start-up is quick and the performance of the humidity control amount is improved. can be improved.

Further, as described above, when the low temperature cold medium flows into the exhaust side heat exchange means 22 from the exhaust side heat exchange means inlet pipe 31, the air supply side heat exchange means inlet pipe of the air supply side heat exchange means 21 A high-temperature cooling medium flows from 33 .
Therefore, the temperature difference between the exhaust side heat exchange means inlet pipe 31 and the air supply side heat exchange means inlet pipe 33 becomes extremely large. Due to this temperature difference, dew condensation may occur on the partition member 27 .

However, in the present embodiment, the exhaust-side heat exchange means inlet pipe 31 is provided at the lowest part of the exhaust-side heat exchange means 22, and the supply-side heat exchange means inlet pipe 33 is provided at the lowest part of the supply-side heat exchange means 21. located at the bottom.
Therefore, the space between the exhaust-side heat exchange means inlet pipe 31 and the air supply-side heat exchange means inlet pipe 33 can be secured to some extent. It is possible to suppress the influence of the temperature difference between

[1-3. effects, etc.]
As described above, in the present embodiment, the housing 10 and the air supply side heat exchange means 21 provided in the air supply passage 11 that is disposed inside the housing 10 and supplies air to the air-conditioned space , the exhaust side heat exchange means 22 provided in the exhaust passage 12 disposed inside the housing 10 and exhausting air to the outside, and the air supply passage 11 and the exhaust passage 12 provided in the humidity control means driving The exhaust-side heat exchange means 22 includes an exhaust-side heat exchange means inlet pipe 31 into which the cold medium flows and an exhaust air from which the cold medium flows out. and a side heat exchange means outlet pipe 32 , and the exhaust side heat exchange means inlet pipe 31 is positioned below the exhaust side heat exchange means outlet pipe 32 .

As a result, the air flowing through the exhaust channel 12 passes through the exhaust-side heat exchange means inlet pipe 31 having the highest temperature and is sent to the humidity control means 25, so that the humidity control means 25 moves from the air supply channel 11 to the exhaust channel. At the moment it moves to 12, it can be heated by the hottest air. Therefore, during the cooling operation in which it is necessary to discharge the humidity to the outside, the humidity control means 25 can be quickly dehumidified and completely regenerated. .

In the present embodiment, the air supply side heat exchange means 21 includes an air supply side heat exchange means inlet pipe 33 into which the cooling medium flows, an air supply side heat exchange means outlet pipe 34 into which the cold medium flows out, The air supply side heat exchange means inlet pipe 33 is positioned below the air supply side heat exchange means outlet pipe 34 .
As a result, the air flowing through the air supply channel 11 passes through the air supply side heat exchange means inlet pipe 33 having the highest temperature and is sent to the humidity control means 25, so that the air moves from the exhaust channel 12 to the air supply channel 11. It can be instantly heated by the hottest air. Therefore, during the heating operation in which it is necessary to supply humidity to the room, the humidity control means 25 can be quickly dehumidified and completely regenerated. can.

Further, in the present embodiment, the humidity control means 25 are composed of a plurality of units, and are individually rotatable in a predetermined direction by transmitting power from the humidity control means driving section 26 .
As a result, it is possible to improve the humidity control performance of the plurality of humidity control means 25 .

Further, in the present embodiment, the exhaust-side heat exchange means 22 includes a cooling medium pipe 30 through which a cooling medium flows in the width direction of the exhaust-side heat exchange means 22, and the exhaust-side heat exchange means inlet pipe 31 is provided on the exhaust side. Located at the bottom of the heat exchange means 22 , the exhaust side heat exchange means outlet pipe 32 is located at the top of the exhaust side heat exchange means 22 .
As a result, the air flowing through the exhaust flow path 12 is sent to the humidity control means 25 through the exhaust-side heat exchange means inlet pipe 31 located at the bottom of the exhaust-side heat exchange means 22 and having the highest temperature. The moistening means 25 can be heated by the hottest air. Therefore, during the cooling operation in which it is necessary to discharge the humidity to the outside, the humidity control means 25 can be quickly dehumidified and completely regenerated. .

Further, in the present embodiment, the air supply side heat exchange means 21 is provided with a cooling medium pipe 30 through which the cooling medium flows in the width direction of the air supply side heat exchange means 21, and the air supply side heat exchange means inlet pipe 33 is , and the air supply side heat exchange means outlet pipe 34 is positioned at the top of the air supply side heat exchange means 21 .
As a result, the air flowing through the air supply passage 11 is sent to the humidity control means 25 through the air supply side heat exchange means inlet pipe 33 located at the lowest part of the air supply side heat exchange means 21 and having the highest temperature. , the humidity control means 25 can be heated by the hottest air. Therefore, during the heating operation in which it is necessary to supply humidity to the room, the humidity control means 25 can be quickly dehumidified and completely regenerated. can.

As described above, Embodiment 1 has been described as an example of the technology disclosed in the present application. However, the technology in the present disclosure is not limited to this, and can also be applied to embodiments with modifications, replacements, additions, omissions, and the like.

The present disclosure can be suitably applied as a humidity control device capable of quickly dehumidifying and completely regenerating the humidity control means, quickly starting up, and improving the performance of the amount of humidity control.

1 humidity control device 10 housing 11 air supply channel 12 exhaust channel 13 outdoor air supply port 14 indoor air supply port 15 indoor air circulation port 16 outdoor air exhaust port 17 air supply fan 18 exhaust fan 20 total heat exchanger 21 air supply side Heat Exchange Means 22 Exhaust Side Heat Exchange Means 24 Humidity Conditioning Unit 25 Humidity Conditioning Means 26 Humidity Conditioning Means Driving Section 27 Partition Member 30 Cold Heat Medium Piping 31 Exhaust Side Heat Exchange Means Inlet Piping 32 Exhaust Side Heat Exchange Means Outlet Piping 33 Air Supply Side Heat exchange means inlet pipe 34 Air supply side heat exchange means outlet pipe

Claims

a housing;
an air-supply side heat exchange means disposed inside the housing and provided in an air supply passage for supplying air to an air-conditioned space;
Exhaust-side heat exchange means disposed inside the housing and provided in an exhaust flow path for exhausting air to the outside;
a humidity control device provided in the air supply flow path and the exhaust flow path and having a rotor shape that is rotated in a predetermined direction by a humidity control means drive unit,
The exhaust-side heat exchange means includes an exhaust-side heat exchange means inlet pipe into which a cold medium flows and an exhaust-side heat exchange means outlet pipe into which the cold medium flows out,
The humidity control apparatus according to claim 1, wherein the exhaust-side heat exchanging means inlet pipe is located below the exhaust-side heat exchanging means outlet pipe.
The air supply side heat exchange means includes an air supply side heat exchange means inlet pipe into which a cold medium flows and an air supply side heat exchange means outlet pipe into which the cold medium flows out,
2. The humidity control apparatus according to claim 1, wherein said air supply side heat exchange means inlet pipe is positioned below said air supply side heat exchange means outlet pipe.
3. The humidity control device according to claim 1, wherein the humidity control device is composed of a plurality of units, and can be individually rotated in a predetermined direction by transmitting power from the humidity control device drive unit. Wetting equipment.
The exhaust-side heat exchange means includes a cooling medium pipe through which a cooling medium flows in the width direction of the exhaust-side heat exchange means,
The exhaust-side heat exchange means inlet pipe is positioned at the bottom of the exhaust-side heat exchange means, and the exhaust-side heat exchange means outlet pipe is positioned at the top of the exhaust-side heat exchange means. The humidity control device according to any one of claims 1 to 3.
The air supply side heat exchange means includes a cooling medium pipe through which a cooling medium flows in the width direction of the air supply side heat exchange means,
The air supply side heat exchange means inlet pipe is located at the lowest part of the air supply side heat exchange means, and the air supply side heat exchange means outlet pipe is located at the top part of the air supply side heat exchange means. 5. The humidity control apparatus according to any one of claims 2 to 4, characterized by: