KR101630143B1 - Dehumidification device and dehumidification system - Google Patents

Abstract

The first and second adsorption heat exchangers (101, 102) are respectively installed in the first and second heat exchange rooms (S11, S12) and are switched to an evaporator and a condenser. The first adsorption block 301 is installed at a position downstream of the first adsorption heat exchanger 101 when the first adsorption heat exchanger 101 serves as an evaporator in the first heat exchange room S11, 2 adsorption block 302 is installed at a position downstream of the second adsorption heat exchanger 102 when the second adsorption heat exchanger 102 in the second heat exchange room S12 becomes an evaporator. With this configuration, it is possible to provide a dehumidifying device capable of improving the dehumidifying ability while suppressing an increase in power consumption.

Description

[0001] DEHUMIDIFICATION DEVICE AND DEHUMIDIFICATION SYSTEM [0002]

The present invention relates to a dehumidifying device and a dehumidifying system for dehumidifying air and supplying the dehumidified air to a dehumidifying space, and more particularly to a dehumidifying device having an adsorption heat exchanger carrying an adsorbent.

Background Art [0002] Conventionally, a dehumidifying device for dehumidifying air and supplying it to a humidity control space (for example, an indoor space) is known. For example, Patent Document 1 discloses a humidity control system having a refrigerant circuit having two adsorption heat exchangers and adjusting the humidity of air in an adsorption heat exchanger. The humidity control system alternately repeats the operations of the first adsorption heat exchanger serving as a condenser, the second adsorption heat exchanger serving as an evaporator, the first adsorption heat exchanger serving as an evaporator, and the second adsorption heat exchanger serving as a condenser. Specifically, the humidity control system supplies the dehumidified air in the adsorption heat exchanger functioning as an evaporator to the room, and at the same time, performs the dehumidification operation in which the humidified air is discharged to the outside from the adsorption heat exchanger functioning as a condenser.

Japanese Patent Application Laid-Open No. 2006-349294

However, in the dehumidifying device (humidity control device) as in Patent Document 1, it is conceivable to improve the dehumidifying ability by increasing the number of revolutions of the compressor of the refrigerant circuit. However, if the number of revolutions of the compressor of the refrigerant circuit is increased, the power consumption of the dehumidifying device is increased.

It is therefore an object of the present invention to provide a dehumidifying device capable of improving the dehumidifying ability while suppressing an increase in power consumption.

The first adsorption heat exchanger (101) and the second adsorption heat exchanger (101) each having an adsorbent carried thereon serve as an evaporator to dehumidify air, and the second adsorption heat exchanger Is a condenser and regenerates the adsorbent; and a second operation in which the first adsorption heat exchanger (101) becomes a condenser and regenerates the adsorbent, and the second adsorption heat exchanger (102) A first and a second heat exchange chambers (S11, S12) in which the first and second adsorption heat exchangers (101, 102) are respectively installed, and a second heat exchange chamber The air having passed through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 serving as evaporators in the heat exchange rooms S11 and S12 is supplied to the humidity control space S0, So that the air for regenerating the adsorbent flows in the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101, And a second adsorption heat exchanger (101) configured to adsorb the adsorbent and make air come into contact with the adsorbent, wherein when the first adsorption heat exchanger (101) serves as an evaporator in the first heat exchange room (S11) A first adsorption block (301) disposed at a position downstream of the adsorption heat exchanger (101), and a second adsorption block (301) arranged to contact the adsorbent with the adsorbent to bring the adsorbent into contact with the adsorbent, wherein in the second heat exchange chamber And a second adsorption block (302) disposed at a position downstream of the second adsorption heat exchanger (102) when the adsorption heat exchanger (102) serves as an evaporator.

In the first invention, the air to be supplied to the humidity control space (S0) is allowed to flow through the heat exchange chambers (S11, S12) provided with the adsorption heat exchangers (101, 102) (101, 102) and the adsorbent of the adsorption block (301, 302), thereby dehumidifying the air. The air for regenerating the adsorbent is allowed to flow through the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101 serving as condensers so that the adsorption heat exchangers 102 and 101 and the adsorption block 302 , 301 can regenerate the adsorbent of the adsorption heat exchangers (102, 101) and the adsorption blocks (302, 301) by releasing moisture in the adsorbent. As described above, by adding the first and second adsorption blocks 301 and 302 to the first and second heat exchange rooms S11 and S12, the air dehumidification amount in the first and second heat exchange rooms S11 and S12 Can be increased.

In the first invention, in the case where the adsorption heat exchangers (101, 102) serve as evaporators in the first and second heat exchange rooms (S11, S12), the downstream side of the adsorption heat exchangers (101, 102) It is possible to supply dehumidified and cooled air to the adsorption blocks 301 and 302 by the adsorption heat exchangers 101 and 102 by disposing the adsorption blocks 301 and 302 at positions where the adsorption heat exchangers 101 and 102 are disposed. Accordingly, adsorption of moisture to the adsorbent of the adsorption blocks 301 and 302 can be promoted.

A second aspect of the present invention is the adsorption apparatus according to the first aspect of the present invention, wherein the switching mechanism (200) is configured such that the flow direction of air passing through each of the first and second adsorption heat exchangers (101, 102) 101, 102) function as an evaporator and the adsorption heat exchangers (101, 102) serve as a condenser, the flow direction of the air is switched.

In the second aspect of the present invention, in each of the first and second heat exchange chambers S11 and S12, the adsorption blocks 301 and 302 are arranged such that, when the adsorption heat exchangers (101 and 102) Is located on the downstream side of the adsorption heat exchangers (101, 102), and when the adsorption heat exchangers (101, 102) serve as a condenser, they are located on the upstream side of the adsorption heat exchangers (101, 102). That is, in each of the first and second heat exchange rooms S11 and S12, the air supplied to the heat exchange chambers S11 and S12 is subjected to adsorption heat exchange (adsorption heat exchange) when the adsorption heat exchangers 101 and 102 become evaporators After passing through the units 101 and 102 and then passing through the adsorption blocks 301 and 302 and the adsorption heat exchangers 101 and 102 serving as a condenser, after passing through the adsorption blocks 301 and 302, (101, 102).

A third aspect of the present invention is the adsorbing apparatus according to the first aspect of the present invention, wherein the switching mechanism (200) is arranged such that the flow direction of air passing through each of the first and second adsorption heat exchangers (101, 102) 101, 102) serve as an evaporator, and when the adsorption heat exchangers (101, 102) serve as a condenser, the flow of air is switched so as to be the same direction.

In the third aspect of the present invention, in each of the first and second heat exchange rooms (S11, S12), the adsorption blocks (301, 302) are provided in the case where the adsorption heat exchangers (101, 102) serve as evaporators and the adsorption heat exchangers 101 and 102 are located on the downstream side of the adsorption heat exchanger (101, 102). Therefore, in each of the first and second heat exchange rooms S11 and S12, when the adsorption heat exchangers 101 and 102 serve as evaporators, the air that has been dehumidified and cooled by the adsorption heat exchangers 101 and 102 The adsorbing heat can be supplied to the adsorption blocks 301 and 302 and the air heated by the adsorption heat exchangers 101 and 102 can be supplied to the adsorption blocks 301 and 302 when the adsorption heat exchangers 101 and 102 serve as a condenser .

The fourth invention is characterized in that, in any one of the first to third inventions, the first and second adsorption blocks (301, 302) are connected to the first and second adsorption heat exchangers (101, 102) And are spaced apart from each other.

In the fourth aspect of the present invention, the adsorption blocks (301, 302) are disposed in the first and second heat exchange rooms (S11, S12) at intervals from the adsorption heat exchangers (101, 102) It is possible to suppress the unevenness of the temperature distribution and the air drift (drift)

The fifth invention is characterized in that, in any one of the first to third inventions, the first and second adsorption blocks (301, 302) are connected to the first and second adsorption heat exchangers (101, 102) And is disposed so as to be in contact with the dehumidifier.

In the fifth invention, the adsorption blocks (301, 302) are arranged so as to be in contact with the adsorption heat exchangers (101, 102) in the first and second heat exchange rooms (S11, S12) , 102 and the adsorption block (301, 302) can be promoted. That is, when the adsorption heat exchangers 101 and 102 serve as evaporators, the adsorption blocks 301 and 302 can be cooled by the heat absorbing action of the refrigerant flowing through the adsorption heat exchangers 101 and 102, 101 and 102 function as condensers, the adsorption blocks 301 and 302 can be heated by the heat radiation action of the refrigerant flowing through the adsorption heat exchangers 101 and 102. [

The sixth invention is characterized in that it comprises a dehumidifying device (10) of the second invention and a heater (21) for heating air for regenerating the adsorbent, wherein the switching mechanism (200) Characterized in that the flow of air is switched so that air passing through the heater (21) flows into the heat exchange chambers (S12, S11) provided with the adsorption heat exchangers (102, 101) It is a dehumidification system.

In the sixth invention, air supplied to the heat exchange chambers S11 and S12 in the first and second heat exchange rooms S11 and S12 is supplied to the adsorption heat exchangers 101 and 102 as evaporators Passes through the adsorption blocks 301 and 302 after passing through the adsorption heat exchangers 101 and 102 and passes through the adsorption blocks 301 and 302 when the adsorption heat exchangers 101 and 102 serve as a condenser And then passes through the adsorption heat exchanger (101, 102). Therefore, the air passing through the heater 21 is allowed to flow through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 serving as the condensers, whereby the adsorption heat exchanger Air heated by the heater 21 can be supplied to the adsorption blocks 301 and 302 located on the upstream side of the adsorption units 101 and 102.

A seventh aspect of the present invention provides the sixth aspect of the present invention, wherein the heat exchange chambers (S11, S12) in which the adsorbent is supported and the adsorption heat exchangers (101, 102) which serve as evaporators in the first and second heat exchange rooms (S11, S12) And a regeneration section 72 for regenerating the adsorbent by bringing air that has passed through the heater 21 into contact with the adsorbent to regenerate the adsorbent, Wherein the air that has passed through the heat exchange chambers (S11, S12) provided with the adsorption heat exchangers (101, 102) as evaporators in the first and second heat exchange rooms (S11, S12) Is supplied to the humidity adjusting space (S0) through the adsorption part (71) of the rotor (70), and the switching mechanism (200) is provided in the first and second heat exchange rooms (S11, S12) (21) and the regeneration section (72) of the adsorption rotor (70) in the heat exchange chambers (S12, S11) provided with adsorption heat exchangers (102, 101) And the flow of air is switched so that air flows.

In the seventh invention, the air to be supplied to the humidity control space (S0) is dehumidified in the heat exchange chambers (S11, S12) provided with the adsorption heat exchangers (101, 102) (71). On the other hand, the air heated by the heater 21 passes through the regeneration section 72 of the adsorption rotor 70, and thereafter the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101 as condensers It passes. That is, the air that has passed through the regeneration section 72 of the adsorption rotor 70 can be used for adsorbent regeneration of the adsorption heat exchangers 102, 101 and the adsorption blocks 302, 301.

According to the first and second inventions, it is possible to increase the amount of dehumidification of air in the first and second heat exchange rooms (S11, S12), and to prevent the adsorption of the moisture to the adsorbent of the adsorption block (301, 302) So that the dehumidifying ability of the dehumidifying device 10 can be improved. Furthermore, since the number of revolutions of the compressor 103 of the refrigerant circuit 100 need not be increased in order to improve the dehumidifying capability of the dehumidifying device 10, the increase in the power consumption of the dehumidifying device 10 can be suppressed.

According to the third invention, since the air heated by the adsorption heat exchangers (101, 102) can be supplied to the adsorption blocks (301, 302) when the adsorption heat exchangers (101, 102) 301 and 302 can be promoted.

According to the fourth invention, it is possible to suppress unevenness of the temperature distribution and air drift in the adsorption blocks (301, 302), so that the adsorption ability and the regeneration ability of the adsorption blocks (301, 302) can be prevented from deteriorating.

According to the fifth invention, since the heat conduction between the adsorption heat exchanger (101, 102) and the adsorption block (301, 302) can be promoted, adsorption of moisture to the adsorbent in the adsorption block (301, 302) Can be promoted.

According to the sixth invention, the air heated by the heater (21) is supplied to the adsorption blocks (301, 302) located on the upstream side of the adsorption heat exchangers (101, 102) serving as the condensers in the heat exchange rooms (S11, S12) It is possible to promote the regeneration of the adsorbent in the adsorption blocks 301 and 302. [

According to the seventh invention, the dehumidifying ability of the dehumidifying system (1) can be improved by adding the adsorption rotor (70). Since the air that has passed through the regeneration section 72 of the adsorption rotor 70 can be used for adsorbent regeneration of the adsorption heat exchangers 102 and 101 and the adsorption blocks 302 and 301, Air can be effectively utilized.

1 is a piping system diagram for explaining a configuration example of a dehumidification system according to the first embodiment.
Fig. 2 is a schematic view for explaining the structure of the dehumidifier of the first embodiment and the flow of air in the first dehumidification operation. Fig.
3 is a schematic view for explaining the structure of the dehumidifier of the first embodiment and the flow of air in the second dehumidification operation.
4 is a piping system diagram for explaining Modification 1 of the dehumidification system of the first embodiment.
5 is a piping system diagram for explaining a second modification of the dehumidification system of the first embodiment.
6 is a piping system diagram for explaining Modification 3 of the dehumidification system of the first embodiment.
Fig. 7 is a piping system diagram for explaining a configuration example of the dehumidification system of the second embodiment. Fig.
8 is a schematic view for explaining the structure of the dehumidifier of the second embodiment and the flow of air in the first dehumidification operation.
9 is a schematic view for explaining the structure of the dehumidifier of the second embodiment and the flow of air in the second dehumidification operation.
10 is a piping system diagram for explaining a modified example of the dehumidification system of the second embodiment.
11 is a piping system diagram for explaining a configuration example of the dehumidification system of the third embodiment.
Fig. 12 is a piping system diagram for explaining a configuration example of the dehumidification system of the fourth embodiment. Fig.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding portions are denoted by the same reference numerals, and description thereof will not be repeated.

(First Embodiment)

Fig. 1 shows a configuration example of a dehumidifying system 1 according to the first embodiment. The dehumidifying system 1 dehumidifies air (in this example, outdoor air (OA)) and supplies it to the humidity control space S0. In this example, the humidity control space S0 is constituted by the indoor space S1. The interior space S1 is a space in which air having a low dew point temperature (for example, air having a dew point temperature of about -30 DEG C to -50 DEG C) is required to be supplied. For example, Dry clean room installed on line.

The dehumidifying system (1) includes a dehumidifying device (10) and a controller (20). The dehumidifying device 10 is provided with a supply passage P1 and a regeneration passage P2. The dehumidifying apparatus 10 includes first and second heat exchange chambers S11 and S12, a refrigerant circuit 100, a switching mechanism 200, and first and second adsorption blocks 301 and 302 .

<Supply air passage>

In the air supply passage P1, air (in this example, air for supplying the indoor space S1) to be supplied to the humidity control space S0 flows. In this example, the air supply passage P1 is configured to suck outdoor air OA from the outdoor space and supply the supply air SA to the indoor space S1. Specifically, the air supply passage P1 has a first air supply passage P11 to which the inlet end is connected to the outdoor space and a second air supply passage P12 to which the outlet end is connected to the indoor space S1 . In this example, the first air supply passage P11 of the air supply passage P1 is provided with a cooler 11, and the drain pan 12 is provided near the cooler 11. [

<Regeneration path>

In the regeneration passage P2, air for regenerating the adsorbent flows. In this example, the regeneration passage P2 is configured to suck indoor air RA from the indoor space S1 to discharge the exhaust air EA to the outdoor space. Specifically, the regeneration passage P2 includes a first regeneration passage P21 in which the inflow end is connected to the indoor space S1 and a second regeneration passage P21 in which the outflow end is connected to the outdoor space, And a regeneration passage P22. In this example, a part of the air in the indoor space S1 is discharged to the outdoor space as the discharge air EA without passing through the regeneration passage P2.

<Heat exchange room>

The first and second heat exchange chambers S11 and S12 are arranged such that one heat exchange chamber is provided in the air supply passage P1 as a part of the air supply passage P1 and the other heat exchange chamber is provided in the regeneration passage P2 And can be installed in the regeneration passage P2 as a part. Concretely, each of the first and second heat exchange rooms S11 and S12 is connected between the outflow end of the first air supply passage portion P11 and the inflow end of the second air supply passage portion P12, (Air to be supplied to the humidification space S0) is circulated in the first regeneration passage P21 and between the outlet end of the first regeneration passage P21 and the inflow end of the second regeneration passage P22 (Air for regenerating the adsorbent) is flowed through the regeneration passage P2. Hereinafter, the generic names of the first and second heat exchange rooms S11 and S12 are simply referred to as "heat exchange rooms S11 and S12 ".

<Cooler, drain pan>

The cooler 11 dehumidifies the outdoor air (OA) by cooling it. For example, the cooler 11 may be constituted by a heat exchanger (specifically, a pin-and-tube heat exchanger) functioning as an evaporator of a refrigerant circuit (not shown). The drain pan (12) recovers the condensed water in the cooler (11). For example, the drain pan 12 is constituted by a container whose upper surface is opened so as to receive condensed water in the cooler 11, and is disposed below the cooler 11. [ In this example, the cooler 11 is installed in the first air supply passage P11 of the air supply passage P1.

<Refrigerant Circuit>

The refrigerant circuit 100 circulates the refrigerant and performs a refrigeration cycle operation. The refrigerant circuit 100 includes first and second adsorption heat exchangers 101 and 102, a compressor 103, an expansion valve 104, (105).

&Quot; Adsorption heat exchanger &quot;

Each of the first and second adsorption heat exchangers (101, 102) is constituted by supporting an adsorbent on the surface of a heat exchanger (for example, a pin-and-tube heat exchanger of a cross pin type). The first and second adsorption heat exchangers (101, 102) are respectively installed in the first and second heat exchange rooms (S11, S12). As the adsorbent, an organic polymer material having a functional group (functional group) of zeolite, silica gel, activated carbon or hydrophilic (hydrophilic) may be used, or a material having a function of absorbing not only moisture but also water A so-called sorbing agent) may be used. Hereinafter, the generic terms of the first and second adsorption heat exchangers 101 and 102 are referred to simply as "adsorption heat exchangers 101 and 102 ".

"compressor"

The compressor (103) compresses and discharges the refrigerant. The compressor (103) is configured to be capable of changing the number of rotations (operation frequency) under the control of the controller (20). For example, the compressor 103 is constituted by a variable capacity compressor (a rotary type, a swing type, a scroll type compressor or the like) capable of adjusting the number of revolutions by an inverter circuit (not shown).

"Expansion valve"

The expansion valve 104 regulates the pressure of the refrigerant. For example, the expansion valve 104 is constituted by an electronic expansion valve capable of changing the opening degree in response to the control by the controller 20. [

"Four-way switching valve"

The four-way selector valve 105 has first to fourth ports, the first port is connected to the discharge side of the compressor 103, the second port is connected to the suction side of the compressor 103, The port is connected to the end of the second adsorption heat exchanger 102 and the fourth port is connected to the end of the first adsorption heat exchanger 101. [ The four-way selector valve 105 can be set to the first connection state (the state shown by the solid line in FIG. 1) and the second connected state (the state shown by the broken line in FIG. 1) in response to the control by the controller 20 .

"Refrigeration cycle operation by refrigerant circuit"

When the four-way selector valve 105 is in the first connection state, the refrigerant circuit 100 is configured such that the first adsorption heat exchanger 101 becomes the evaporator and dehumidifies the air, and the second adsorption heat exchanger 102 becomes the condenser A first refrigeration cycle operation (first operation) for humidifying the air (i.e., regenerating the adsorbent) is executed. On the other hand, when the four-way switching valve 105 is in the second connected state, the refrigerant circuit 100 is configured such that the second adsorption heat exchanger 102 serves as an evaporator to dehumidify the air and the first adsorption heat exchanger 101, And performs a second refrigeration cycle operation (second operation) for humidifying the air (i.e., regenerating the adsorbent). Thus, the refrigerant circuit 100 is configured to be capable of executing the first and second refrigeration cycle operations in response to the control by the controller 20. [ Specifically, the refrigerant circuit 100 is configured to perform the first and second refrigeration cycle operations alternately.

- first refrigeration cycle operation (first operation) -

When the four-way selector valve 105 is in the first connected state, the first port and the third port communicate with each other, and the second port and the fourth port communicate with each other. Accordingly, the refrigerant compressed by the compressor 103 flows into the second adsorption heat exchanger 102 through the four-way switching valve 105. In the second adsorption heat exchanger (102), the adsorbent is heated by the refrigerant, and a regeneration operation is performed in which moisture in the adsorbent is released into the air. The refrigerant that has been released and condensed in the second adsorption heat exchanger (102) is depressurized by the expansion valve (104), and then flows into the first adsorption heat exchanger (101). In the first adsorption heat exchanger (101), adsorption operation in which moisture in the air is adsorbed by the adsorbent is performed, and the adsorption heat generated at that time is given to the refrigerant. The refrigerant evaporated by heat absorption in the first adsorption heat exchanger (101) is sucked into the compressor (103) and compressed.

- second refrigeration cycle operation (second operation) -

When the four-way selector valve 105 is in the second connected state, the first port and the fourth port communicate with each other, and the second port and the third port communicate with each other. Accordingly, the refrigerant compressed by the compressor 103 flows into the first adsorption heat exchanger 101 through the four-way switching valve 105. In the first adsorption heat exchanger (101), the adsorbent is heated by the refrigerant, and a regeneration operation is performed in which moisture in the adsorbent is released into the air. The refrigerant that is condensed by radiating heat in the first adsorption heat exchanger (101) is decompressed by the expansion valve (104), and then flows into the second adsorption heat exchanger (102). In the second adsorption heat exchanger (102), adsorption operation in which moisture in the air is adsorbed by the adsorbent is performed, and the adsorption heat generated at that time is given to the refrigerant. The refrigerant absorbed and evaporated in the second adsorption heat exchanger (102) is sucked into the compressor (103) and compressed.

<Switching mechanism>

The switching mechanism 200 switches the connection state between the first and second heat exchange rooms S11 and S12 and the supply passage P1 and the regeneration passage P2 in response to the control by the controller 20, (A state shown by a solid line in Fig. 1) and a second passage state (a state shown by a broken line in Fig. 1).

The &quot; first passage state &quot;

When the connection state of the first and second heat exchange chambers S11 and S12 becomes the first passage state, the first heat exchange chamber S11 is connected between the first and second air supply passage portions P11 and P12, And the second heat exchange chamber S12 is connected to the regeneration passage P2 between the first and second regeneration passage portions P21 and P22.

The &quot; second passage condition &quot;

When the connection state of the first and second heat exchange chambers S11 and S12 becomes the second passage state, the first heat exchange chamber S11 is connected between the first and second regeneration passage portions P21 and P22, And the second heat exchange chamber S12 is installed between the first and second air supply passage portions P11 and P12 and is provided in the air supply passage P1.

&Quot; Connection switching operation of heat exchange chamber &

The switching mechanism 200 sets the connection state of the first and second heat exchange chambers S11 and S12 to the first passage state when the four-way switching valve 105 is in the first connection state, And sets the connection state of the first and second heat exchange chambers S11 and S12 to the second passage state when the valve 105 is in the second connection state. As described above, the switching mechanism 200 is provided with the heat exchange chamber provided with the adsorption heat exchanger serving as the evaporator among the first and second heat exchange rooms S11 and S12 as a part of the air supply passage P1, and the adsorption heat exchanger serving as the condenser The first and second heat exchange chambers S11 and S12 and the supply passage P1 and the regeneration passage P1 are interlocked with the switching of the refrigerating cycle operation of the refrigerant circuit 100 so that the installed heat exchange chambers are provided as part of the regeneration passage P2. And the connection state with the terminal P2. That is, the switching mechanism 200 is configured such that the air that has passed through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 as the evaporators in the first and second heat exchange rooms S11 and S12, S0 so that the air for regenerating the adsorbent flows in the heat exchange chambers S12, S11 provided with the adsorption heat exchangers 102, 101 as the condensers.

&Quot; Flow direction of air passing through adsorption heat exchanger &quot;

In this example, when the connection state of the first and second heat exchange rooms S11 and S12 is the first passage state (that is, when the first heat exchange chamber S11 is provided as a part of the air supply passage P1) The flow direction of the air passing through the first adsorption heat exchanger 101 in the first heat exchange chamber S11 and the second heat exchange chamber S11 in the case where the connection state of the first and second heat exchange rooms S11 and S12 is the second passage state Is provided as a part of the regeneration passage P2) in the same direction as the flow direction of the air passing through the first adsorption heat exchanger 101 (so-called parallel flow). The same applies to the flow direction of air passing through the second adsorption heat exchanger 102. Thus, the flow direction of the air passing through each of the first and second adsorption heat exchangers (101, 102) does not change even when the adsorption heat exchanger is switched from the evaporator to the condenser (or from the condenser to the evaporator). That is, the switching mechanism 200 is configured such that the flow direction of the air passing through each of the first and second adsorption heat exchangers (101, 102) is different from the case where the adsorption heat exchangers (101, 102) The flow of air is switched so that the heat exchangers 101 and 102 become the same direction when they serve as a condenser.

<Adsorption Block>

Each of the first and second adsorption blocks 301 and 302 is configured to support an adsorbent to bring air into contact with the adsorbent. For example, each of the first and second adsorption blocks 301 and 302 is formed by supporting an adsorbent on the surface of a structure (specifically, a structure having a honeycomb structure). The first and second adsorption blocks 301 and 302 are installed in the first and second heat exchange chambers S11 and S12, respectively. Here, in the following description, the generic names of the first and second adsorption blocks 301 and 302 are referred to simply as "adsorption blocks 301 and 302 ".

The first adsorption block 301 is disposed downstream of the first adsorption heat exchanger 101 (on the windward side) in the first heat exchange chamber S11 when the first adsorption heat exchanger 101 becomes an evaporator, (That is, the position where air dehumidified by the first adsorption heat exchanger 101 passes when the first heat exchange chamber S11 is provided as a part of the air supply passage P1). In other words, the first adsorption block 301 is configured such that the connection state of the first and second heat exchange chambers S11 and S12 in the first heat exchange chamber S11 is the first passage state (the state shown by the solid line in FIG. 1) The first adsorption heat exchanger 101 is located at a position downstream of the first adsorption heat exchanger 101.

Similarly, in the second adsorption heat exchanger 102, when the second adsorption heat exchanger 102 becomes an evaporator, the second adsorption block 302 is located downstream (downwind) side of the second adsorption heat exchanger 102 in the second heat exchange chamber S12, (That is, the position where air dehumidified by the second adsorption heat exchanger 102 passes when the second heat exchange chamber S12 is provided as a part of the air supply passage P1). In other words, the second adsorption block 302 is configured such that the connection state of the first and second heat exchange chambers S11 and S12 in the second heat exchange chamber S12 is the second passage state (the state shown by the broken line in FIG. 1) The second adsorption heat exchanger 102 is located at a position downstream of the second adsorption heat exchanger 102.

In this example, the flow direction of the air passing through each of the first and second adsorption heat exchangers 101 and 102 is the same as that in the case where the adsorption heat exchangers 101 and 102 are evaporators and the adsorption heat exchangers 101, 102 are in the same direction when they serve as a condenser. Therefore, when the connection state of the first and second heat exchange chambers S11 and S12 is the first passage state (the state shown by the solid line in Fig. 1), the position, which is the downstream side of the first adsorption heat exchanger 101, Is the same position as the downstream side of the first adsorption heat exchanger 101 when the connection state of the first and second heat exchange rooms S11 and S12 is the second passage state (the state shown by the broken line in Fig. 1) . Similarly, when the connection state of the first and second heat exchange rooms S11 and S12 is the second passage state (the state shown by the broken line in Fig. 1), the position downstream of the second adsorption heat exchanger 102 is (The state shown by the solid line in Fig. 1), and the second adsorption heat exchanger 102 is located at the same position as the downstream side of the second adsorption heat exchanger 102 when the connection state of the first and second heat exchange rooms S11 and S12 is the first passage state to be. That is, in each of the first and second heat exchange chambers S11 and S12, the adsorption blocks 301 and 302 are arranged such that the adsorption heat exchangers 101 and 102 serve as evaporators and the adsorption heat exchangers 101 and 102 serve as evaporators, Is located on the downstream side of the adsorption heat exchanger (101, 102).

<Controller>

The controller 20 controls the dehumidifier 10 based on the detection values of various sensors (for example, a temperature sensor and a humidity sensor). For example, the controller 20 is constituted by a CPU, a memory, and the like.

&Lt; Dehumidifying operation by dehumidifying device &gt;

Next, a dehumidifying operation of the dehumidifying device 10 of the first embodiment will be described with reference to Fig. The dehumidifying device 10 alternately repeats the first and second dehumidifying operations at predetermined time intervals (for example, every 10 minutes).

&Quot; First dehumidification action &

In the first dehumidifying operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way switching valve 105 becomes the first connected state (the state shown by the solid line in Fig. 1). Thus, the refrigerant circuit 100 performs the first refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes an evaporator and the second adsorption heat exchanger 102 becomes a condenser. The switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the first passage state (the state shown by the solid line in Fig. 1).

- Air flow in the air supply passage -

The air sucked into the air supply passage P1 (in this example, the outdoor air OA) is cooled and dehumidified by the cooler 11 and then supplied to the first heat exchange chamber S11. The air supplied to the first heat exchange room S11 passes through the first adsorption heat exchanger 101 functioning as an evaporator. At this time, the moisture in the air passing through the first adsorption heat exchanger (101) is adsorbed on the adsorbent of the first adsorption heat exchanger (101). The heat of adsorption generated during the adsorption is absorbed by the refrigerant flowing through the first adsorption heat exchanger (101). As described above, the air passing through the first adsorption heat exchanger 101 functioning as an evaporator is deprived of moisture by the adsorbent of the first adsorption heat exchanger 101, so that the humidity is lowered and the adsorption heat of the first adsorption heat exchanger 101 The refrigerant is cooled by the endothermic action of the refrigerant and the temperature is lowered. Next, air dehumidified and cooled by the first adsorption heat exchanger (101) passes through the first adsorption block (301). At this time, moisture in the air is adsorbed to the adsorbent of the first adsorption block 301. Accordingly, the air dehumidified by the first adsorption heat exchanger (101) is further dehumidified by the first adsorption block (301). The dehumidified air passing through the first adsorption heat exchanger 101 and the first adsorption block 301 is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air (in this example, room air RA) sucked into the regeneration passage P2 is supplied to the second heat exchange chamber S12. The air supplied to the second heat exchange chamber S12 passes through the second adsorption heat exchanger 102 functioning as a condenser. At this time, air passing through the second adsorption heat exchanger (102) is heated by the refrigerant flowing through the second adsorption heat exchanger (102). In addition, the moisture in the adsorbent of the second adsorption heat exchanger (102) is released into the air passing through the second adsorption heat exchanger (102). As a result, the adsorbent of the second adsorption heat exchanger 102 is regenerated. Thus, the air passing through the second adsorption heat exchanger 102 functioning as the condenser is supplied with moisture from the adsorbent of the second adsorption heat exchanger 102, so that the humidity is raised, and at the same time, the second adsorption heat exchanger 102, the temperature is also increased. Next, the air humidified and heated by the second adsorption heat exchanger (102) passes through the second adsorption block (302). At this time, the moisture of the adsorbent of the second adsorption block 302 is released to the air passing through the second adsorption block 302. As a result, the adsorbent of the second adsorption block 302 is regenerated. The air having passed through the second adsorption heat exchanger (102) and the second adsorption block (302) is discharged to the outdoor space as the exhaust air (EA).

&Quot; Second dehumidification action &

In the second dehumidifying operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way switching valve 105 becomes the second connected state (the state shown by the broken line in Fig. 1). Thus, the refrigerant circuit 100 performs the second refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes the condenser and the second adsorption heat exchanger 102 becomes the evaporator. Further, the switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the second passage state (the state shown by the broken line in Fig. 1).

- Air flow in the air supply passage -

The air sucked into the air supply passage P1 (in this example, the outdoor air OA) is cooled and dehumidified by the cooler 11 and then supplied to the second heat exchange chamber S12. The air supplied to the second heat exchange chamber S12 passes through the second adsorption heat exchanger 102 functioning as an evaporator. At this time, the air passing through the second adsorption heat exchanger 102 functioning as an evaporator is deprived of moisture by the adsorbent of the second adsorption heat exchanger 102, so that the humidity is lowered, and the adsorption heat of the second adsorption heat exchanger 102 The refrigerant is cooled by the endothermic action of the refrigerant and the temperature is lowered. Next, the air dehumidified and cooled by the second adsorption heat exchanger (102) passes through the second adsorption block (302). At this time, moisture in the air is adsorbed to the adsorbent of the second adsorption block 302. Accordingly, the air dehumidified by the second adsorption heat exchanger (102) is further dehumidified by the second adsorption block (302). The dehumidified air passing through the second adsorption heat exchanger 102 and the second adsorption block 302 is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air sucked into the regeneration passage P2 (room air RA in this example) is supplied to the first heat exchange chamber S11. The air supplied to the first heat exchange room S11 passes through the first adsorption heat exchanger 101 functioning as a condenser. At this time, the air passing through the first adsorption heat exchanger (101) functioning as a condenser is supplied with moisture from the adsorbent of the first adsorption heat exchanger (101), so that the humidity is raised and the adsorption heat of the first adsorption heat exchanger 101 is heated by the heat radiating action of the refrigerant flowing through the evaporator 101 and the temperature rises. As a result, the adsorbent of the first adsorption heat exchanger (101) is regenerated. Next, air humidified and heated by the first adsorption heat exchanger (101) passes through the first adsorption block (301). At this time, the moisture of the adsorbent of the first adsorption block 301 is released to the air passing through the first adsorption block 301. Thus, the adsorbent of the first adsorption block 301 is regenerated. The air having passed through the first adsorption heat exchanger (101) and the first adsorption block (301) is discharged to the outdoor space as the exhaust air (EA).

<Structure of dehumidifying device>

Next, the structure of the dehumidifying device 10 according to the first embodiment will be described with reference to Fig. Here, the terms "top", "bottom", "left", "right", "front", "rear", and "inside" used in the following description refer to the direction when the dehumidifying device 10 is viewed from the front side 2, the center view is a plan view of the dehumidifier 10, the right view is a right side view of the dehumidifier 10, and the left side view is a left side view of the dehumidifier 10.

The dehumidifier (10) has a casing (41) for accommodating components of the refrigerant circuit (100). The casing 41 is formed in a rectangular parallelepiped shape having a relatively flat and relatively low height and has a front panel 42, a rear panel 43, a left side panel 44 and a right side panel 45. [ In this example, the longitudinal direction of the casing 41 is the forward and backward direction.

The suction side suction port 51, the regeneration side suction port 52, the air supply mechanism 53, and the air outlet 54 are formed in the casing 41. The suction side suction port 51 is formed on the upper portion of the rear panel 43 and the regenerative suction port 52 is formed on the lower side portion of the rear panel 43. The air supply port 53 is formed in the vicinity of the end portion of the right side panel 45 on the side of the front panel 42 and the air outlet 54 is formed in the vicinity of the front panel 42 in the left side panel 44. [ As shown in Fig.

The first partition plate 46, the second partition plate 47, and the central partition plate 48 are provided in the inner space of the casing 41. These partition plates 46, 47 and 48 are provided standing on the bottom plate of the casing 41 and partition the inner space of the casing 41 from the bottom plate of the casing 41 through the top plate. The first and second partition plates 46 and 47 are disposed at predetermined intervals in the longitudinal direction of the casing 41 in a posture in parallel with the front panel 42 and the rear panel 43. The first partition plate 46 is disposed in the vicinity of the rear panel 43 and the second partition plate 47 is disposed in the vicinity of the front panel 42. [ The arrangement of the central partition plate 48 will be described later.

The space between the first partition plate 46 and the back panel 43 in the casing 41 is divided into two upper and lower spaces so that the lower space constitutes the first suction side internal passage S21, And the space on the upper side constitutes the first regeneration side internal passage S22. The first suction side internal passage S21 is connected to the outdoor space via a duct connected to the suction side suction port 51 (corresponding to the first air supply passage portion P11 in Fig. 1). The first regeneration side inner passage S22 is connected to the indoor space S1 via a duct (corresponding to the first regeneration passage P21 in Fig. 1) connected to the regeneration side intake port 52. [ The adsorption-side filter 63 is provided in the first adsorption-side internal passage S21 and the regeneration-side filter 64 is provided in the first regeneration-side internal passage S22.

The space between the first partition plate 46 and the second partition plate 47 is partitioned left and right by the central partition plate 48 in the casing 41 and the left space of the central partition plate 48 And the right space of the central partition plate 48 constitutes the second heat exchange chamber S12. The first adsorption heat exchanger 101 is accommodated in the first heat exchange chamber S11 and the second adsorption heat exchanger 102 is accommodated in the second heat exchange chamber S12. In the second heat exchange chamber S12, an expansion valve 104 (not shown) of the refrigerant circuit 100 is accommodated.

Each of the first and second adsorption heat exchangers (101, 102) is formed into a generally rectangular plate-like or flat rectangular parallelepiped shape, and two main surfaces (wide side surfaces) . The first adsorption heat exchanger 101 is installed so as to stand in the first heat exchange chamber S11 such that the two main surfaces are parallel to the first and second partition plates 46 and 47 . Similarly, the second adsorption heat exchanger 102 is installed so as to stand in the second heat exchange chamber S12 in such a posture that the two main surfaces are parallel to the first and second partition plates 46 and 47 do.

Each of the first and second adsorption blocks 301 and 302 is formed as a generally rectangular plate-like or flat rectangular parallelepiped, and two main surfaces (wide side surfaces) facing each other serve as a surface through which air passes. For example, each of the first and second suction blocks 301 and 302 is a honeycomb structure having a plurality of holes passing from one main surface to the other main surface. The first adsorption block 301 is installed so as to stand in the first heat exchange chamber S11 in such a posture that the two main surfaces are parallel to the first and second partition plates 46 and 47. Likewise, the second adsorption block 302 is installed so as to stand in the second heat exchange chamber S12 in such a manner that the two main surfaces are parallel to the first and second partition plates 46, 47 .

In this example, the first adsorption block 301 is disposed between the first adsorption heat exchanger 101 and the second partition plate 47 in the first heat exchange chamber S11, and the second adsorption block 301 302 are disposed between the second adsorption heat exchanger 102 and the second partition plate 47 in the second heat exchange chamber S12. The first adsorption block 301 is spaced apart from the first adsorption heat exchanger 101 in the front-rear direction and the second adsorption block 302 is disposed in the second adsorption heat exchanger 102 ).

In the casing 41, the space along the front surface of the second partition plate 47 is divided into upper and lower portions. Of the space defined by the upper and lower portions, the upper portion is the second adsorption-side inner passage S23 And the lower portion constitutes the second regenerator side internal passage S24.

The first to fourth dampers D1 to D4 are provided in the first partition plate 46 and the fifth to eighth dampers D5 to D8 are provided in the second partition plate 47. [ Each of the first to eighth dampers D1 to D8 is configured to be capable of switching between an open state and a closed state in response to a control by the controller 20. [ The first to eighth dampers D1 to D8 constitute a switching mechanism 200. [

The first damper D1 is mounted on the right side of the central partition plate 48 in the upper portion of the first partition plate 46 (the portion facing the first regenerative side passage S22) (D2) is mounted on the left side of the central partition plate (48) in the upper portion of the first partition plate (46). The third damper D3 is mounted on the right side of the central partition plate 48 in the lower portion of the first partition plate 46 (the portion facing the first suction side internal passage S21) The first partition plate D4 is mounted on the left side of the central partition plate 48 in the lower portion of the first partition plate 46. [

The fifth damper D5 is mounted on the right side of the central partition plate 48 in the upper portion of the second partition plate 47 (the portion facing the second suction side internal passage S23) D6 are mounted on the upper side of the second partition plate 47 on the left side of the central partition plate 48. [ The seventh damper D7 is mounted on the right side of the lower partition 22 (the portion facing the second regeneration side inner passage S24) of the second partition plate 47 to the right of the central partition plate 48 and the eighth damper D8 are mounted on the lower side of the second partition plate 47 on the left side of the central partition plate 48. [

The space between the second adsorption-side inner passage S23 and the second regeneration-side inner passage S24 and the front panel 42 in the casing 41 is partitioned to the left and right by the partition plate 49 The space on the right side of the partition plate 49 constitutes the air supply fan chamber S25 and the space on the left side of the partition plate 49 constitutes the air exhaust chamber S26. The air supply fan chamber S25 communicates with the indoor space S1 via a duct connected to the air supply mechanism 53 (corresponding to the second air supply passage P12 in Fig. 1). The exhaust fan chamber S26 communicates with the outdoor space through a duct (corresponding to the second regeneration passage P22 in Fig. 1) connected to the exhaust port 54. [ An air supply fan 61 is accommodated in the air supply fan chamber S25 and an air exhaust fan 62 is accommodated in the air exhaust chamber S26. The air supply fan 61 is connected to the air supply mechanism 53 and discharges the air sucked from the second partition plate 47 side to the air supply mechanism 53. The discharge port of the exhaust fan 62 is connected to the discharge port 54 and discharges the air sucked from the second partition plate 47 side to the discharge port 54. For example, each of the air supply fan 61 and the exhaust fan 62 is constituted by a centrifugal multi-purpose fan (so-called sirocco fan). The compressor 103 and the four-way switching valve 105 (not shown) of the refrigerant circuit 100 are accommodated in the air supply fan chamber S25.

&Quot; Air flow in the first dehumidifying operation &quot;

Next, referring to Fig. 2, the flow of air in the first dehumidifying operation by the dehumidifier 10 of the first embodiment will be described. In the first dehumidification operation, the first adsorption heat exchanger (101) serves as an evaporator and the second adsorption heat exchanger (102) serves as a condenser. The first, fourth, sixth, and seventh dampers D1, D4, D6, and D7 are in an open state and the second, third, fifth, and eighth dampers D2, D3 , D5, and D8 are closed. Thus, the connection state of the first and second heat exchange chambers S11 and S12 is set to the first passage state (the state shown by the solid line in FIG. 1), and the first heat exchange chamber S11 is connected to the air supply passage P1 And the second heat exchange chamber S12 is provided in the regeneration passage P2.

- Air flow in the air supply passage -

The air (OA in this example) supplied to the first suction side internal passage S21 via the suction side suction port 51 passes through the suction side filter 63 and then flows into the fourth damper D4 to be supplied to the first heat exchange chamber S11.

The air supplied to the first heat exchange chamber S11 passes through the first adsorption heat exchanger 101 and the first adsorption block 301 while passing through the first adsorption heat exchanger 101 and the first adsorption block 301 in order. 301) is dehumidified by taking moisture from the adsorbent.

The dehumidified air passing through the first adsorption heat exchanger 101 and the first adsorption block 301 passes through the sixth damper D6 and flows into the second adsorption-side inner passage S23, and the air in the air supply fan chamber S25 And the air supply mechanism 53 and is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air (RA in this example) supplied to the first regeneration side internal passage S22 via the regeneration side intake port 52 passes through the regeneration side filter 64 and then flows into the first damper D1 to be supplied to the second heat exchange chamber S12.

The air supplied to the second heat exchange chamber S12 flows through the second adsorption heat exchanger 102 and the second adsorption block 102 when passing through the second adsorption heat exchanger 102 and the second adsorption block 302 in order. Water is imparted from the adsorbent of the adsorbent 302. As a result, the adsorbent of the second adsorption heat exchanger 102 and the adsorbent of the second adsorption block 302 is regenerated.

The air having passed through the second adsorption heat exchanger 102 and the second adsorption block 302 flows through the seventh damper D7 into the second regeneration side internal passage S24 and flows into the exhaust gas compartment S26 and Passes through the exhaust port (54) and is discharged to the outdoor space.

&Quot; Air flow in the second dehumidifying operation &quot;

Next, the flow of air in the second dehumidifying operation by the dehumidifying device 10 of the first embodiment will be described with reference to Fig. In the second dehumidification operation, the first adsorption heat exchanger (101) serves as a condenser and the second adsorption heat exchanger (102) serves as an evaporator. 3, the second, third, fifth, and eighth dampers D2, D3, D5, and D8 are in an open state and the first, fourth, sixth, and seventh dampers D1, D4 , D6, D7 are closed. Thus, the connection state of the first and second heat exchange chambers S11 and S12 is set to the second passage state (the state shown by the broken line in Fig. 1), and the first heat exchange chamber S11 is connected to the regeneration passage P2 And the second heat exchange chamber S12 is installed in the air supply passage P1.

- Air flow in the air supply passage -

The air (OA in this example) supplied to the first suction side internal passage S21 via the suction side suction port 51 passes through the suction side filter 63 and then flows into the third damper D3 to be supplied to the second heat exchange chamber S12.

The air supplied to the second heat exchange chamber S12 flows through the second adsorption heat exchanger 102 and the second adsorption block 102 when passing through the second adsorption heat exchanger 102 and the second adsorption block 302 in order. 302) to be dehumidified.

The dehumidified air passing through the second adsorption heat exchanger 102 and the second adsorption block 302 passes through the fifth damper D5 and flows into the second adsorption-side inner passage S23. The air in the air supply fan chamber S25 And the air supply mechanism 53 and is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air (RA in this example) supplied to the first regeneration side internal passage S22 via the regeneration side intake port 52 passes through the regeneration side filter 64 and then flows into the second damper D2 to be supplied to the first heat exchange chamber S11.

The air supplied to the first heat exchange chamber S11 passes through the first adsorption heat exchanger 101 and the first adsorption block 301 while passing through the first adsorption heat exchanger 101 and the first adsorption block 301 in order. 301 are supplied with moisture from the adsorbent. Thus, the adsorbent of the first adsorption heat exchanger (101) and the first adsorption block (301) is regenerated.

The air having passed through the first adsorption heat exchanger 101 and the first adsorption block 301 passes through the eighth damper D8 and flows into the second regeneration side internal passage S24, Passes through the exhaust port (54) and is discharged to the outdoor space.

&Lt; Effects according to the first embodiment &gt;

In the dehumidifying device 10 of the first embodiment, by adding the first and second adsorption blocks 301 and 302 to the first and second heat exchange chambers S11 and S12, the first and second heat exchange chambers S11 , S12) can be increased.

In the case where the first heat exchange chamber S11 is provided in the air supply passage P1, the first adsorption block 301 is disposed at a position through which air dehumidified by the first adsorption heat exchanger 101 passes, 1 adsorption heat exchanger (101) to the first adsorption block (301). Accordingly, adsorption of moisture to the adsorbent in the first adsorption block 301 can be promoted. Similarly, when the second heat exchange chamber S12 is provided in the air supply passage P1, the dehumidified and cooled air can be supplied to the second adsorption block 302 by the second adsorption heat exchanger 102 , Adsorption of moisture to the adsorbent in the second adsorption block (302) can be promoted. That is, in the first and second heat exchange chambers S11 and S12, when the adsorption heat exchangers 101 and 102 serve as evaporators, the adsorption heat exchangers (101 and 102) 301 and 302 can be supplied to the adsorption blocks 301 and 302 by the adsorption heat exchangers 101 and 102 so that the adsorption blocks 301 and 302 can adsorb moisture to the adsorbent . &Lt; / RTI &gt;

As described above, the amount of dehumidification of air in the first and second heat exchange rooms S11 and S12 can be increased and the adsorption of moisture to the adsorbent in the adsorption blocks 301 and 302 can be promoted, The dehumidifying ability of the dehumidifying device 10 can be improved.

In addition, since the number of revolutions of the compressor 103 of the refrigerant circuit 100 need not be increased in order to improve the dehumidifying capability of the dehumidifying device 10, the increase in power consumption of the dehumidifying device 10 can be suppressed.

In the first embodiment, in each of the first and second heat exchange chambers S11 and S12, the adsorption blocks 301 and 302 are arranged so that adsorption heat exchangers (101 and 102) The adsorption heat exchangers 101 and 102 are located downstream of the adsorption heat exchangers 101 and 102 in any case where the units 101 and 102 serve as condensers. Therefore, in the first heat exchange chamber S11, when the first adsorption heat exchanger 101 serves as a condenser (that is, when the first heat exchange chamber S11 is provided in the regeneration passage P2) Air heated by the heat exchanger (101) can be supplied to the first adsorption block (301). Accordingly, regeneration of the adsorbent of the first adsorption block 301 can be promoted. Similarly, in the second heat exchange chamber S12, when the second adsorption heat exchanger 102 serves as a condenser (that is, when the second heat exchange chamber S12 is provided in the regeneration passage P2) Air heated by the adsorption heat exchanger (102) can be supplied to the second adsorption block (302). Accordingly, regeneration of the adsorbent of the second adsorption block 302 can be promoted. As described above, since the regeneration of the adsorbent in the adsorption blocks 301 and 302 can be promoted, the dehumidifying ability of the dehumidifying device 10 can be further improved.

By disposing the first adsorption block 301 at a distance from the first adsorption heat exchanger 101, it is possible to suppress the unevenness of the temperature distribution and the air drift in the first adsorption block 301. The same applies to the second adsorption block 302. As described above, since the unevenness of the temperature distribution in the first and second adsorption blocks 301 and 302 and the air drift can be suppressed, the adsorption ability and the regeneration ability of the first and second adsorption blocks 301 and 302 Can be suppressed.

(Modified Example 1 of the First Embodiment)

4, the regeneration passage P2 may be configured to suck the outdoor air OA and to discharge the exhaust air EA to the outdoor space. In this example, the inlet end of the first regeneration passage P21 is connected to the middle portion of the first air supply passage P11 (specifically, the downstream side of the cooler 11). The other configuration is the same as the configuration shown in Fig.

In the dehumidifying system 1 shown in Fig. 4, the indoor air RA is prevented from returning from the indoor space S1 toward the dehumidifier 10. Therefore, even when the indoor space (S1) is contaminated by chemicals or the like, the outdoor air (OA) cleaner than the indoor air (RA) can be dehumidified by the dehumidifier (10) and supplied to the indoor space The cleanliness of the space S1 can be maintained.

(Modified example 2 of the first embodiment)

As shown in Fig. 5, the air supply passage P1 may be configured to suck indoor air RA to supply the supply air SA to the indoor space S1. Further, the regeneration passage P2 may be configured to suck the outdoor air (OA) and discharge the exhaust air (EA) to the outdoor space. In this example, the inlet end of the first air supply passage P11 is connected to the indoor space S1, and the inlet end of the first regeneration passage P21 is connected to the outdoor space. In addition, the cooler 11 is formed in the first regeneration passage P21. The other configuration is the same as the configuration shown in Fig.

In the dehumidifying system 1 shown in Fig. 5, since the indoor air RA at the low dew point is dehumidified by the dehumidifier 10 and supplied to the indoor space S1, .

(Modification 3 of the first embodiment)

As shown in Fig. 6, the dehumidifying system 1 may include a dehumidifying device 30 for the preceding process, in addition to the dehumidifying device 10 and the controller 20 shown in Fig. In this example, the humidity control space S0 is constituted by an indoor space S1 and a chamber S2 provided in the indoor space S1. The indoor space S1 is a space required to supply air having a low dew point temperature (for example, air having a dew point temperature of about -30 占 폚), and the chamber S2 has a dew point temperature (For example, air having a dew point temperature of about -50 DEG C). In this example, the dehumidifying system 1 is provided with a front processing passage P3 and a rear processing passage P4. In this dehumidifying system 1, the dehumidified air (in this example, outdoor air (OA)) is supplied as the supply air SA0 to the indoor space S1 by the dehumidifying device 30 for the preceding process And the air dehumidified by the dehumidifying device 10 (room air RA in this example) is supplied to the chamber S2 as the supply air SA. The controller (20) controls the dehumidifying device (10) and the pre-processing dehumidifying device (30) based on the detection values of various sensors.

&Lt; Previous treatment channel &gt;

(In this example, air to be supplied to the indoor space S1) to be supplied to the humidity control space S0 flows in the front processing passage P3. In this example, the front processing passage P3 is configured to suck outdoor air OA from the outdoor space and supply the supply air SA0 to the indoor space S1. More specifically, the front processing passage P3 includes a first pre-processing passage P31 in which the inlet end is connected to the outdoor space, and a second pre-processing passage P31 in which the outlet end is connected to the indoor space S1 P32). In this example, the cooler 11 is installed in the first pre-treatment passage P31.

&Lt; Post processing channel &gt;

In the post-treatment process passage P4, air (in this example, air supplied from the regeneration passage P2) for regenerating the adsorbent flows. In this example, the after-treatment passage P4 is configured to suck air from the outflow end of the regeneration passage P2 to discharge the exhaust air EA to the outdoor space. Specifically, the postprocessing passage P4 includes a first post-treatment passage P41 in which the inlet end is connected to the outlet end of the regeneration passage P2, and a second post-treatment passage P41 in which the outlet end is connected to the outdoor space And a second after-treatment passage P42. In this example, a part of the air in the chamber S2 is discharged to the outdoor space as the discharge air EA without passing through the indoor space S1, and a part of the air in the indoor space S1 flows into the regeneration passage Is discharged to the outdoor space as the exhaust air (EA) without passing through the post-treatment passages (P2) and the post-treatment passages (P4).

<Supply air passage, regeneration passage>

In this example, the air supply passage P1 is configured to suck indoor air RA from the indoor space S1 and supply the supply air SA to the chamber S2. Concretely, the inlet end of the first air supply passage P11 is connected to the indoor space S1, and the outlet end of the second air supply passage P12 is connected to the chamber S2. The regeneration passage P2 is configured to suck indoor air RA from the indoor space S1 and to discharge the regeneration air (air for regenerating the adsorbent) to the post-treatment passage P4. Concretely, the inlet end of the first regeneration passage P21 is connected to the middle portion of the first air supply passage P11, and the outlet end of the second regeneration passage P22 is connected to the first end ) Processing passage P41.

<Dehumidifying device for previous treatment>

The dehumidifying device 30 for the previous treatment has the same configuration as the dehumidifying device 10. [ The structure of the dehumidifying device 30 for the preceding process is the same as that of the dehumidifying device 10 shown in Fig.

&Lt; Refrigerant circuit of dehumidifying device for previous treatment &gt;

The refrigerant circuit 100 of the dehumidifying device 30 for the preceding process is connected to the first adsorption heat exchanger (not shown) in response to the control by the controller 20, like the refrigerant circuit 100 of the dehumidifier 10 101) serves as an evaporator to dehumidify the air, a second adsorption heat exchanger (102) serves as a condenser to regenerate the adsorbent, and a second adsorption heat exchanger (102) serves as an evaporator to dehumidify the air, 1 adsorption heat exchanger 101 serves as a condenser and regenerates the adsorbent.

&Lt; Switching mechanism of the dehumidifying device for previous treatment &gt;

The switching mechanism 200 of the pre-processing dehumidifying device 30 is switched to the first and second heat exchange chambers (not shown) of the pre-processing dehumidifier 30 in response to the control by the controller 20 S11 and S12 and the front processing channel P3 and the rear processing channel P4 are switched between the third channel state (the state shown by the solid line in FIG. 6) and the fourth channel state (Indicated by broken lines in Fig.

&Quot; Third passage condition &quot;

When the connection state of the first and second heat exchange chambers S11 and S12 of the pre-processing dehumidifier 30 becomes the third passage state, the first heat exchange chamber S11 is connected to the first and second pre- And the second heat exchange chamber S12 is connected to the first and second post processing passages P41 and P42 by being connected between the passage portions P31 and P32 and provided in the front processing passage P3, And is installed in the post processing passage P4.

&Quot; Fourth passage condition &quot;

When the connection state of the first and second heat exchange chambers S11 and S12 of the pre-processing dehumidifying device 30 becomes the fourth passage state, the first heat exchange chamber S11 is closed by the first and second heat exchange chambers And the second heat exchange chamber S12 is connected to the first and second pretreatment passage portions P31 and P32 and is connected to the rear processing passage P4 and is connected between the rear processing passage portions P41 and P42, And is installed in the preceding process passage P3.

&Quot; Connection switching operation of heat exchange chamber &

The switching mechanism 200 of the front processing dehumidifier 30 is connected to the first and second heat exchange chambers S11 and S12 when the four- State is set to the third passage state and the connection state of the first and second heat exchange rooms S11 and S12 is set to the fourth passage state when the four-way selector valve 105 is in the second connection state. That is, the switching mechanism 200 of the pre-processing dehumidifying device 30, like the switching mechanism 200 of the dehumidifying device 10, is provided between the first and the second heat exchange rooms S11 and S12, The air having passed through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 serving as the adsorption heat exchangers 101 and 102 is supplied to the humidity control space S0 (in this example, the indoor space S1) (In this example, the first and second heat exchange chambers S11 and S12 of the dehumidifying device 10) for regenerating the adsorbent in the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101, (Air that has passed through the heat exchange chambers S11 and S12 provided with the units 101 and 102) flows.

&Quot; Flow direction of air passing through adsorption heat exchanger &quot;

In this example, in the case where the connection state of the first and second heat exchange chambers S11 and S12 in the pre-processing dehumidifier 30 is the third passage state (that is, the first heat exchange chamber The flow direction of the air passing through the first adsorption heat exchanger 101 in the first and second heat exchange chambers S11 and S12 is the same as the flow direction of the air passing through the first adsorption heat exchanger 101, The air passing through the first adsorption heat exchanger 101 in the case where the connection state is the fourth passage state (that is, when the first heat exchange chamber S11 is provided as a part of the after-treatment passage P4) The same direction as the flow direction. The same applies to the flow direction of air passing through the second adsorption heat exchanger 102. That is, the switching mechanism 200 of the pre-processing dehumidifier 30 is provided with the first adsorption heat exchanger 101 and the second adsorption heat exchanger 102, respectively, as in the switching mechanism 200 of the dehumidifier 10 The flow direction of the air passing through the adsorption heat exchangers 101 and 102 is switched so that the adsorption heat exchangers 101 and 102 become the evaporator and the adsorption heat exchangers 101 and 102 become the condenser .

&Lt; Dehumidifying operation by dehumidifying device for previous treatment &gt;

Next, the dehumidifying operation by the dehumidifying device 30 for the preceding process will be described with reference to Fig. The pre-processing dehumidifier 30 alternately repeats the third and fourth dehumidification operations at predetermined time intervals (for example, every 10 minutes).

&Quot; Third dehumidification action &

In the third dehumidifying operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way switching valve 105 becomes the first connected state (the state shown by the solid line in FIG. 6). Thus, the refrigerant circuit 100 performs the first refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes an evaporator and the second adsorption heat exchanger 102 becomes a condenser. In addition, the switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the third passage state (the state shown by the solid line in Fig. 6).

The air sucked into the preceding process passage P3 (in this example, the outdoor air OA) is cooled and dehumidified by the cooler 11, and then supplied to the first heat exchange chamber S11. The air supplied to the first heat exchange chamber S11 passes through the first adsorption heat exchanger 101 and the first adsorption block 301 while passing through the first adsorption heat exchanger 101 and the first adsorption block 301 in order. 301) is dehumidified by taking moisture from the adsorbent. The air dehumidified in the first heat exchange room S11 is supplied to the indoor space S1 as the supply air SA0.

The air (in this example, air supplied from the regeneration passage P2) sucked into the post-treatment process passage P4 is supplied to the second heat exchange chamber S12. The air supplied to the second heat exchange chamber S12 flows through the second adsorption heat exchanger 102 and the second adsorption block 102 when passing through the second adsorption heat exchanger 102 and the second adsorption block 302 in order. Water is imparted from the adsorbent of the adsorbent 302. As a result, the adsorbent of the second adsorption heat exchanger 102 and the adsorbent of the second adsorption block 302 is regenerated. The air having passed through the second heat exchange room S12 is discharged to the outdoor space as the discharge air (EA).

"Fourth dehumidification action"

In the fourth dehumidification operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way switching valve 105 becomes the second connected state (the state shown by the broken line in Fig. 6). Thus, the refrigerant circuit 100 performs the second refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes the condenser and the second adsorption heat exchanger 102 becomes the evaporator. Further, the switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the fourth passage state (the state shown by the broken line in Fig. 6).

The air sucked into the preceding process passage P3 (in this example, the outdoor air OA) is cooled and dehumidified by the cooler 11 and then supplied to the second heat exchange chamber S12. The air supplied to the second heat exchange chamber S12 flows through the second adsorption heat exchanger 102 and the second adsorption block 102 when passing through the second adsorption heat exchanger 102 and the second adsorption block 302 in order. 302) to be dehumidified. The air dehumidified in the second heat exchange room S12 is supplied to the indoor space S1 as the supply air SA0.

The air sucked into the post-treatment process passage P4 (in this example, the air supplied from the regeneration passage P2) is supplied to the first heat exchange chamber S11. The air supplied to the first heat exchange chamber S11 passes through the first adsorption heat exchanger 101 and the first adsorption block 301 while passing through the first adsorption heat exchanger 101 and the first adsorption block 301 in order. 301 are supplied with moisture from the adsorbent. Thus, the adsorbent of the first adsorption heat exchanger (101) and the first adsorption block (301) is regenerated. The air having passed through the first heat exchange room S11 is discharged to the outdoor space as the discharge air (EA).

&Lt; Effects of Modification 3 of First Embodiment &gt;

As described above, the dehumidifying device 30 dehumidifies the air (OA in this example) to be supplied to the indoor space S1 and supplies the dehumidified air to the indoor space And the dehumidifying device 10 dehumidifies the room air RA supplied from the indoor space S1 and supplies the dehumidified air to the chamber S2 as the supply air SA, The dew point temperature can be made lower than the dew point temperature of air in the indoor space S1. As described above, by supplying the low-dew point supply air SA intensively to the chamber S2, the power consumption required for the operation of the dehumidification system 1 Can be reduced.

(Second Embodiment)

7 shows a configuration example of the dehumidifying system 1 according to the second embodiment. The dehumidifying system 1 includes a dehumidifier 10, a controller 20, and a heater 21. Here, the structure of the dehumidifying device 10 of the second embodiment is different from that of the dehumidifying device 10 of the first embodiment (Fig. 2). Concretely, the flow direction of the air passing through the first and second adsorption heat exchangers (101, 102) and the arrangement of the first and second adsorption blocks (301, 302) are different from those of the first embodiment. The rest of the configuration is the same as that of the first embodiment.

<Heater>

The heater 21 is disposed on the upstream side (wind side) of the heat exchange chamber provided in the regeneration passage P2 and provided with the adsorption heat exchanger in the first and second heat exchange rooms S11 and S12 as a condenser do. That is, the heater 21 is configured to heat the air for regenerating the adsorbent. In this example, the heater 21 is disposed in the first regeneration passage P21. For example, the heater 21 may be constituted by a sensible heat exchanger that performs heat exchange between the air flowing through the first regeneration passage P21 and the air flowing through the second regeneration passage P22 And may be constituted by a heat exchanger (specifically, a fin-and-tube heat exchanger) functioning as a condenser of a refrigerant circuit (not shown) or the like.

<Refrigerant Circuit>

The first adsorption heat exchanger 101 serves as an evaporator to dehumidify the air and the second adsorption heat exchanger 102 is connected to the first adsorption heat exchanger 101. The refrigerant circuit 100, A second refrigeration cycle in which the second adsorption heat exchanger (102) becomes an evaporator to dehumidify air and the first adsorption heat exchanger (101) becomes a condenser and regenerates the adsorbent; And alternately perform operations.

<Switching mechanism>

In response to the control by the controller 20, the switching mechanism 200 switches the connection states of the first and second heat exchange rooms S11 and S12 to the first passage state (the state shown by the solid line in FIG. 7) And can be set to a two-passage state (a state shown by a broken line in Fig. 7). When the four-way selector valve 105 is in the first connection state (the state shown by the solid line in FIG. 7), the switching mechanism 200 switches the connection state of the first and second heat exchange rooms S11 and S12 7 and the connecting state of the first and second heat exchange rooms S11 and S12 is set to the second passage (the state shown by the broken line in Fig. 7) when the four-way switching valve 105 is in the second connecting state State. That is, the switching mechanism 200 is configured such that the air that has passed through the heat exchange chambers S11 and S12, in which the adsorption heat exchangers 101 and 102 that serve as evaporators, are installed in the first and second heat exchange rooms S11 and S12, (In this example, the air that has passed through the heater 21) for regenerating the adsorbent is supplied to the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101, which are supplied to the adsorption heat exchanger S0, , The air flow is switched.

In this example, when the connection state of the first and second heat exchange rooms S11 and S12 is the first passage state (that is, when the first heat exchange chamber S11 is provided as a part of the air supply passage P1) The flow direction of the air passing through the first adsorption heat exchanger 101 in the first heat exchange chamber S11 and the second heat exchange chamber S11 in the case where the connection state of the first and second heat exchange rooms S11 and S12 is the second passage state (That is, as a part of the regeneration passage P2) is opposite to the flow direction of the air passing through the first adsorption heat exchanger 101 (so-called counter flow). The same applies to the flow direction of air passing through the second adsorption heat exchanger 102. Thus, the flow direction of the air passing through each of the first and second adsorption heat exchangers (101, 102) reverses when the adsorption heat exchanger is switched from the evaporator to the condenser (or from the condenser to the evaporator) . That is, the switching mechanism 200 is configured such that the flow direction of the air passing through each of the first and second adsorption heat exchangers (101, 102) is different from the case where the adsorption heat exchangers (101, 102) And the flow of air is switched so that the heat exchangers (101, 102) are in opposite directions when they serve as condensers.

<Adsorption Block>

The first adsorption block 301 is disposed downstream (downstream side) of the first adsorption heat exchanger 101 when the first adsorption heat exchanger 101 becomes an evaporator in the first heat exchange room S11 (That is, the position where air dehumidified by the first adsorption heat exchanger 101 passes when the first heat exchange chamber S11 is provided as a part of the air supply passage P1).

The second adsorption block 302 is disposed downstream (downstream side) of the second adsorption heat exchanger 102 in the second heat exchange chamber S12 when the second adsorption heat exchanger 102 becomes an evaporator (That is, the position where air dehumidified by the second adsorption heat exchanger 102 passes when the second heat exchange chamber S12 is provided as a part of the air supply passage P1).

In this example, the flow direction of the air passing through each of the first and second adsorption heat exchangers (101, 102) is different from the case where the adsorption heat exchangers (101, 102) serve as evaporators and the adsorption heat exchanger 101, 102 are in the opposite direction when they serve as a condenser. Therefore, when the connection state of the first and second heat exchange chambers S11 and S12 is the first passage state (the state shown by the solid line in Fig. 7), the position, which is the downstream side of the first adsorption heat exchanger 101, When the connection state of the first and second heat exchange chambers S11 and S12 is the second passage state (the state shown by the broken line in FIG. 7), the position which is the upstream side of the first adsorption heat exchanger 101 And the position between the heater 21 and the first adsorption heat exchanger 101). Similarly, when the connection state of the first and second heat exchange rooms S11 and S12 is the second passage state (the state shown by the broken line in FIG. 7), the position downstream of the second adsorption heat exchanger 102 is (The position of the upstream side of the second adsorption heat exchanger 102 when the connection state of the first and second heat exchange rooms S11 and S12 is the first passage state (the state shown by the solid line in FIG. 7) (The position between the heater 21 and the second adsorption heat exchanger 102). That is, in each of the first and second heat exchange chambers S11 and S12, the adsorption blocks 301 and 302 are connected to the adsorption heat exchangers 101 and 102 when the adsorption heat exchangers 101 and 102 serve as evaporators, And the adsorption heat exchangers 101 and 102 are located on the upstream side of the adsorption heat exchangers 101 and 102 when they serve as a condenser.

&Lt; Dehumidifying operation by dehumidifying device &gt;

Next, the dehumidifying operation of the dehumidifying device 10 of the second embodiment will be described with reference to Fig. As in the dehumidifying device 10 of the first embodiment, the dehumidifying device 10 of the second embodiment alternately repeats the first and second dehumidifying operations at predetermined time intervals (for example, every 10 minutes) do.

&Quot; First dehumidification action &

In the first dehumidification operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way selector valve 105 becomes the first connected state (the state shown by the solid line in FIG. 7). Thus, the refrigerant circuit 100 performs the first refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes an evaporator and the second adsorption heat exchanger 102 becomes a condenser. Further, the switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the first passage state (the state shown by the solid line in Fig. 7).

- Air flow in the air supply passage -

The air sucked into the air supply passage P1 (in this example, the outdoor air OA) is cooled and dehumidified by the cooler 11 and then supplied to the first heat exchange chamber S11. The air supplied to the first heat exchange room S11 passes through the first adsorption heat exchanger 101 functioning as an evaporator. At this time, the air passing through the first adsorption heat exchanger (101) functioning as an evaporator is deprived of moisture by the adsorbent of the first adsorption heat exchanger (101) The temperature is also lowered. Next, air dehumidified and cooled by the first adsorption heat exchanger (101) passes through the first adsorption block (301). At this time, moisture in the air is adsorbed to the adsorbent of the first adsorption block 301. Accordingly, the air dehumidified by the first adsorption heat exchanger (101) is further dehumidified by the first adsorption block (301). The dehumidified air passing through the first adsorption heat exchanger 101 and the first adsorption block 301 is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air (in this example, room air RA) sucked into the regeneration passage P2 is supplied to the second heat exchange chamber S12 after being heated by the heater 21. [ The air supplied to the second heat exchange chamber (S12) passes through the second adsorption block (302). At this time, the moisture of the adsorbent of the second adsorption block 302 is released to the air passing through the second adsorption block 302. As a result, the adsorbent of the second adsorption block 302 is regenerated. Next, the air humidified by the second adsorption block 302 passes through the second adsorption heat exchanger 102 functioning as a condenser. The air passing through the second adsorption heat exchanger 102 functioning as a condenser is supplied with moisture from the adsorbent of the second adsorption heat exchanger 102 to increase the humidity and to adsorb the second adsorption heat exchanger 102 The temperature is also increased by the heat radiation action of the flowing refrigerant. As a result, the adsorbent of the second adsorption heat exchanger 102 is regenerated. The air having passed through the second adsorption heat exchanger (102) and the second adsorption block (302) is discharged to the outdoor space as the exhaust air (EA).

&Quot; Second dehumidification action &

In the second dehumidifying operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way switching valve 105 becomes the second connected state (the state shown by the broken line in Fig. 7). Thus, the refrigerant circuit 100 performs the second refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes the condenser and the second adsorption heat exchanger 102 becomes the evaporator. Further, the switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the second passage state (the state shown by the broken line in Fig. 7).

- Air flow in the air supply passage -

The air sucked into the air supply passage P1 (in this example, the outdoor air OA) is cooled and dehumidified by the cooler 11 and then supplied to the second heat exchange chamber S12. The air supplied to the second heat exchange chamber S12 passes through the second adsorption heat exchanger 102 functioning as an evaporator. At this time, the air passing through the second adsorption heat exchanger 102 functioning as an evaporator is deprived of moisture by the adsorbent of the second adsorption heat exchanger 102, so that the humidity is lowered, and the adsorption heat of the second adsorption heat exchanger 102 The refrigerant is cooled by the endothermic action of the refrigerant flowing therethrough and the temperature is lowered. Next, the air dehumidified and cooled by the second adsorption heat exchanger (102) passes through the second adsorption block (302). At this time, moisture in the air is adsorbed to the adsorbent of the second adsorption block 302. Accordingly, the air dehumidified by the second adsorption heat exchanger (102) is further dehumidified by the second adsorption block (302). The dehumidified air passing through the second adsorption heat exchanger 102 and the second adsorption block 302 is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air sucked into the regeneration passage P2 (room air RA in this example) is supplied to the first heat exchange chamber S11 after being heated by the heater 21. [ The air supplied to the first heat exchange chamber (S11) passes through the first adsorption block (301). At this time, the moisture of the adsorbent of the first adsorption block 301 is released to the air passing through the first adsorption block 301. Thus, the adsorbent of the first adsorption block 301 is regenerated. Next, the air humidified by the first adsorption block 301 passes through the first adsorption heat exchanger 101 functioning as a condenser. At this time, the air passing through the first adsorption heat exchanger (101) functioning as a condenser is supplied with moisture from the adsorbent of the first adsorption heat exchanger (101), so that the humidity is raised and the adsorption heat of the first adsorption heat exchanger 101 is heated by the heat radiating action of the refrigerant flowing through the evaporator 101 and the temperature rises. As a result, the adsorbent of the first adsorption heat exchanger (101) is regenerated. The air having passed through the first adsorption heat exchanger (101) and the first adsorption block (301) is discharged to the outdoor space as the exhaust air (EA).

<Structure of dehumidifying device>

Next, the structure of the dehumidifying device 10 according to the second embodiment will be described with reference to Fig. Here, the terms "top", "bottom", "left", "right", "front", "rear", and "inside" used in the following description refer to the direction when the dehumidifying device 10 is viewed from the front side . 8, the central view is a plan view of the dehumidifier 10, the top view is a rear view of the dehumidifier 10, and the bottom view is a front view of the dehumidifier 10.

The dehumidifier (10) has a casing (41) for accommodating components of the refrigerant circuit (100). The casing 41 is formed in a rectangular parallelepiped shape that is slightly flat and relatively low in height and has a front panel 42 and a rear panel 43 and a left panel 44 and a right panel 45. In this example, the longitudinal direction of the casing 41 is the left-right direction.

The suction side suction port 51, the regeneration side suction port 52, the air supply mechanism 53, and the air outlet 54 are formed in the casing 41. The suction side suction port 51 is formed at a position near the right side of the rear panel 43 and the regenerative suction port 52 is formed at a position near the left side of the rear panel 43. The air supply mechanism 53 is formed at a position near the left side of the front panel 42 and the air outlet 54 is formed at a position near the right side of the front panel 42.

The inner space of the casing 41 is provided with a first partition plate 46, a second partition plate 47 and a central partition plate 48. These partition plates 46, 47 and 48 are provided standing on the bottom plate of the casing 41 and divide the inner space of the casing 41 from the bottom plate of the casing 41 through the top plate. The first and second partition plates 46 and 47 are disposed at a predetermined interval in the left and right direction of the casing 41 in a posture in parallel with the left side panel 44 and the right side panel 45. The first partition plate 46 is disposed in the vicinity of the left side panel 44 and the second partition plate 47 is disposed in the vicinity of the right side panel 45. [ The left space of the first partition plate 46 becomes the left space S31 and the space between the first partition plate 46 and the second partition plate 47 becomes the center space S32, The right space of the partition plate 47 becomes the right space S33. Here, the arrangement of the central partition plate 48 will be described later.

The left space S31 is divided into a portion on the left side panel 44 side and a portion on the first partitioning plate 46 side. The space on the left side of the casing 41 in the left space S31 is divided into two spaces before and after the front side and the space on the front side constitutes the air supply fan chamber S25, S28). The space on the side of the first partition plate 46 in the left space S31 is divided into two upper and lower spaces, the upper space constitutes the second adsorption-side inner passage S23, And an internal passage S22.

The air supply fan chamber S25 communicates with the indoor space S1 via a duct connected to the air supply mechanism 53 (corresponding to the second air supply passage P12 in Fig. 7). In the air supply fan chamber S25, the air supply fan 61 is accommodated. The discharge port of the air supply fan (61) is connected to the air supply mechanism (53). The compressor 103 and the four-way switching valve 105 (not shown) of the refrigerant circuit 100 are accommodated in the air supply fan chamber S25. On the other hand, the regeneration side suction chamber S28 communicates with the indoor space S1 via a duct (corresponding to the first regeneration passage P21 in Fig. 7) connected to the regeneration side suction port 52. [

The second suction side internal passage (S23) is partitioned by a partition plate extending forward and backward from the regeneration side suction chamber (S28), and communicates with the air supply fan chamber (S25). The first regeneration side inner passage (S22) communicates with the regeneration side suction chamber (S28).

The right space S33 is divided into a right side portion of the casing 41 and a second partition plate 47 side portion. The front space on the right side space of the casing 41 in the right space S33 constitutes the exhaust fan chamber S26. On the other hand, the inner space is divided into upper and lower portions, and the lower space constitutes a suction side suction chamber S27 partitioned from the exhaust fan chamber S26, and the upper space communicates with the exhaust fan chamber S26. The space on the side of the second partition plate 47 in the right space S33 is divided into two upper and lower spaces, the upper space constitutes the second regenerating side internal passage S24, and the lower space constitutes the first adsorption side inner And constitutes the passage S21.

The exhaust fan chamber S26 communicates with the outdoor space through a duct (corresponding to the second regeneration passage P22 in Fig. 7) connected to the exhaust port 54. [ An exhaust fan 62 is accommodated in the exhaust fan chamber S26. The discharge port of the exhaust fan (62) is connected to the exhaust port (54). The suction side suction chamber S27 communicates with the outdoor space through a duct connected to the suction side suction port 51 (corresponding to the first air supply passage P11 in Fig. 7).

The second regeneration side internal passage S24 communicates with the exhaust fan chamber S26. The first suction side internal passage (S21) communicates with the suction side suction chamber (S27).

The central space S32 is divided into a front space and a rear space by a central partition plate 48 and a rear space of the central partition plate 48 constitutes a first heat exchange chamber S11 and a front space of the central partition plate 48 And constitutes a second heat exchange chamber S12. The first adsorption heat exchanger 101 is accommodated in the first heat exchange chamber S11 and the second adsorption heat exchanger 102 is accommodated in the second heat exchange chamber S12. In the second heat exchange chamber S12, an expansion valve 104 (not shown) of the refrigerant circuit 100 is accommodated.

Each of the first and second adsorption heat exchangers (101, 102) is formed into a generally rectangular plate-like or flat rectangular parallelepiped shape, and two main surfaces (wide side surfaces) . The first adsorption heat exchanger 101 is installed so as to stand in the first heat exchange chamber S11 such that the two main surfaces are parallel to the first and second partition plates 46 and 47 . Similarly, the second adsorption heat exchanger 102 is installed so as to stand in the second heat exchange chamber S12 in such a posture that the two main surfaces are parallel to the first and second partition plates 46 and 47 do.

Each of the first and second adsorption blocks 301 and 302 is formed as a generally rectangular plate-like or flat rectangular parallelepiped, and two main surfaces (wide side surfaces) opposed to each other serve as a surface through which air passes. For example, each of the first and second suction blocks 301 and 302 is a honeycomb structure having a plurality of holes passing from one main surface to the other main surface. The first adsorption block 301 is installed so as to stand in the first heat exchange chamber S11 in such a posture that the two main surfaces are parallel to the first and second partition plates 46 and 47. Likewise, the second adsorption block 302 is installed so as to stand in the second heat exchange chamber S12 in such a manner that the two main surfaces are parallel to the first and second partition plates 46, 47 . In this example, the first adsorption block 301 is disposed between the first adsorption heat exchanger 101 and the first partition plate 46 in the first heat exchange room S11, and the second adsorption block 301 is disposed between the first adsorption heat exchanger 101 and the first partition plate 46 in the first heat exchange room S11, The block 302 is disposed between the second adsorption heat exchanger 102 and the first partition plate 46 in the second heat exchange chamber S12. The first adsorption block 301 is spaced apart from the first adsorption heat exchanger 101 in the left and right direction and the second adsorption block 302 is disposed in the second adsorption heat exchanger 102 ).

The first to fourth dampers D1 to D4 are provided in the first partition plate 46 and the fifth to eighth dampers D5 to D8 are provided in the second partition plate 47. [ Each of the first to eighth dampers D1 to D8 is configured to be capable of switching between an open state and a closed state in response to a control by the controller 20. [ The first to eighth dampers D1 to D8 constitute a switching mechanism 200. [

The first damper D1 is mounted on the upper side of the first partition plate 46 (the portion facing the second suction side internal passage S23) on the front side than the central partition plate 48, The damper D2 is mounted on the rear side of the central partition plate 48 in the upper portion of the first partition plate 46. [ The third damper D3 is mounted on the lower side of the first partition plate 46 (the portion facing the first regeneration side internal passage S22) on the front side of the central partition plate 48, The damper D4 is mounted on the rear side of the first partition plate 46 at a lower portion than the central partition plate 48. [

When the first damper D1 is opened, the second adsorption-side inner passage S23 and the second heat exchange chamber S12 communicate with each other. When the second damper D2 is opened, the second adsorption-side internal passage S23 and the first heat exchange chamber S11 communicate with each other. When the third damper D3 is opened, the first regeneration side internal passage S22 and the second heat exchange chamber S12 communicate with each other. When the fourth damper D4 is opened, the first regeneration side internal passage S22 and the first heat exchange chamber S11 communicate with each other.

The fifth damper D5 is mounted on the upper side of the second partition plate 47 (the portion facing the second regeneration side inner passage S24) on the front side of the central partition plate 48, The damper D6 is mounted on the back side of the second partition plate 47 in the upper portion than the central partition plate 48. [ The seventh damper D7 is mounted on the front side of the lower partition (the portion facing the first adsorption-side inner passage S21) of the second partition plate 47 in front of the central partition plate 48, The damper D8 is mounted on the rear side of the second partition plate 47 at a lower portion than the central partition plate 48. [

When the fifth damper D5 is opened, the second regeneration side internal passage S24 and the second heat exchange chamber S12 communicate with each other. When the sixth damper D6 is opened, the second regeneration side internal passage S24 and the first heat exchange chamber S11 communicate with each other. When the seventh damper D7 is opened, the first adsorption-side inner passage S21 and the second heat exchange chamber S12 communicate with each other. When the eighth damper D8 is opened, the first adsorption-side internal passage S21 and the first heat exchange chamber S11 communicate with each other.

&Quot; Air flow in the first dehumidifying operation &quot;

Next, the flow of air in the first dehumidifying operation by the dehumidifier 10 of the second embodiment will be described with reference to Fig. In the first dehumidifying operation, the first adsorption heat exchanger (101) is evaporated and the second adsorption heat exchanger (102) becomes a condenser. 8, the second, third, fifth, and eighth dampers D2, D3, D5, and D8 are opened and the first, fourth, sixth, and seventh dampers D1, D4 , D6, D7 are closed. Accordingly, the connection state of the first and second heat exchange chambers S11 and S12 is set to the first passage state (the state shown by the solid line in Fig. 7), and the first heat exchange chamber S11 is connected to the air supply passage P1 And the second heat exchange chamber S12 is installed in the regeneration passage P2.

- Air flow in the air supply passage -

(In this example, outdoor air OA) supplied to the first suction side internal passage S21 via the suction side suction port 51 and the suction side suction chamber S27 passes through the eighth damper D8 And is supplied to the first heat exchange chamber S11.

The air supplied to the first heat exchange chamber S11 passes through the first adsorption heat exchanger 101 and the first adsorption block 301 while passing through the first adsorption heat exchanger 101 and the first adsorption block 301 in order. 301) is dehumidified by taking moisture from the adsorbent.

The dehumidified air passing through the first adsorption heat exchanger 101 and the first adsorption block 301 passes through the second damper D2 and flows into the second adsorption side internal passage S23, And the air supply mechanism 53 and is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air (in this example, the room air RA) supplied to the first regeneration side internal passage S22 via the regeneration side intake port 52 and the regeneration side intake chamber S28 passes through the third damper D3 And is supplied to the second heat exchange chamber S12.

The air supplied to the second heat exchange chamber S12 flows through the second adsorption block 302 and the second adsorption heat exchanger 102 when passing through the second adsorption block 302 and the second adsorption heat exchanger 102 in order Water is imparted from the adsorbent. As a result, the adsorbent of the second adsorption heat exchanger 102 and the adsorbent of the second adsorption block 302 is regenerated.

The air having passed through the second adsorption block 302 and the second adsorption heat exchanger 102 flows through the fifth damper D5 into the second regeneration side internal passage S24, Passes through the exhaust port (54) and is discharged to the outdoor space.

&Quot; Air flow in the second dehumidifying operation &quot;

Next, the flow of air in the second dehumidifying operation by the dehumidifier 10 of the second embodiment will be described with reference to Fig. In the second dehumidification operation, the first adsorption heat exchanger (101) serves as a condenser and the second adsorption heat exchanger (102) serves as an evaporator. 9, the first, fourth, sixth and seventh dampers D1, D4, D6 and D7 are opened and the second, third, fifth and eighth dampers D2 and D3 , D5, and D8 are closed. Thus, the connection state of the first and second heat exchange chambers S11 and S12 is set to the second passage state (the state shown by the broken line in Fig. 7), and the first heat exchange chamber S11 is connected to the regeneration passage P2 And the second heat exchange chamber S12 is installed in the air supply passage P1.

- Air flow in the air supply passage -

(In this example, outdoor air OA) supplied to the first suction side internal passage S21 via the suction side suction port 51 and the suction side suction chamber S27 passes through the seventh damper D7 And is supplied to the second heat exchange chamber S12.

The air supplied to the second heat exchange chamber S12 flows through the second adsorption heat exchanger 102 and the second adsorption block 102 when passing through the second adsorption heat exchanger 102 and the second adsorption block 302 in order. 302) to be dehumidified.

The dehumidified air passing through the second adsorption heat exchanger 102 and the second adsorption block 302 passes through the first damper D1 and flows into the second adsorption side internal passage S23 and flows into the air supply fan chamber S25 And the air supply mechanism 53 and is supplied to the indoor space S1 as the supply air SA.

- air flow in the regeneration path -

The air (in this example, the room air RA) supplied to the first regeneration side internal passage S22 via the regeneration side intake port 52 and the regeneration side intake chamber S28 passes through the fourth damper D4 And is supplied to the first heat exchange chamber S11.

The air supplied to the first heat exchange chamber S11 passes through the first adsorption block 301 and the first adsorption heat exchanger 101 101). &Lt; / RTI &gt; Thus, the adsorbent of the first adsorption heat exchanger (101) and the first adsorption block (301) is regenerated.

The air having passed through the first adsorption block 301 and the first adsorption heat exchanger 101 flows through the sixth damper D6 into the second regeneration side internal passage S24 and flows into the exhaust gas compartment S26 and Passes through the exhaust port (54) and is discharged to the outdoor space.

&Lt; Effect according to the second embodiment &gt;

In the dehumidifying device 10 of the second embodiment, the first and second adsorption blocks 301 and 302 are added to the first and second heat exchange chambers S11 and S12 to form the first and second heat exchange chambers S11 , S12) can be increased.

Further, when the first adsorption heat exchanger (S11) is sucked into the air supply passage (P1), the first adsorption block (301) is disposed at a position where air dehumidified by the first adsorption heat exchanger (101) 1 adsorption heat exchanger (101) to the first adsorption block (301). Thus, adsorption of moisture to the adsorbent in the first adsorption block 301 can be promoted. Similarly, when the second heat exchange chamber S12 is provided in the air supply passage P1, the dehumidified and cooled air can be supplied to the second adsorption block 302 by the second adsorption heat exchanger 102 , Adsorption of moisture to the adsorbent in the second adsorption block 302 can be promoted. That is, in the first and second heat exchange chambers S11 and S12, when the adsorption heat exchangers 101 and 102 serve as evaporators, the adsorption heat exchangers (101 and 102) 301 and 302 can be supplied to the adsorption blocks 301 and 302 by the adsorption heat exchangers 101 and 102 so that the adsorption blocks 301 and 302 can adsorb moisture to the adsorbent . &Lt; / RTI &gt;

As described above, the amount of dehumidification of air in the first and second heat exchange rooms S11 and S12 can be increased, and the adsorption of water to the adsorbent in the adsorption blocks 301 and 302 can be promoted , The dehumidifying ability of the dehumidifying device (10) can be improved.

In addition, since the number of revolutions of the compressor 103 of the refrigerant circuit 100 need not be increased in order to improve the dehumidifying capability of the dehumidifying device 10, the increase in power consumption of the dehumidifying device 10 can be suppressed.

In the second embodiment, in each of the first and second heat exchange chambers S11 and S12, the adsorption blocks 301 and 302 are arranged so that adsorption heat exchangers (101 and 102) Is located on the downstream side of the heat exchangers 101 and 102 and is located on the upstream side of the adsorption heat exchangers 101 and 102 when the adsorption heat exchangers 101 and 102 serve as a condenser. Therefore, by passing the air that has passed through the heater 21 to the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 which serve as the condensers in the first and second heat exchange rooms S11 and S12, The air heated by the heater 21 can be supplied to the adsorption blocks 301 and 302 located on the upstream side of the adsorption heat exchangers 101 and 102 in the heat exchange chambers S11 and S12. Accordingly, regeneration of the adsorbent in the adsorption blocks 301 and 302 can be promoted.

In the first embodiment, when the first adsorption heat exchanger 101 serves as a condenser, the first adsorption block 301 is located downstream of the first adsorption heat exchanger 101 in the first heat exchange room S11 The air having passed through the first adsorption heat exchanger (101) is supplied to the first adsorption block (301). In this case, air supplied to the first adsorption block 301 through the first adsorption heat exchanger 101 is not only heated by the first adsorption heat exchanger 101 but also becomes humidified. The same applies to the second adsorption block 302.

On the other hand, in the second embodiment, in the case where the first adsorption heat exchanger 101 serves as a condenser, the first adsorption block 301 is located upstream of the first adsorption heat exchanger 101 in the first heat exchange room S11 And the air heated by the heater 21 is supplied to the first adsorption block 301. In this case, air supplied to the first suction block 301 through the heater 21 is heated by the heater 21, but is not humidified. Therefore, regeneration of the adsorbent of the first adsorption block 301 can be promoted more than that of the first embodiment, and the adsorption ability in the first adsorption block 301 can be further improved. The same applies to the second adsorption block 302.

By disposing the first adsorption block 301 at a distance from the first adsorption heat exchanger 101, it is possible to suppress the unevenness of the temperature distribution and the air drift in the first adsorption block 301. The same applies to the second adsorption block 302. As described above, since the first and second adsorption blocks 301 and 302 can suppress the unevenness of the temperature distribution and the air drift, the adsorption ability and regeneration ability of the first and second adsorption blocks 301 and 302 Can be suppressed.

(Modification of Second Embodiment)

10, the dehumidifying system 1 is provided with a dehumidifying device 30 for the preceding process in addition to the dehumidifier 10, the controller 20 and the heater 21 shown in Fig. 7 . In this example, the humidity control space S0 is constituted by an indoor space S1 and a chamber S2 provided in the indoor space S1. In the dehumidifying system 1, a front treatment passage P3 and a rear treatment passage P4 are formed. In this dehumidifying system 1, the dehumidified air (OA in this example) is supplied as the supply air SA0 to the indoor space S1 by the dehumidifying device 30 for the preceding process (In this example, room air RA) dehumidified by the dehumidifying device 10 is supplied to the chamber S2 as the supply air SA. The controller (20) controls the dehumidifying device (10) and the pre-processing dehumidifying device (30) based on the detection values of various sensors.

&Lt; Previous treatment passage, after (after) treatment passage &gt;

The front processing passage P3 is configured to suck the outdoor air OA from the outdoor space and supply the supply air SA0 to the indoor space S1. The aftertreatment passage P4 is configured to draw air from the outlet end of the regeneration passage P2 to discharge the exhaust air EA to the outdoor space.

<Supply air passage, regeneration passage>

In this example, the supply passage P1 is configured to suck indoor air RA from the indoor space S1 and supply the supply air SA to the chamber S2. Concretely, the inlet end of the first air supply passage P11 is connected to the indoor space S1, and the outlet end of the second air supply passage P12 is connected to the chamber S2. The regeneration passage P2 is configured to suck indoor air RA from the indoor space S1 and discharge the treated air to the post-treatment passage P4. Concretely, the inlet end of the first regeneration passage P21 is connected to the middle portion of the first air supply passage P11, and the outlet end of the second regeneration passage P22 is connected to the first end ) Processing passage P41.

<Dehumidifying device for previous treatment>

The dehumidifying device 30 for the previous treatment has the same configuration as the dehumidifying device 10. [ The structure of the dehumidifying device 30 for the preceding process is the same as that of the dehumidifying device 10 shown in Fig.

&Lt; Refrigerant circuit of dehumidifying device for previous treatment &gt;

The refrigerant circuit 100 of the dehumidifying device 30 for the preceding process is connected to the first adsorption heat exchanger (not shown) in response to the control by the controller 20, like the refrigerant circuit 100 of the dehumidifier 10 101) serves as an evaporator to dehumidify the air, a second adsorption heat exchanger (102) serves as a condenser to regenerate the adsorbent, and a second adsorption heat exchanger (102) serves as an evaporator to dehumidify the air, 1 adsorption heat exchanger 101 serves as a condenser and regenerates the adsorbent.

&Lt; Switching mechanism of the dehumidifying device for previous treatment &gt;

The switching mechanism 200 of the pre-processing dehumidifying device 30 is switched to the first and second heat exchange chambers (not shown) of the pre-processing dehumidifier 30 in response to the control by the controller 20 (The state shown by the solid line in FIG. 10) and the fourth passage state (the state shown in FIG. 10) and the connection state between the front processing channel P3 and the rear processing channel P4, (Indicated by broken lines in Fig.

&Quot; Third passage condition &quot;

When the connection state of the first and second heat exchange chambers S11 and S12 of the pre-processing dehumidifier 30 becomes the third passage state, the first heat exchange chamber S11 is connected to the first and second pre- And the second heat exchange chamber S12 is connected to the first and second post processing passages P41 and P42 by being connected between the passage portions P31 and P32 and provided in the front processing passage P3, And is installed in the post-treatment process passage P4.

&Quot; Fourth passage condition &quot;

When the connection state of the first and second heat exchange chambers S11 and S12 of the pre-processing dehumidifying device 30 becomes the fourth passage state, the first heat exchange chamber S11 is closed by the first and second heat exchange chambers And the second heat exchange chamber S12 is connected to the first and second pretreatment passage portions P31 and P32 and is connected to the rear processing passage P4 and is connected between the rear processing passage portions P41 and P42, And is installed in the preceding process passage P3.

&Quot; Connection switching operation of heat exchange chamber &

The switching mechanism 200 of the front processing dehumidifier 30 is connected to the first and second heat exchange chambers S11 and S12 when the four- State is set to the third passage state and the connection state of the first and second heat exchange rooms S11 and S12 is set to the fourth passage state when the four-way selector valve 105 is in the second connection state. That is, the switching mechanism 200 of the pre-processing dehumidifying device 30, like the switching mechanism 200 of the dehumidifying device 10, is provided between the first and the second heat exchange rooms S11 and S12, The air having passed through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 serving as the adsorption heat exchangers 101 and 102 is supplied to the humidity control space S0 and the heat exchange chambers S12 (S11, S12) of the dehumidifier 10, in which the adsorption heat exchangers 101, 102, which serve as the condensers, are provided for regenerating the adsorbent S11, and S12) flows.

&Quot; Flow direction of air passing through adsorption heat exchanger &quot;

In this example, in the case where the connection state of the first and second heat exchange chambers S11 and S12 in the pre-processing dehumidifier 30 is the third passage state (that is, the first heat exchange chamber The flow direction of the air passing through the first adsorption heat exchanger 101 in the first and second heat exchange chambers S11 and S12 is the same as the flow direction of the air passing through the first adsorption heat exchanger 101, The air passing through the first adsorption heat exchanger 101 in the case where the connection state is the fourth passage state (that is, when the first heat exchange chamber S11 is provided as a part of the after-treatment passage P4) It is the opposite direction of the flow direction. The same applies to the flow direction of air passing through the second adsorption heat exchanger 102. That is, the switching mechanism 200 of the pre-processing dehumidifier 30 is provided with the first adsorption heat exchanger 101 and the second adsorption heat exchanger 102, respectively, as in the switching mechanism 200 of the dehumidifier 10 The flow direction of the air passing through the adsorption heat exchangers 101 and 102 is switched so that the adsorption heat exchangers 101 and 102 become the evaporator and the adsorption heat exchangers 101 and 102 become the condenser .

&Lt; Dehumidifying operation by dehumidifying device for previous treatment &gt;

Next, the dehumidifying operation by the dehumidifying device 30 for the preceding process will be described with reference to Fig. Like the previous processing dehumidifier 30 of the modification 3 of the first embodiment, the former processing dehumidifier 30 of the modified example of the second embodiment differs from the former dehumidification apparatus 30 of the second embodiment in that the third and fourth dehumidification operations Are alternately repeated at predetermined time intervals (for example, every 10 minutes).

&Quot; Third dehumidification action &

In the third dehumidifying operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way switching valve 105 becomes the first connected state (the state shown by the solid line in FIG. 10). Thus, the refrigerant circuit 100 performs the first refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes an evaporator and the second adsorption heat exchanger 102 becomes a condenser. Further, the switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the third passage state (the state shown by the solid line in Fig. 10).

"Fourth dehumidification action"

In the fourth dehumidification operation, the compressor 103 is driven and the opening degree of the expansion valve 104 is adjusted so that the four-way switching valve 105 becomes the second connected state (the state shown by the broken line in Fig. 10). Thus, the refrigerant circuit 100 performs the second refrigeration cycle operation in which the first adsorption heat exchanger 101 becomes the condenser and the second adsorption heat exchanger 102 becomes the evaporator. Further, the switching mechanism 200 sets the connection state of the first and second heat exchange rooms S11 and S12 to the fourth passage state (the state shown by the broken line in Fig. 10).

&Lt; Effects of Modifications of the Second Embodiment &gt;

As described above, the dehumidifying device 30 dehumidifies the air (OA in this example) to be supplied to the indoor space S1 and supplies the dehumidified air to the indoor space And the dehumidifying device 10 dehumidifies the room air RA supplied from the indoor space S1 and supplies the dehumidified air to the chamber S2 as the supply air SA, The dew point temperature can be made lower than the dew point temperature of air in the indoor space S1. By supplying the supply air SA at the low dew point to the chamber S2 in this way, the power consumption required for the operation of the dehumidifying system 1 can be reduced, as compared with the case where the entire indoor space S1 is set as the low dew point can do.

(Third Embodiment)

11 shows a configuration example of the dehumidifying system 1 according to the third embodiment. The dehumidifying system 1 includes a dehumidifying device 30 for the preceding process shown in Fig. 10, instead of the dehumidifying device 30 for the previous process shown in Fig. The rest of the configuration is the same as in Fig. The same effects as those of Modification 3 (FIG. 6) and Modification 2 (FIG. 10) of the first embodiment can also be obtained in the case of such a configuration.

(Fourth Embodiment)

Fig. 12 shows a configuration example of the dehumidifying system 1 according to the fourth embodiment. The dehumidification system 1 includes a heater 21, an adsorption rotor 70 and a subcooler 80 in addition to the dehumidifier 10 and the controller 20 shown in Fig. The dehumidifying system 1 is provided with a rotor air supply passage P71, a rotor regeneration passage P72, a purge passage P73 and a cooling air passage P80.

<Rotor supply passage>

In the rotor air supply passage P71, air (in this example, air to be supplied to the indoor space S1) to be supplied to the humidity control space S0 flows. In this example, the rotor air supply passage P71 is configured to suck air from the outlet end of the air supply passage P1 to supply the supply air SA to the indoor space S1. Specifically, in the rotor air supply passage P71, the inlet end is connected to the outlet end of the air supply passage P1, and the outlet end is connected to the indoor space S1.

<Rotor regeneration passage>

In the rotor regeneration passage P72, air (in this example, air supplied from the purge passage P73) for regenerating the adsorbent flows. In this example, the rotor regeneration passage P72 is configured to suck air from the outlet end of the purge passage P73 to supply the regeneration air (air for regenerating the adsorbent) to the regeneration passage P2. Specifically, the rotor regeneration passage P72 has its inlet end connected to the outlet end of the purge passage P73, and the outlet end connected to the inlet end of the regeneration passage P2.

<Purge passage>

In the purge passage P73, air (in this example, air supplied from the air supply passage P1) to be supplied to the rotor regeneration passage P72 flows. In this example, the purge passage P73 is configured to suck air from the outlet end of the air supply passage P1 to supply the regeneration air to the rotor regeneration passage P72. Specifically, the purge passage P73 has its inlet end connected to the outlet end of the air supply passage P1, and the outlet end connected to the inlet end of the rotor regeneration passage P72.

<Cooling air passage>

In the cooling air passage (P80), the cooled and dehumidified air flows. In this example, the cooling air passage P80 sucks the room air RA from the indoor space S1 and transfers the air to the intermediate portion of the air supply passage P1 (specifically, the adsorption heat exchanger 101 as an evaporator (A portion through which air that has passed through the heat exchange chambers S11 and S12 provided with the heat exchange chambers 102) passes. Specifically, the cooling air passage P80 has its inlet end connected to the indoor space S1, and the outlet end connected to the middle portion of the air supply passage P1.

<Heater>

The heater 21 is provided in the rotor regeneration passage P72 and is configured to heat the air (in this example, the air supplied to the rotor regeneration passage P72 from the purge passage P73) for regenerating the adsorbent. Here, the heating temperature of the heater 21 is set to a temperature (for example, 60 DEG C) lower than the upper limit of the condensation temperature of the adsorption heat exchangers 101 and 102. [

<Adsorption Rotor>

The adsorption rotor 70 is constituted by carrying an adsorbent on the surface of a disc-shaped porous base material, and is disposed over the rotor air supply passage P71, the regeneration passage P72 and the purge passage P73. The adsorption rotor 70 is driven by a drive mechanism (not shown) and is configured to rotate about the axial center between the rotor air supply passage P71 and the rotor regeneration passage P72 and the purge passage P73 . Specifically, the adsorption rotor 70 includes an adsorbing portion 71 disposed in the rotor air supply passage P71, a regeneration portion 72 disposed in the rotor regeneration passage P72, and a regeneration portion 72 disposed in the purge passage P73 As shown in Fig. The adsorbent carried on the adsorption rotor 70 sequentially moves the adsorption section 71, the regeneration section 72 and the purge section 73 as the adsorption rotor 70 rotates. That is, in the adsorption rotor 70, the portion of the adsorbing portion 71 that is located in the regeneration portion 72 moves to the regeneration portion 72, and the portion of the adsorption rotor 70 that is located in the regeneration portion 72 moves to the purge portion 73, 73 are moved to move to the adsorbing portion 71.

The &quot;

The adsorption unit 71 is connected to the adsorption heat exchangers 101 and 102 (in this example, the first and second heat exchange rooms S11 and S12 of the dehumidifying device 10) (Air having been passed through the cooling air passage P80) to the air passing through the heat exchange chambers S11 and S12 provided with the adsorbent (hereinafter referred to as the adsorbent) is contacted with the adsorbent to dehumidify the air. The dehumidified air passing through the adsorption unit 71 is supplied to the indoor space S1 as the supply air SA.

&Quot;

The regeneration section 72 is disposed at a position downstream of the heater 21 in the rotor regeneration passage P72 and is disposed at a position where the air flowing through the rotor regeneration passage P72 Air) with the adsorbent to regenerate the adsorbent. The air that has passed through the regeneration section 72 is supplied to the regeneration passage P2.

"Finger"

The purge portion 73 is supplied to the regeneration portion 72 using the exhaust heat of the regeneration portion 72 (concretely, the arrangement not used for regeneration of the adsorbent in the regeneration portion 72) It is the part to preheat the air. More specifically, in the purge portion 73, air flowing through the purge passage P73 is dehumidified by contact with the adsorbent. The portion located in the regeneration portion 72 (i.e., the portion heated by the air that has passed through the heater 21) moves to the purge portion 73 as the adsorption rotor 70 rotates. Therefore, the air flowing through the purge passage P73 is preheated by applying heat (i.e., the arrangement of the regenerator 72) from the purge portion 73. [ The portion located at the purge portion 73 is cooled by applying heat to the air passing through the purge passage P73 and then moved to the adsorption portion 71 following the rotation of the adsorption rotor 70. [

<Subcooler>

The subcooler 80 is installed in the cooling air passage P80 and cools the air (in this example, the room air RA) flowing through the cooling air passage P80. For example, the subcooler 80 may be constituted by a heat exchanger (specifically, a fin-and-tube heat exchanger) functioning as an evaporator of a refrigerant circuit (not shown). The air cooled in the cooling air passage P80 is supplied to the adsorption heat exchanger 12 serving as an evaporator among the air flowing in the air supply passage P1 (in this example, the first and second heat exchange rooms S11 and S12 of the dehumidifying device 10) (Air that has passed through the heat exchange chambers S11 and S12 provided with the heat exchangers 101 and 102).

<Dehumidifying device>

In this example, the air that has passed through the air supply passage P1 passes through the rotor air supply passage P71 and is supplied to the indoor space S1. That is, the air that has passed through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 which serve as evaporators in the first and second heat exchange rooms S11 and S12 of the dehumidifier 10, 70, and is supplied to the indoor space S1.

In this example, the air that has passed through the rotor regeneration passage P72 passes through the regeneration passage P2 and is discharged to the outdoor space. That is, the switching mechanism 200 of the dehumidifying device 10 is connected to the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101 as the condensers in the first and second heat exchange rooms S11 and S12, The flow of the air is switched so that air passing through the heater 21 and the regeneration section 72 of the adsorption rotor 70 in turn flows.

<Effects according to the fourth embodiment>

As described above, the air (in this example, the air to be supplied to the indoor space S1) to be supplied to the humidity control space S0 is supplied to the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102, S12), the dehumidified air is further dehumidified in the adsorption portion 71 of the adsorption rotor (70). Thus, by adding the adsorption rotor 70, the dehumidifying ability of the dehumidifying system 1 can be improved.

The air heated by the heater 21 passes through the regeneration section 72 of the adsorption rotor 70 and then passes through the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101 serving as a condenser It passes. That is, the air that has passed through the regeneration section 72 of the adsorption rotor 70 can be used for adsorbent regeneration of the adsorption heat exchangers 102, 101 and the adsorption blocks 302, 301. Thus, the air heated by the heater 21 can be effectively used.

In addition, by supplying the air flowing through the cooling air passage P80 to the middle portion of the air supply passage P1, the adsorption heat exchangers 101 and 102 serving as the evaporators are cooled using the air cooled in the cooling air passage P80 It is possible to lower the temperature of the air that has passed through the installed heat exchange rooms S11 and S12. That is, it is possible to lower the temperature of the air that has risen due to the remaining heat remaining in the adsorption blocks 302, 301 and the adsorption heat of the adsorption blocks 302, 301.

Since part of the air supplied from the air supply passage P1 passes through the purge passage P73, the rotor regeneration passage P72 and the regeneration passage P2 in this order, the adsorption heat exchangers 101 and 102 serving as evaporators are installed A part of the air that has passed through the heat exchange chambers S11 and S12 (that is, the air dehumidified by the dehumidifier 10) is introduced into the adsorbent of the adsorption heat exchanger 102 or 101, which is the adsorbent of the adsorption rotor 70 and the condenser, It can be used for playback. Thus, regeneration of the adsorbent can be promoted.

(Other Embodiments)

In the above description, the case where the first adsorption block 301 is disposed at a distance from the first adsorption heat exchanger 101 and the second adsorption block 302 is disposed at a distance from the second adsorption heat exchanger 102 The first adsorption block 301 may be arranged to be in contact with the first adsorption heat exchanger 101 and the second adsorption block 302 may be arranged to be in contact with the second adsorption heat exchanger 102 . With this configuration, it is possible to promote the heat conduction between the first adsorption heat exchanger 101 and the first adsorption block 301, and to promote the heat transfer between the second adsorption heat exchanger 102 and the second adsorption block 302 It is possible to promote the thermal conduction. For example, when the first heat exchange chamber S11 is provided in the air supply passage P1, the first adsorption block 301 can be cooled by the heat absorbing action of the refrigerant flowing through the first adsorption heat exchanger 101 When the first heat exchange chamber S11 is provided in the regeneration passage P2, the first adsorption block 301 can be heated by the heat radiation action of the refrigerant flowing through the first adsorption heat exchanger 101. [ As a result, adsorption of moisture to the adsorbent and regeneration of the adsorbent in the first and second adsorption blocks 301 and 302 can be promoted.

In addition, one dehumidifying unit may be constituted by connecting a plurality of dehumidifying apparatuses 10 in parallel with each other. For example, a plurality of dehumidifying apparatuses 10 shown in Fig. 2 (or Fig. 7) are vertically stacked to form openings of the respective dehumidifying apparatuses 10 (specifically, adsorption-side inlets 51, regeneration- ), The air supply mechanism (53), and the air exhaust port (54)) may be connected in common for each type to constitute one dehumidifying unit.

The first adsorption heat exchanger 101 and the second adsorption heat exchanger 102 are enlarged in size without adding the first adsorption block 301 and the second adsorption block 302 to the dehumidification device 10, You can think of improving your ability. That is, by increasing the size of the adsorption heat exchanger, the absorption heat of the refrigerant can be increased in the adsorption heat exchanger functioning as the evaporator. As a result, the temperature of the air in the adsorption heat exchanger can be lowered, and the temperature rise of the air due to the adsorption heat of the adsorbent can be suppressed. In addition, as the temperature of the air in the adsorption heat exchanger is lowered, the amount of saturated water vapor in the air is lowered, and moisture in the air tends to be easily adsorbed on the adsorbent. Thus, adsorption of moisture from the air to the adsorbent can be promoted by the endothermic effect of the refrigerant.

However, in the interior of the adsorption heat exchanger functioning as an evaporator, the temperature of the air and the amount of water in the air become smaller as the direction from the upstream side toward the downstream side. That is, in the adsorption heat exchanger, the dehumidified and cooled air on the upstream side is supplied to the downstream side. Therefore, even if the temperature of the air is lowered due to the endothermic effect of the refrigerant and the amount of saturated water vapor in the air is reduced on the downstream side in the adsorption heat exchanger, the water content in the air becomes small, and therefore it is difficult to promote the adsorption of moisture from the air into the adsorbent . Also, the smaller the moisture content in the air is, the smaller the amount of adsorbed heat generated by the adsorbent is. As a result, on the downstream side of the adsorption heat exchanger, the adsorbent is over-cooled by the endothermic effect of the refrigerant.

As described above, even when the size of the adsorption heat exchanger is increased, the effect of the endothermic effect of the refrigerant (the effect of promoting the adsorption of moisture to the adsorbent, It is difficult to effectively improve the dehumidifying ability of the dehumidifying device 10. [0064]

It is also conceivable to increase the contact area between the air and the adsorbent as means for promoting moisture adsorption from the air to the adsorbent. That is, the larger the contact area between air and the adsorbent, the more easily the moisture in the air is adsorbed by the adsorbent. Particularly, when the moisture content in the air is small, when the contact area between the air and the adsorbent is made larger than when the temperature of the air is lowered by the endothermic effect of the refrigerant, the adsorption of moisture from the air to the adsorbent is promoted . In addition, since there is no need to provide a component such as a refrigerant pipe in the adsorption block, the adsorption block is easier to increase the surface area (contact area with air) than the adsorption heat exchanger in terms of structure. Therefore, by disposing the adsorption block at a position downstream of the adsorption heat exchanger functioning as an evaporator (a position where the air that has been dehumidified and cooled by the adsorption heat exchanger passes through), the adsorption block is disposed on the downstream side of the adsorption heat exchanger, The dehumidifying ability of the dehumidifying device 10 can be improved more effectively than the case of increasing the size of the adsorption heat exchanger.

In general, the regeneration operation of the adsorbent (moisture release from the adsorbent) leads to a higher reaction rate than the adsorption action of the adsorbent (adsorption of moisture from the air to the adsorbent). Therefore, the air flow rate of the air passing through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 as the evaporators in the first and second heat exchange rooms S11 and S12 is the same as that of the adsorption heat exchanger 102, 101 may be equal to or greater than the air flow rate passing through the heat exchange chambers S12, S11 provided with the heat exchanger.

Although the heater 21 is provided in the regeneration passage P2 in the second embodiment (Fig. 7) and the modification of the second embodiment (Fig. 10), the dehumidifying system 1, The heater 21 may not be provided. For example, the temperature of the air supplied to the regeneration passage P2 (that is, the air supplied to the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101 as condensers) (That is, air supplied to the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 serving as evaporators), and the temperature difference between these air is a predetermined temperature difference (specifically, , The temperature difference at which the adsorbent can be regenerated), the heater 21 may be omitted.

The above embodiments may be appropriately combined. The above embodiments are essentially preferred examples and are not intended to limit the scope of the present invention, its applications, or uses thereof.

[Industrial applicability]

As described above, the dehumidifying device described above is useful as a dehumidifying device for dehumidifying a humidity control space such as a dry clean room.

1: Dehumidification system 10: Dehumidification system
100: Refrigerant circuit 101: First adsorption heat exchanger
102: second adsorption heat exchanger 103: compressor
104: expansion valve 105: four-way switching valve
200: switching mechanism 301: first adsorption block
302: second adsorption block S0: humidity control space
S1: interior space S2: chamber
S11: first heat exchange chamber S12: second heat exchange chamber
P1: supply passage P2: regeneration passage
20: Controller 30: Dehumidifying device for previous treatment
P3: previous treatment passage P4: after (after) treatment passage
70: adsorption rotor 71: adsorption section
72: reproduction section 73:

Claims (7)

The first adsorption heat exchanger (101) serves as an evaporator and dehumidifies air, and the second adsorption heat exchanger (102) becomes a condenser. The first adsorption heat exchanger (101) and the second adsorption heat exchanger A first operation for regenerating the adsorbent and a second operation for regenerating the adsorbent by the first adsorption heat exchanger 101 as a condenser and dehumidifying the air as an evaporator by the second adsorption heat exchanger 102 A refrigerant circuit 100,
First and second heat exchange chambers (S11, S12) in which the first and second adsorption heat exchangers (101, 102) are respectively installed,
The air that has passed through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 which serve as evaporators out of the first and second heat exchange rooms S11 and S12 is supplied to the humidifying space S0 A switching mechanism 200 for switching the air flow so that air for regenerating the adsorbent flows in the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101 to be supplied as the condenser,
The first adsorption heat exchanger 101 and the second adsorption heat exchanger 101 are arranged such that the adsorbent is supported to bring air into contact with the adsorbent and is disposed in the first heat exchange room S11, A first suction block 301 disposed at a position downstream of the first adsorption block 301,
And the second adsorption heat exchanger (102) is configured to contact the adsorbent with the adsorbent to be disposed in the second heat exchange room (S12). When the second adsorption heat exchanger (102) And a second adsorption block (302) disposed at a position downstream of the adsorption block
Wherein the dehumidifying device is a dehumidifying device. The method according to claim 1,
The switching mechanism 200 is configured such that the flow direction of the air passing through each of the first and second adsorption heat exchangers 101 and 102 is changed in the case where the adsorption heat exchangers 101 and 102 serve as an evaporator, And switches the flow of the air so that the heat exchanger (101, 102) is in the opposite direction when it becomes a condenser. The method according to claim 1,
The switching mechanism 200 is configured such that the flow direction of the air passing through each of the first and second adsorption heat exchangers 101 and 102 is changed in the case where the adsorption heat exchangers 101 and 102 serve as an evaporator, And the flow of the air is switched so that the heat exchangers (101, 102) become the same direction when they serve as condensers. The method according to any one of claims 1 to 3,
The first adsorption block 301 and the second adsorption block 302 are respectively disposed at intervals from the first adsorption heat exchanger 101 and the second adsorption heat exchanger 102
Wherein the dehumidifying device is a dehumidifying device. The method according to any one of claims 1 to 3,
The first and second adsorption blocks 301 and 302 are disposed so as to be in contact with the first and second adsorption heat exchangers 101 and 102, respectively
Wherein the dehumidifying device is a dehumidifying device. A dehumidifying device (10) according to claim 2,
And a heater (21) for heating the air for regenerating the adsorbent,
The switching mechanism 200 is configured to pass the heater 21 to the heat exchange chambers S12 and S11 provided with the adsorption heat exchangers 102 and 101 as the condensers in the first and second heat exchange rooms S11 and S12 To allow one air to flow, to switch the flow of air
Wherein the dehumidifying system is a dehumidifying system. The method of claim 6,
The air having passed through the heat exchange chambers S11 and S12 in which the adsorbent is carried and the adsorption heat exchangers 101 and 102 serving as evaporators in the first and second heat exchange rooms S11 and S12 are provided is brought into contact with the adsorbent, And an adsorption rotor 70 having a regeneration section 72 for regenerating the adsorbent by bringing air that has passed through the heater 21 into contact with the adsorbent,
The air that has passed through the heat exchange chambers S11 and S12 provided with the adsorption heat exchangers 101 and 102 which serve as evaporators in the first and second heat exchange rooms S11 and S12 is supplied to the adsorption portion 71 and supplied to the humidity control space S0,
The switching mechanism 200 is connected to the heat exchanger S12 or S11 provided with the adsorption heat exchanger 102 or 101 serving as a condenser of the first and second heat exchange rooms S11 and S12, The flow of air is switched so that air passing through the regeneration section 72 of the adsorption rotor 70 in turn flows
Wherein the dehumidifying system is a dehumidifying system.

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