JP3785753B2 - Air conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
    The present invention relates to an air conditioner in which humidity adjustment and temperature adjustment are performed with a liquid absorbent.
[0002]
[Prior art]
    Conventionally, some humidity control apparatuses include an absorbent circuit in which a liquid absorbent made of an aqueous lithium chloride circuit circulates as disclosed in JP-A-5-146627. The absorbent circuit is configured by connecting a dehumidifying unit and a regenerating unit via a communication unit, and the dehumidifying unit is configured such that indoor air and the liquid absorbent exchange moisture through a moisture permeable membrane. On the other hand, the regeneration unit is configured such that outdoor air and the liquid absorbent exchange water vapor via a moisture permeable membrane.
[0003]
    As shown in FIG. 21, the dehumidifying operation of the dehumidifying device is performed in the dehumidifying section between the room air at point A2 and the liquid absorbent at points C2 to D2. That is, when the liquid absorbent of high concentration is cooled by room air and the water vapor partial pressure (saturated vapor pressure) drops to the point C2, the water vapor partial pressure of the room air increases, and the water (water vapor) of the room air is increased. Absorbed by the liquid absorbent, the liquid absorbent becomes a low concentration liquid absorbent.
[0004]
    On the other hand, in the regeneration of the liquid absorbent, in the regeneration section, the liquid absorbent at points E2 to F2 releases moisture (water vapor) to the outdoor air at point B2. That is, the low concentration liquid absorbent (D2) that has absorbed the water is heated by the outdoor air, and when the water vapor partial pressure (saturated vapor pressure) rises to the E2 point, the water vapor partial pressure of the outdoor air decreases, and the liquid The moisture (water vapor) of the absorbent is released to the outdoor air, and the liquid absorbent is regenerated into a high concentration liquid absorbent at F2.
[0005]
    The high-concentration liquid absorbent moves to the dehumidifying unit again as described above, is cooled to the point C2, absorbs moisture in the room air, and repeats this circulation operation to dehumidify the room.
[0006]
    Further, in the above dehumidifying apparatus, there is an apparatus in which an evaporator and a condenser are provided in the communication part. The dehumidifying device cools the liquid absorbent flowing to the dehumidifying part by the evaporator, and heats the liquid absorbent flowing to the regenerating part by the condenser. As a result, the water vapor partial pressure of the liquid absorbent is reliably lowered and raised, that is, the liquid absorbent is reliably lowered to the point C2 shown in FIG. 21, while it is reliably raised to the point E2 to absorb and release moisture. Is surely done.
[0007]
[Problems to be solved by the invention]
    However, in the above-described dehumidifying device, only indoor humidity adjustment is performed, and thus there is a problem that a temperature control device such as an air conditioner must be separately installed in order to perform temperature adjustment. .
[0008]
    Specifically, as shown in FIG. 21, the conventional dehumidifying device exhibits the intended dehumidifying function if water vapor is exchanged between the liquid absorbent and room air or outdoor air. The liquid absorbent is merely cooled and heated so that the water vapor partial pressure (saturated vapor pressure) becomes the predetermined values C2 and E2.
[0009]
    Therefore, the conventional dehumidifying device cannot cool indoor air, for example, and in order to cool indoors, it is necessary to install a cooling device separately, especially in a dehumidifying device provided with an evaporator. However, since the liquid absorbent does not change the sensible heat so much, it is necessary to install a cooling device separately.
[0010]
    As a result, when performing air conditioning that regulates indoor temperature and humidity, a dehumidifying device and a temperature control device must be installed, requiring a large installation space and operating two devices. Therefore, there is a problem that not only the equipment cost but also the running cost becomes high.
[0011]
    The present invention has been made in view of such points, and aims to reduce the installation cost and the running cost while reducing the installation space by performing temperature adjustment and humidity adjustment with a liquid absorbent. It is what.
[0012]
[Means for Solving the Problems]
        -Summary of invention-
    The present invention relates to an indoor exchanger (21) for transferring water vapor between indoor air and a liquid absorbent through a moisture permeable membrane, and a water vapor via a moisture permeable membrane between outdoor air and a liquid absorbent. An absorbent circuit (20) provided with an outdoor exchanger (22) for delivering and receiving is provided. In addition, a heat source circuit (30) is provided that includes a heat source heat exchanger (35) and a regeneration heat exchanger (33) for exchanging heat with the liquid absorbent and in which the refrigerant circulates. The heat source heat exchanger (35) changes the sensible heat of the liquid absorbent so that the liquid absorbent exchanges heat with room air to generate temperature-conditioned air, and adjusts the humidity and temperature with the liquid absorbent. Adjustment and the lineYeah.
[0013]
        -Solution-
    concreteToThe means taken by the invention according to claim 1 is configured as a closed circuit in which a liquid absorbent is filled and the liquid absorbent circulates, and a moisture permeable membrane between the first air and the liquid absorbent. A first exchanger (21) that exchanges water vapor through the second air exchanger, and a second exchanger (22) that exchanges water vapor through the moisture permeable membrane between the second air and the liquid absorbent, An absorbent circuit (20) is provided in which the first exchanger (21) and the second exchanger (22) are connected by a circulation passage (24). In addition, the liquid absorbent is provided in the circulation passage (24) on the upstream side of the first exchanger (21) so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned air. A heat source side heat exchanger (35) for changing the sensible heat is provided.
[0014]
    Further, the first exchanger ( twenty one ) Is a humidity exchanger that adjusts the humidity of the first air by transferring water vapor between the first air and the liquid absorbent ( 21-h ), And a sensible heat exchanger that adjusts the temperature of the first air by heat exchange between the first air and the liquid absorbent ( 21-t ) And more.
[0015]
    In the invention according to the first aspect, the liquid absorbent circulates in the absorbent circuit (20), and the liquid absorbent is cooled by, for example, the heat source side heat exchanger (35). It flows to the first exchanger (21) as a high-concentration liquid absorbent that has undergone a significant sensible heat change and has a low water vapor partial pressure (saturated vapor pressure), and exchanges heat with the first air. While cooling, it absorbs the moisture of the first air and becomes a low concentration liquid absorbent.
[0016]
    Thereafter, the low-concentration liquid absorbent is, for example, a high-concentration liquid that releases water to the second air from a state in which the water vapor partial pressure (saturated vapor pressure) is increased in the second exchanger (22) at a high temperature. Regenerates as an absorbent. The regenerated high-concentration liquid absorbent flows again to the heat source side heat exchanger (35) and repeats the above operation to adjust the humidity of the first air and the temperature of the first air.The
[0017]
    MoreSince the humidity adjustment and the temperature adjustment of the first air are individually performed by the humidity exchanger (21-h) and the sensible heat exchanger (21-t), a large-capacity heat transfer is performed.
[0018]
    Claim2The means taken by the described invention is the above claim.1In the described invention, the humidity exchanger (21-h) and the sensible heat exchanger (21-t) are connected in series.
[0019]
    In accordance with the above-mentioned invention specific matters,2In the described invention, the temperature of the first air is adjusted with the sensible heat exchanger (21-t), and then the humidity of the first air is adjusted with the humidity exchanger (21-h).
[0020]
    Claim3The means taken by the described invention is the above claim.1In the described invention, the humidity exchanger (21-h) and the sensible heat exchanger (21-t) are connected in parallel.
[0021]
    In accordance with the above-mentioned invention specific matters,3In the described invention, since the humidity adjustment and the temperature adjustment of the first air are performed separately, the humidity capability and the temperature capability can be controlled independently.
[0022]
    Claim4The means taken by the described invention is the above claim.2 or 3In the described invention, the sensible heat exchanger (21-t) is arranged above the humidity exchanger (21-h).
[0023]
    In accordance with the above-mentioned invention specific matters,4In the described invention, the drain generated in the sensible heat exchanger (21-t) is absorbed by the humidity exchanger (21-h).
[0024]
    Claim5The means taken by the invention described above is configured such that the liquid absorbent is controlled to be equal to or higher than the dew point temperature of the first air in the invention described in claim 1 above.
[0025]
    In accordance with the above-mentioned invention specific matters,5In the described invention, condensation in the first exchanger (21) and the circulation passage (24) is suppressed.
[0026]
    Claim6The measures taken by the described invention are:A first exchanger configured to form a closed circuit in which the liquid absorbent is filled and circulates the liquid absorbent, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane ( twenty one ) And a second exchanger that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane ( twenty two ) And the first exchanger ( twenty one ) And the second exchanger ( twenty two ) Is the circulation path ( twenty four Absorbent circuit connected by 20 ) Is provided. In addition, the first exchanger ( twenty one ) Upstream circulation path ( twenty four ), And a heat exchanger for a heat source that changes the sensible heat of the liquid absorbent so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air ( 35 ) Is provided.
[0027]
    Further, the heat source heat exchanger ( 35 ) Is a heat source circuit in which the refrigerant circulates ( 30 ) 1 exchanger ( twenty one The heat exchanger for the first heat source that changes the sensible heat of the liquid absorbent flowing through 35 ), While the above heat source circuit ( 30 ) Includes a second exchanger ( twenty two ) A heat exchanger for the second heat source that exchanges heat with the liquid absorbent flowing in 33 ) Is provided.
[0028]
    Besides, aboveIn the absorbent circuit (20), the bypass passage (26) has a second heat source heat exchanger such that the liquid absorbent bypasses the second heat source heat exchanger (33) and the second exchanger (22). (33) and parallel to the second exchanger (22)PleaseYes.
[0029]
    Claim7The measures taken by the described invention are:A first exchanger configured to form a closed circuit in which the liquid absorbent is filled and circulates the liquid absorbent, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane ( twenty one ) And a second exchanger that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane ( twenty two ) And the first exchanger ( twenty one ) And the second exchanger ( twenty two ) Is the circulation path ( twenty four Absorbent circuit connected by 20 ) Is provided. In addition, the first exchanger ( twenty one ) Upstream circulation path ( twenty four ), And a heat exchanger for a heat source that changes the sensible heat of the liquid absorbent so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air ( 35 ) Is provided.
[0030]
    Further, the heat source heat exchanger ( 35 ) Is a heat source circuit in which the refrigerant circulates ( 30 ), And changes the sensible heat of the liquid absorbent by the amount of heat of the refrigerant while the heat source circuit ( 30 ) Includes an air heat exchanger that exchanges heat with the second air ( 37 ) Is provided.
[0031]
    Besides, aboveIn the absorbent circuit (20), a bypass passage (26) is provided in parallel to the second exchanger (22) so that the liquid absorbent bypasses the second exchanger (22).PleaseYes.
[0032]
    The means taken by the invention according to claim 8 is the heat exchanger for heat source in the invention according to claim 7. 35 ) Is the first exchanger ( twenty one ) Heat exchanger for the first heat source that changes the sensible heat of the liquid absorbent flowing in 35 ), While the heat source circuit ( 30 ) Includes a second exchanger ( twenty two ) A heat exchanger for the second heat source that exchanges heat with the liquid absorbent flowing in 33 ) Is provided.
[0033]
    Claim9The measures taken by the described invention are:A first exchanger configured to form a closed circuit in which the liquid absorbent is filled and circulates the liquid absorbent, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane ( twenty one ) And a second exchanger that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane ( twenty two ) And the first exchanger ( twenty one ) And the second exchanger ( twenty two ) Is the circulation path ( twenty four Absorbent circuit connected by 20 ) Is provided. In addition, the first exchanger ( twenty one ) Upstream circulation path ( twenty four ), And a heat exchanger for a heat source that changes the sensible heat of the liquid absorbent so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air ( 35 ) Is provided.
[0034]
    Further, the heat source heat exchanger ( 35 ) Is a heat source circuit in which the refrigerant circulates ( 30 ) And the first exchanger ( twenty one The heat exchanger for the first heat source that changes the sensible heat of the liquid absorbent flowing through 35 ), While the above heat source circuit ( 30 ) Includes a second exchanger ( twenty two ) A heat exchanger for the second heat source that exchanges heat with the liquid absorbent flowing in 33 ) Is provided.
[0035]
    In addition, the absorbent circuit ( 20 ) Includes a second exchanger ( twenty two ) Heat recovery heat exchanger that recovers heat from the liquid absorbent that flows out ( twenty five ) Is provided,The bypass passage (26) is connected to the heat recovery heat exchanger (25 so that the liquid absorbent bypasses the heat recovery heat exchanger (25), the second heat source heat exchanger (33), and the second exchanger (22). ) And the second heat source heat exchanger (33) and the second exchanger (22).PleaseYes.
[0036]
    In accordance with the above-mentioned invention specific matters,6. Claim 7as well asClaim 9In the described invention, when only the temperature adjustment of the first air by the sensible heat change of the liquid absorbent is performed, the liquid absorbent flows through the bypass passage (26) without circulating through the second exchanger (22), and circulates. Efficiency is improved.
[0037]
    Further, it is possible to adjust so that only the circulation amount of the liquid absorbent necessary for adjusting the humidity in the first exchanger (21) flows through the second exchanger (22).
[0038]
    In the invention according to claim 8, the heat source circuit ( 30 ) Will circulate through the first heat source side heat exchanger ( 35 ) Is the heat quantity of the second heat source ( 33 ) Will dissipate heat.
[0039]
    Claim10The measures taken by the described invention are:A first exchanger configured to form a closed circuit in which the liquid absorbent is filled and circulates the liquid absorbent, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane ( twenty one ) And a second exchanger that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane ( twenty two ) And the first exchanger ( twenty one ) And the second exchanger ( twenty two ) Is the circulation path ( twenty four Absorbent circuit connected by 20 ) Is provided. In addition, the first exchanger ( twenty one ) Upstream circulation path ( twenty four ), And a heat exchanger for a heat source that changes the sensible heat of the liquid absorbent so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air ( 35 ) Is provided.
[0040]
    Furthermore, the absorbent circuit ( 20 ) Includes a water supply means for supplying make-up water to the liquid absorbent ( 40 ) Connected and aboveThe water supply means (40) includes a replenishment humidity exchanger (44) provided in the absorbent circuit (20) and supplying makeup water through the moisture permeable membrane (4b).YeahYes.
[0041]
    In accordance with the above-mentioned invention specific matters,10In the described invention,Compared to the case where the liquid absorbent absorbs water vapor from the second air, water supply means ( 40 ) Water vapor will be supplied more reliably. In addition,The liquid absorbent will absorb makeup water through the moisture permeable membrane (4b).
[0042]
    Claim11The means taken by the described invention is the above claim.10In the described invention, the water supply means (40) includes a heating means (45) for heating the makeup water.
[0043]
    In accordance with the above-mentioned invention specific matters,11In the described invention, since the temperature of the makeup water becomes high, the liquid absorbent easily absorbs the makeup water.
[0044]
    Claim12The means taken by the described invention is the above claim.11In the described invention, the heating means (45) is configured to heat makeup water with a liquid absorbent.
[0045]
    In accordance with the above-mentioned invention specific matters,12In the described invention, the configuration of the heating means (45) can be simplified.
[0046]
    Claim13The means taken by the described invention is the above claim.12In the described invention, the replenishment humidity exchanger (44) and the heating means (45) are integrally formed.
[0047]
    In accordance with the above-mentioned invention specific matters,13In the described invention, the configuration of the heating means (45) can be further simplified.
[0048]
    Claim14The measures taken by the described invention are:The liquid absorbent is filled and configured in a closed circuit in which the liquid absorbent circulates, and water vapor is passed between the first air and the liquid absorbent through a moisture permeable membrane. The first exchange (providing and receiving) twenty one ) And a second exchanger that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane ( twenty two ) And the first exchanger ( twenty one ) And the second exchanger ( twenty two ) Is the circulation path ( twenty four Absorbent circuit connected by 20 ) Is provided. In addition, the first exchanger ( twenty one ) Upstream circulation path ( twenty four ), And a heat exchanger for a heat source that changes the sensible heat of the liquid absorbent so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air ( 35 ) Is provided. Furthermore, the aboveAbsorbent so that the humidity of the first air falls within the humidity control range determined by the control lower limit value based on the absolute humidity based on the dryness of the mucous membrane in the oral cavity and the control upper limit value based on the relative humidity based on the degree of deterioration of the indoor air quality Controller (50) for controlling humidity adjustment of circuit (20)Is provided.
[0049]
    In accordance with the above-mentioned invention specific matters,14In the described invention, the first air is suppressed from being in a low humidity state as compared to the conventional case, and the high humidity state is suppressed.
[0050]
【The invention's effect】
    Therefore,BookAccording to the invention, the heat source side heat exchanger (35) changes the sensible heat of the liquid absorbent in the absorbent circuit (20) so that the liquid absorbent adjusts the temperature of the first air. Since temperature adjustment and humidity adjustment can be performed simultaneously, for example, cooling and dehumidification can be performed with one apparatus. As a result, it is not necessary to separately install a humidity control device such as a dehumidification device and a temperature control device such as a cooling device as in the prior art, so that the device can be reduced in size and space can be reduced.
[0051]
    In addition, since only one device is operated, not only equipment costs but also running costs can be reduced.The
[0052]
    Also, Claims1According to the described invention, since the first exchanger (21) is composed of the humidity exchanger (21-h) and the sensible heat exchanger, one first exchanger (21) is provided. Compared to the case, a large amount of heat can be transferred efficiently.
[0053]
    Claims2According to the described invention, since the sensible heat exchanger and the humidity exchanger (21-h) are connected in series, the configuration of the absorbent circuit (20) can be prevented from being complicated.
[0054]
    Claims3According to the described invention, since the sensible heat exchanger and the humidity exchanger (21-h) are connected in parallel, the temperature adjustment and humidity adjustment of the indoor air can be controlled independently. The control range can be expanded.
[0055]
    Claims4According to the described invention, since the sensible heat exchanger is arranged above the humidity exchanger (21-h), the drain generated in the sensible heat exchanger is absorbed by the humidity exchanger (21-h). Therefore, it is not necessary to perform the drain process separately, and the configuration can be simplified.
[0056]
    Claims5According to the described invention, since the liquid absorbent is controlled to be equal to or higher than the dew point temperature of the first air, the generation of drain in the first exchanger (21) can be suppressed, and the circulation passage (24) Condensation and the like can be reliably prevented. In other words, the liquid absorbent can absorb moisture even when the temperature is higher than the dew point temperature of the first air, so that it is possible to reduce the cost of measures such as generation of drain and condensation.The
[0057]
    Also, Claims6, 7 and 9According to the described invention, since the bypass circuit (26) is provided in the absorbent circuit (20), when only the sensible heat of the liquid absorbent is used during cooling operation or heating operation, Since there is no need to flow the liquid absorbent to the second exchanger (22), high performance can be achieved.
[0058]
    Further, since the liquid absorbent bypasses the second exchanger (22), only the amount of the liquid absorbent necessary for adjusting the humidity in the first exchanger (21) is the second exchanger ( 22) can be adjusted to flow.
[0059]
    According to the invention of claim 7, the heat source circuit ( 30 ) To air heat exchanger ( 37 ) To provide a heat source circuit ( 30 ) Can be treated with outdoor air, so that the application range can be expanded.
[0060]
    Moreover, according to invention of Claim 9, a 2nd exchanger ( twenty two ) To recover the amount of heat from the liquid absorbent flowing out from the heat source side heat exchanger ( 35 The amount of heat to be cooled or the amount of heat to be heated is reduced, and the operation efficiency can be improved.
[0061]
    Claims10According to the described invention, since the water supply means (40) is connected to the absorbent circuit (20), even when water cannot be absorbed from the second air, the water supply means (40) Since the makeup water is supplied, the humidification operation can be performed reliably.
[0062]
    Moreover, since it is possible to absorb moisture without cooling the liquid absorbent, cooling of the liquid absorbent can be omitted.
[0063]
    Further, for example, since the water supply means (40) can be provided only outdoors, it is not necessary to introduce a water supply system indoors, and the overall configuration can be simplified.
[0064]
    MaThe supplementIn the supply humidity exchanger (44), the liquid absorbent absorbs moisture from the makeup water through the moisture permeable membrane (4b), so that impurities can be prevented from being mixed into the liquid absorbent.
[0065]
    Claims11According to the described invention, since the liquid absorbent is heated by the heating means (45), moisture absorption in the replenishment humidity exchanger (44) can be easily performed. The water supply part of the damp film (4b) can be reduced in area.
[0066]
    Claims12According to the described invention, since the makeup water is heated by the liquid absorbent of the absorbent circuit (20), a separate heating source or the like is not required, so that the circuit configuration can be simplified.
[0067]
    Claims13According to the described invention, since the replenishment humidity exchanger (44) and the heating means (45) are integrally formed, the configuration can be further simplified.
[0068]
    Claims14According to the described invention, the lower limit value of the humidity control is set by the absolute humidity based on the dryness of the mucous membrane in the oral cavity, and the upper limit value of the humidity control is set by the relative humidity based on the degree of deterioration of the indoor air quality. 1 air can be prevented from entering a low humidity state, and the first air can be prevented from entering a high humidity state.
As a result, for example, the indoor air condition can be controlled within a range in which the health of the occupants can be maintained, so that a comfortable indoor environment suitable for health can be realized. That is, it is possible to prevent cold infection and to prevent generation of mold in the room.
[0069]
DETAILED DESCRIPTION OF THE INVENTION
    Hereinafter, embodiments of the present inventionStateThis will be described in detail with reference to the drawings.First, various premise technologies that are the premise of the present invention will be described, and then each embodiment of the present invention will be described.
[0070]
    <Prerequisite technology 1>
    As shown in FIG. 1, the air conditioner (10) includes an absorbent circuit (20) and a heat source circuit (30), and is configured to perform temperature adjustment and humidity adjustment.
[0071]
    In the absorbent circuit (20), an indoor exchanger (21), an outdoor exchanger (22), and a circulation pump (23) are configured in a closed circuit by a circulation passage (24). The absorbent circuit (20) is configured to be filled with a liquid absorbent such as an aqueous lithium chloride solution, and the liquid absorbent is circulated by a circulation pump (23).
[0072]
    The indoor exchanger (21) is a first exchanger that is installed indoors and air-conditions the room, and includes a moisture permeable membrane such as a porous hydrophobic polymer membrane (not shown). The moisture permeable membrane prevents passage of water but allows passage of water vapor (moisture), and is provided at a portion where the liquid absorbent and room air are in contact with each other. The indoor exchanger (21) is configured such that the liquid absorbent exchanges water vapor with indoor air, which is the first air, via a moisture permeable membrane.
[0073]
    The outdoor exchanger (22) constitutes a second exchanger as a regenerator that is installed outside and regenerates the liquid absorbent. Although not shown, the outdoor exchanger (22) is porous and hydrophobic like the indoor exchanger (21). A moisture permeable membrane such as a conductive polymer membrane is provided. The moisture permeable membrane is provided in a portion where the liquid absorbent and the outdoor air are in contact with each other, and the outdoor exchanger (22) is configured such that the liquid absorbent is the second air through the moisture permeable membrane. It is configured to give and receive.
[0074]
    The heat source circuit (30) is constituted by a vapor compression refrigeration cycle filled with a refrigerant and circulated through the refrigerant, and is configured to change the sensible heat of the liquid absorbent in the absorbent circuit (20). The heat source circuit (30) includes a compressor (31), a four-way switching valve (32), a regeneration heat exchanger (33), an expansion valve (34), and a heat source heat exchanger (35) in order of refrigerant piping. (36) connected to form a closed circuit, and the refrigerant circulation direction is reversible.
[0075]
    The regeneration heat exchanger (33) is disposed in the circulation passage (24) on the upstream side of the outdoor exchanger (22) in the absorbent circuit (20), and is a second heat source for exchanging heat between the liquid absorbent and the refrigerant. A heat exchanger is constructed. The regeneration heat exchanger (33) functions as a condenser that condenses the refrigerant when the outdoor exchanger (22) releases the moisture of the liquid absorbent, and the liquid absorbent that flows to the outdoor exchanger (22) It is configured to heat. On the other hand, the outdoor heat exchanger (33) functions as an evaporator that evaporates the refrigerant when the outdoor exchanger (22) absorbs moisture into the liquid absorbent, and absorbs the liquid flowing in the outdoor exchanger (22). It is configured to cool the agent.
[0076]
    The heat source heat exchanger (35) is disposed in the circulation passage (24) on the upstream side of the indoor exchanger (21) in the absorbent circuit (20), and the first heat source exchanges heat between the liquid absorbent and the refrigerant. A heat exchanger is constructed. The heat source heat exchanger (35) functions as an evaporator in which the refrigerant evaporates when the indoor exchanger (21) absorbs moisture into the liquid absorbent, and the liquid absorbent flowing into the indoor exchanger (21) It is configured to cool. On the other hand, the heat source heat exchanger (35) functions as a condenser that condenses the refrigerant when the indoor exchanger (21) releases the moisture of the liquid absorbent, and absorbs the liquid flowing into the indoor exchanger (21). It is comprised so that an agent may be heated.
[0077]
    In particular, the heat exchanger for heat source (35) is characterized in that, as a feature of the present invention, a liquid absorbent is used so that the indoor exchanger (21) performs not only the humidity adjustment operation for adjusting the humidity in the room but also the temperature adjustment operation. The heat exchanger is configured to change the sensible heat, that is, to change the sensible heat of the liquid absorbent so as to generate conditioned air whose temperature is adjusted by exchanging heat with the indoor air in the indoor exchanger (21). ing.
[0078]
    On the other hand, the regeneration heat exchanger (33) is a liquid absorbent of the refrigerant and the absorbent circuit (20) so that the heat balance of the heat source circuit (30) is maintained with respect to the heat source heat exchanger (35). And are configured to exchange heat.
[0079]
    The capacity of the heat source heat exchanger (35) of the heat source circuit (30) is controlled so that the temperature of the liquid absorbent in the absorbent circuit (20) is always equal to or higher than the dew point temperature of the room air. .
[0080]
        -Air conditioning operation-
    Next, the air conditioning operation of the air conditioner (10) will be described.
[0081]
     [Cooling and dehumidifying operation]
    First, when performing the cooling and dehumidifying operation, in the heat source circuit (30), the four-way switching valve (32) is switched to the solid line side in FIG. 1, and the high-temperature high-pressure refrigerant discharged from the compressor (31) is regenerated heat. The liquid absorbent is heated and condensed in the exchanger (33). Thereafter, the condensed refrigerant is depressurized by the expansion valve (34) and flows to the heat source heat exchanger (35). The liquid absorbent is cooled and evaporated by the heat source heat exchanger (35), and the compressor (31 Go back to).
[0082]
    On the other hand, in the absorbent circuit (20), the circulation pump (23) is driven to circulate the liquid absorbent. The liquid absorbent is cooled by the refrigerant of the heat source circuit (30) in the heat exchanger for heat source (35), and is used as an indoor exchanger as a high-concentration liquid absorbent having a low temperature and a reduced water vapor partial pressure (saturated vapor pressure). It flows to (21). The liquid absorbent cools the room air by exchanging heat with the room air, and absorbs moisture from the room air to become a low concentration liquid absorbent.
[0083]
    Thereafter, the low concentration liquid absorbent is heated by the refrigerant in the heat source circuit (30) in the regeneration heat exchanger (33), and is used outdoors as a liquid absorbent whose temperature is high and the water vapor partial pressure (saturated vapor pressure) is increased. Flows to exchanger (22). The liquid absorbent exchanges heat with the outdoor air to radiate heat to the outdoor air, and releases moisture to the outdoor air to regenerate as a high-concentration liquid absorbent.
[0084]
    This regenerated high-concentration liquid absorbent flows again into the heat source heat exchanger (35) and repeats the above operation to dehumidify the room and cool the room. The liquid absorbent is controlled so as to constantly circulate above the dew point temperature of the room air.
[0085]
    Therefore, the state change of the liquid absorbent will be described in detail. As shown in FIG. 2, in the indoor exchanger (21), dehumidification is performed between the indoor air at point A1 and the liquid absorbent at points C1 to D1. Cooling takes place. That is, the high concentration liquid absorbent is cooled by the refrigerant of the heat source circuit (30) in the heat source heat exchanger (35), and the water vapor partial pressure (saturated vapor pressure) is lowered to the C1 point. The liquid absorbent at point C1 is greatly sensible heat-cooled as it is cooled to a lower temperature than the conventional liquid absorbent shown in FIG.
[0086]
    Since the liquid absorbent at point C1 has a high temperature of room air, the room air is cooled by exchanging heat with room air, and the water vapor partial pressure of the room air is large. Sensible heat changes to a low concentration liquid absorbent.
[0087]
    On the other hand, in the outdoor exchanger (22), regeneration is performed between the outdoor air at point B1 and the liquid absorbent at points E1 to F1. That is, the low-concentration liquid absorbent that has absorbed the moisture is heated by the refrigerant in the heat source circuit (30) in the regeneration heat exchanger (33), and the water vapor partial pressure (saturated vapor pressure) rises to point E1. . The liquid absorbent at point E1 is heated to a high temperature and significantly changes in sensible heat as compared with the conventional liquid absorbent shown in FIG.
[0088]
    Since the temperature of the outdoor air is low, the E1 point liquid absorbent radiates heat to the outdoor air, and the water vapor partial pressure of the outdoor air is small. To be played.
[0089]
    Then, as described above, this high concentration liquid absorbent moves to the heat source heat exchanger (35) again, is cooled to the point C1, absorbs the heat and moisture of the room air, and repeats this circulation operation. Cool and dehumidify the room.
[0090]
     [Dehumidifying operation]
    When performing only the dehumidifying operation, the capacity of the heat source circuit (30) is reduced as compared with the cooling and dehumidifying operation described above, and the evaporation capacity of the heat source heat exchanger (35) and the condensation of the regeneration heat exchanger (33) are reduced. Reduce capacity. As a result, the liquid absorbent has a small sensible heat change, and only the moisture is absorbed by the indoor exchanger (21) by raising and lowering the partial pressure of water vapor, while only the moisture is released by the outdoor exchanger (22). Circulate.
[0091]
     [Heating and humidifying operation]
    When the heating / humidifying operation is performed, an operation opposite to the cooling / dehumidifying operation is performed. First, in the heat source circuit (30), the four-way selector valve (32) switches to the broken line side in FIG. 1, and the high-temperature high-pressure refrigerant discharged from the compressor (31) is liquidated in the heat source heat exchanger (35). The absorbent is heated to condense. Thereafter, the condensed refrigerant is depressurized by the expansion valve (34) and flows to the regeneration heat exchanger (33). The regeneration heat exchanger (33) cools and evaporates the liquid absorbent, and the compressor (31 Go back to).
[0092]
    On the other hand, the liquid absorbent in the absorbent circuit (20) is heated by the refrigerant of the heat source circuit (30) in the heat exchanger for heat source (35), and is a low concentration liquid absorbent whose water vapor partial pressure is increased. To the indoor exchanger (21). The liquid absorbent exchanges heat with room air to heat the room air and releases moisture into the room air to become a high concentration liquid absorbent.
[0093]
    Thereafter, the high-concentration liquid absorbent is cooled by the refrigerant in the heat source circuit (30) in the regeneration heat exchanger (33), and the outdoor exchanger (22) as a liquid absorbent having a low temperature and a reduced water vapor partial pressure. Flowing into. The liquid absorbent cools the outdoor air by exchanging heat with the outdoor air, and absorbs moisture from the outdoor air to be regenerated as a low-concentration liquid absorbent.
[0094]
    The regenerated low-concentration liquid absorbent flows again into the heat source heat exchanger (35) and repeats the above operation to humidify the room and heat the room.
[0095]
     [Humidification operation]
    When only humidification operation is performed, the capacity of the heat source circuit (30) is reduced compared to the heating and humidification operation described above, the condensation capacity of the heat source heat exchanger (35) and the evaporation of the regeneration heat exchanger (33). Reduce capacity. As a result, the sensible heat change of the liquid absorbent is reduced, and only the moisture is released by the outdoor exchanger (22) while the indoor exchanger (21) only releases moisture by raising and lowering the water vapor partial pressure. Circulate.
[0096]
        −Prerequisite technology1 effect-
    As above, the bookPrerequisite technologyAccording to 1, since the heat exchanger for heat source (35) changes the sensible heat of the liquid absorbent in the absorbent circuit (20) so that the liquid absorbent adjusts the temperature of the room air, Since humidity adjustment can be performed simultaneously, for example, cooling and dehumidification can be performed with one apparatus. As a result, since it is not necessary to separately install a humidity control device such as a dehumidification device and a temperature control device such as a cooling device as in the prior art, the device can be reduced in size and space can be reduced.
[0097]
    Moreover, since only one apparatus is operated, not only the equipment cost but also the running cost can be reduced.
[0098]
    In particular, since one indoor exchanger (21) performs the humidity control operation and the temperature control operation, the configuration can be simplified.
[0099]
    Further, since the liquid absorbent is controlled to be equal to or higher than the dew point temperature of the indoor air, it is possible to suppress the generation of drain in the indoor exchanger (21) and to reliably prevent the dew condensation in the circulation passage (24). be able to. That is, since the liquid absorbent can absorb moisture even when the temperature is higher than the dew point temperature of the room air, it is possible to reduce the cost of measures such as generation of drain and condensation.
[0100]
    <Prerequisite technology 2>
    Next, another prerequisite technique 2 of the present invention will be described. Basic technologyAs shown in FIG.Prerequisite technologyInstead of having one indoor exchanger (21), 1 is a multi-type having a plurality of indoor exchangers (21). FIG. 3 shows a case where three indoor exchangers (21) are provided.
[0101]
    That is, the indoor side of the circulation passage (24) in the absorbent circuit (20) is branched into three, and the three indoor exchangers (21) are connected in parallel to each other. An open / close valve (SV) is provided in the circulation passage (24) on the upstream side of the indoor exchanger (21).
[0102]
    Therefore,Prerequisite technologyThe on-off valve (SV) is opened corresponding to the indoor exchanger (21) that performs the cooling dehumidification and heating humidification, and the plurality of indoor exchangers (21) perform the cooling dehumidification and heating humidification.
[0103]
    As a result, the effect of reducing the space when performing both cooling and heating and dehumidification / dehumidification of room air can be exhibited more remarkably. Other configurations, functions and effects are as described above.Prerequisite technologySame as 1.
[0104]
    <Embodiment 1>
    Next, Embodiment 1 of the present invention will be described.In the present embodiment, as shown in FIG.Prerequisite technology1 is provided with a sensible heat exchanger (21-t) and a humidity exchanger (21-h) instead of providing one indoor exchanger (21).
[0105]
    That is, the sensible heat exchanger (21-t) and the humidity exchanger (21-h) are connected in series to form the indoor exchanger (21) as the first exchanger, and the sensible heat An exchanger (21-t) is arranged upstream of the flow of liquid absorbent from the humidity exchanger (21-h). The sensible heat exchanger (21-t) is configured to perform only a temperature control operation for adjusting the temperature by exchanging heat between the liquid absorbent and the room air, while the humidity exchanger (21-t) h) is configured to perform only a humidity control operation for transferring moisture between the liquid absorbent and the room air to adjust the humidity.
[0106]
    The sensible heat exchanger (21-t) is disposed above the humidity exchanger (21-h), and the drain generated in the sensible heat exchanger (21-t) is transferred to the humidity exchanger (21-t). h) to absorb.
[0107]
    Therefore, during cooling and dehumidifying operation, the liquid absorbent cooled in the heat source heat exchanger (35) cools the room air in the sensible heat exchanger (21-t), and then the humidity exchanger (21-h) To absorb the moisture in the room air. During the dehumidifying operation without cooling, the liquid absorbent cooled by the heat source heat exchanger (35) does not substantially exchange heat with room air in the sensible heat exchanger (21-t), and the humidity exchanger ( 21-h) absorbs moisture from room air.
[0108]
    On the other hand, at the time of heating and humidifying operation, after the liquid absorbent heated by the heat source heat exchanger (35) heats the room air by the sensible heat exchanger (21-t), the humidity exchanger (21-h) To release moisture into the room air. During humidification operation without heating, the liquid absorber heated in the heat source heat exchanger (35) does not exchange heat with room air in the sensible heat exchanger (21-t), and the humidity exchanger ( 21-h) releases moisture into the room air.
[0109]
    As a result, it is possible to efficiently transfer a large amount of heat as compared with the case where one indoor exchanger (21) is provided.
[0110]
    In addition, since the sensible heat exchanger (21-t) is arranged above the humidity exchanger (21-h), the drain generated in the sensible heat exchanger (21-t) is removed from the humidity exchanger. Since (21-h) can be absorbed, it is not necessary to perform the drain treatment separately, and the configuration can be simplified.
[0111]
    Further, since the sensible heat exchanger (21-t) and the humidity exchanger (21-h) are connected in series, the configuration of the absorbent circuit (20) can be prevented from being complicated. . Other configurations, functions and effects are as described above.Prerequisite technologySame as 1.
[0112]
    <Embodiment 2>
    Next, Embodiment 2 of the present invention will be described.In the present embodiment, as shown in FIG.1Instead of connecting the sensible heat exchanger (21-t) and the humidity exchanger (21-h) in series, the sensible heat exchanger (21-t) and the humidity exchanger (21-h) ) And connected in parallel.
[0113]
    That is, the indoor side of the circulation passage (24) in the absorbent circuit (20) is branched into two, and the sensible heat exchanger (21-t) and the humidity exchanger (21-h) are connected in parallel. In addition, an open / close valve (SV) is provided on the upstream side of the sensible heat exchanger (21-t) and the humidity exchanger (21-h).
[0114]
    Therefore, when both the indoor air temperature adjustment and humidity adjustment are performed, both the open / close valves (SV, SV) are opened, and the indoor air temperature is adjusted with the sensible heat exchanger (21-t). The humidity is adjusted individually with the humidity exchanger (21-h).
[0115]
    When only adjusting the humidity of the indoor air, close the open / close valve (SV) of the sensible heat exchanger (21-t) and adjust the humidity of the indoor air with the humidity exchanger (21-h) When only adjusting the temperature of the indoor air, the open / close valve (SV) of the humidity exchanger (21-h) is closed and the temperature of the indoor air is adjusted with the sensible heat exchanger (21-t).
[0116]
    As a result, the temperature adjustment and humidity adjustment of the indoor air can be controlled independently, so that the control range can be expanded. Other configurations, operations, and effects are the same as those in the above embodiment.1It is the same.
[0117]
    <Prerequisite technology 3>
    Next, another prerequisite technique 3 of the present invention will be described. Basic technologyAs shown in FIG.Prerequisite technology1 is provided with an air heat exchanger (37) in addition to the regeneration heat exchanger (33) instead of providing the regeneration heat exchanger (33) in the heat source circuit (30). is there.
[0118]
    That is, a bypass pipe (38) that bypasses the regeneration heat exchanger (33) is provided outside the heat source circuit (30), and the air heat exchanger (37) exchanges heat between the refrigerant and outdoor air. The bypass pipe (38) is provided so as to be connected in parallel to the regeneration heat exchanger (33).
[0119]
    On the other hand, the outdoor exchanger (22) of the absorbent circuit (20) is configured as a humidity exchanger that adjusts the humidity of the outdoor air by transferring water vapor between the outdoor air and the liquid absorbent, and heat for temperature adjustment. It is the structure which does not perform exchange. Other configurations arePrerequisite technologySame as 1.
[0120]
        -Air conditioning operation and effects-
    Next, the air conditioning operation will be described. In the heat source circuit (30), during the cooling or dehumidifying operation, the high-temperature high-pressure refrigerant discharged from the compressor (31) exchanges air heat with the regeneration heat exchanger (33). The high-pressure refrigerant flows to the outdoor air in the air heat exchanger (37) and condenses and radiates to the outdoor air, while the regeneration heat exchanger (33) in the absorbent circuit (20) The liquid absorbent is heated to condense.
[0121]
    In the regeneration heat exchanger (33), only the heating for increasing the water vapor partial pressure is performed so that the liquid absorbent releases and regenerates the moisture, and the heat release from the refrigerant is performed by the air heat exchanger. (37). The operation of the heat source heat exchanger (35) of the heat source circuit (30) and the indoor exchanger (21) of the absorbent circuit (20)Prerequisite technologyAs in 1, indoor cooling or dehumidification is performed.
[0122]
    Also, during heating or humidification operation, in the heat source circuit (30), the liquid refrigerant condensed in the heat source heat exchanger (35) and depressurized by the expansion valve (34) is converted into the regeneration heat exchanger (33) and the air. This liquid refrigerant flows into the heat exchanger (37) in a diverted flow, and the liquid refrigerant evaporates by exchanging heat with outdoor air in the air heat exchanger (37), while the absorbent circuit (33) in the regeneration heat exchanger (33) 20) Cool and evaporate the liquid absorbent.
[0123]
    In this regeneration heat exchanger (33), only cooling for lowering the partial pressure of water vapor is performed so that the liquid absorbent absorbs and regenerates the moisture, and the heat absorption of the refrigerant heat quantity is the air heat exchanger. (37). The operation of the heat source heat exchanger (35) of the heat source circuit (30) and the indoor exchanger (21) of the absorbent circuit (20)Prerequisite technologyAs in 1, heating or humidification of room air is performed.
[0124]
    So bookBase technology 3According to the present invention, since the heat source circuit (30) is provided with the air heat exchanger (37) in addition to the regeneration heat exchanger (33), the heat exchange for regeneration of the liquid absorbent in the absorbent circuit (20) As the temperature flowing into the heat exchanger (33) and the heat source heat exchanger (35) can be adjusted, excess heat and insufficient heat in the heat source circuit (30) can be treated with outdoor air, so the applicable range Can be expanded. Other effects are abovePrerequisite technologySame as 1.
[0125]
    <Prerequisite technology 4>
    Next, another prerequisite technique 4 of the present invention will be described. Basic technologyAs shown in FIG.Prerequisite technology1 is provided with an air heat exchanger (37) in place of providing one regeneration heat exchanger (33) in the heat source circuit (30).
[0126]
    That is, an air heat exchanger (37) is provided between the compressor (31), the four-way switching valve (32), and the expansion valve (34) on the outdoor side of the heat source circuit (30). Furthermore, the air heat exchanger (37) is disposed upstream of the outdoor air flowing through the outdoor exchanger (22) with respect to the outdoor exchanger (22) of the absorbent circuit (20), and The outdoor air heated or cooled by the exchanger (37) is configured to flow to the outdoor exchanger (22) of the absorbent circuit (20).
[0127]
    On the other hand, the outdoor exchanger (22) of the absorbent circuit (20) is configured as a humidity exchanger that adjusts the humidity of the outdoor air by transferring water vapor between the outdoor air and the liquid absorbent, and heat for temperature adjustment. It is the structure which does not perform exchange. Other configurations are abovePrerequisite technologySame as 1.
[0128]
        -Air conditioning operation and effects-
    Next, the air conditioning operation will be described. In the heat source circuit (30), during the cooling or dehumidifying operation, the high-temperature high-pressure refrigerant discharged from the compressor (31) dissipates heat to the outdoor air by the air heat exchanger (37). And condense. In the outdoor exchanger (22) of the absorbent circuit (20), the low-temperature and low-concentration liquid absorbent flowing from the indoor exchanger (21) is the hot outdoor air that has been heat-exchanged by the air heat exchanger (37). Is heated to increase the partial pressure of water vapor, and the moisture is released into the outdoor air for regeneration. The operations of the heat source heat exchanger (35) of the heat source circuit (30) and the indoor exchanger (21) of the absorbent circuit (20) are as described above.Prerequisite technologyAs in 1, indoor cooling or dehumidification is performed.
[0129]
    During heating or humidification operation, in the heat source circuit (30), the liquid refrigerant condensed in the heat source heat exchanger (35) and decompressed by the expansion valve (34) flows to the air heat exchanger (37), This liquid refrigerant evaporates by exchanging heat with outdoor air in the air heat exchanger (37). In the outdoor exchanger (22) of the absorbent circuit (20), the high-temperature and high-concentration liquid absorbent flowing from the indoor exchanger (21) is the low-temperature outdoor air that is heat-exchanged by the air heat exchanger (37). The water vapor partial pressure drops as it is cooled down by water, and moisture is absorbed from the outdoor air and regenerated.
[0130]
    The operations of the heat source heat exchanger (35) of the heat source circuit (30) and the indoor exchanger (21) of the absorbent circuit (20) are as described above.Prerequisite technologyAs in 1, heating or humidification of room air is performed.
[0131]
    So bookBase technology 4Since the air heat exchanger (37) is provided in the heat source circuit (30), the circuit configuration of the absorbent circuit (20) can be simplified.
[0132]
    Moreover, since the liquid absorbent of the outdoor exchanger (22) can be heated or cooled by the exhaust heat of the air heat exchanger (37), the regeneration efficiency of the liquid absorbent can be improved. Other effectsPrerequisite technologySame as 1.
[0133]
    <Prerequisite technology 5>
    Next, another prerequisite technique 5 of the present invention will be described. Basic technologyAs shown in FIG.Base technology 3The heat recovery heat exchanger (25) is provided in the absorbent circuit (20). That is, the heat recovery heat exchanger (25) is configured to exchange heat between the liquid absorbent flowing into the regeneration heat exchanger (33) and the liquid absorbent flowing out of the outdoor exchanger (22). Has been.
[0134]
    Therefore, at the time of cooling or dehumidifying operation, the low-temperature liquid absorbent is heated from the indoor exchanger (21) by the regeneration heat exchanger (33) and flows out of the outdoor exchanger (22). The heat of the liquid absorbent flowing out from the outdoor exchanger (22) is recovered by the liquid absorbent flowing into the regeneration heat exchanger (33).
[0135]
    On the other hand, during heating or humidifying operation, the high-temperature liquid absorbent is cooled by the regeneration heat exchanger (33) from the indoor exchanger (21) and flows out of the outdoor exchanger (22). The cold energy of the liquid absorbent flowing out from the outdoor exchanger (22) is recovered by the liquid absorbent flowing into the regeneration heat exchanger (33).
[0136]
    As a result, the amount of heat that is cooled by the heat source heat exchanger (35) and the air heat exchanger (37) or the amount of heat that is heated is reduced, and the operation efficiency can be improved. Other configurations, functions and effects are as described above.Base technology 3It is the same.
[0137]
    <Embodiment 3>
    Next, a third embodiment of the present invention will be described.In the present embodiment, as shown in FIG.Base technology 5A bypass passage (26) is provided on the outdoor side of the absorbent circuit (20).
[0138]
    That is, in the bypass passage (26), the liquid absorbent from the indoor exchanger (21) bypasses the heat recovery heat exchanger (25), the regeneration heat exchanger (33), and the outdoor exchanger (22). And it is comprised so that it may flow into a circulation pump (23). The bypass passage (26) is provided with an open / close valve (SV), and an open / close valve (SV) is provided upstream of the heat recovery heat exchanger (25). Other configurations are described aboveBase technology 5It is the same.
[0139]
        -Air conditioning operation and effects-
    Next, the air conditioning operation will be described. When only the cooling operation and the heating operation are performed without dehumidification and humidification, the heat source heat exchanger (35) of the heat source circuit (30) is connected to the evaporator during the cooling operation. It becomes a condenser during heating operation. On the other hand, in the absorbent circuit (20), the on-off valve (SV) on the upstream side of the heat recovery heat exchanger (25) is closed, the on-off valve (SV) of the bypass passage (26) is opened, and the liquid absorbent Circulates from the indoor exchanger (21) through the bypass passage (26) to the circulation pump (23).
[0140]
    As a result, since the liquid absorbent cooled by the heat source heat exchanger (35) flows in the indoor exchanger (21) in the absorbent circuit (20) during the cooling operation, it exchanges heat with the indoor air. While the indoor air is cooled to cool the room, the liquid absorbent heated by the heat source heat exchanger (35) flows during the heating operation, so heat is exchanged with the room air to heat the room air. Then heat the room.
[0141]
    Further, when only the dehumidifying operation and the humidifying operation are performed without cooling and heating, the heat source heat exchanger (35) is connected to the evaporator and the regeneration heat exchanger (33) during the dehumidifying operation in the heat source circuit (30). ) And air heat exchanger (37) become condensers, and during humidification operation, heat source heat exchanger (35) becomes condenser, regeneration heat exchanger (33) and air heat exchanger (37) Becomes an evaporator. On the other hand, in the absorbent circuit (20), the on-off valve (SV) upstream of the heat recovery heat exchanger (25) is opened, the on-off valve (SV) of the bypass passage (26) is closed, and the liquid absorbent Circulates from the indoor exchanger (21) through the heat recovery heat exchanger (25), the regeneration heat exchanger (33) and the outdoor exchanger (22) to the circulation pump (23).
[0142]
    As a result, during the dehumidifying operation, the indoor exchanger (21) in the absorbent circuit (20) is cooled by the heat exchanger for heat source (35) and the liquid absorbent whose water vapor partial pressure has decreased flows. While absorbing moisture from the air, the liquid absorbent that has been heated by the regeneration heat exchanger (33) to increase the partial pressure of water vapor flows, so that moisture is released into the outdoor air to dehumidify the room.
[0143]
    In addition, during the humidifying operation, the indoor exchanger (21) in the absorbent circuit (20) flows in the room air because the liquid absorbent heated by the heat source heat exchanger (35) and having increased water vapor partial pressure flows. While the water absorbent is released, the liquid absorbent that has been cooled by the regeneration heat exchanger (33) and has a reduced partial pressure of water vapor flows, so moisture is absorbed from the outdoor air to humidify the room.
[0144]
    In addition, when performing the cooling and dehumidifying operation or the heating and humidifying operation, the on-off valve (SV) on the upstream side of the heat recovery heat exchanger (25) and the on-off valve (SV) of the bypass passage (26)
And the liquid absorbent flows together through the outdoor exchanger (22) and the bypass passage (26).
[0145]
    Therefore, this embodiment3According to the present invention, since the bypass passage (26) is provided in the absorbent circuit (20), the liquid absorbent is used when only the sensible heat of the liquid absorbent is used during cooling operation or heating operation. Since it is not necessary to flow through the outdoor exchanger (22), high performance can be achieved.
[0146]
    In addition, since the liquid absorbent bypasses the outdoor exchanger (22), the circulation necessary for adjusting the humidity in the indoor exchanger (21) by controlling the bypass amount of the bypass passage (26). Only an amount of liquid absorbent can be adjusted to flow through the outdoor exchanger (22). Other actions and effects are described above.Base technology 5It is the same.
[0147]
    <Embodiment 4>
    Next, a fourth embodiment of the present invention will be described.In the present embodiment, as shown in FIG.Base technology 4In the above embodiment on the outdoor side of the absorbent circuit (20)3A bypass passage (26) is provided in the same manner as in FIG.
[0148]
    That is, the bypass passage (26) is configured such that the liquid absorbent from the indoor exchanger (21) flows to the circulation pump (23) bypassing the outdoor exchanger (22). The bypass passage (26) is provided with an open / close valve (SV), and an open / close valve (SV) is provided upstream of the outdoor exchanger (22). Other configurations are described aboveBase technology 4It is the same.
[0149]
        -Air conditioning operation and effects-
    Next, the air conditioning operation will be described. When only the cooling operation and the heating operation are performed without dehumidification and humidification, the on-off valve (SV) on the upstream side of the outdoor exchanger (22) is set in the absorbent circuit (20). The on-off valve (SV) of the bypass passage (26) is opened, and the liquid absorbent circulates from the indoor exchanger (21) through the bypass passage (26) to the circulation pump (23).
[0150]
    As a result, since the liquid absorbent cooled by the heat source heat exchanger (35) flows in the indoor exchanger (21) in the absorbent circuit (20) during the cooling operation, the indoor exchanger (21) exchanges heat with the indoor air. While the indoor air is cooled to cool the room, the liquid absorbent heated by the heat source heat exchanger (35) flows during the heating operation, so heat is exchanged with the room air to heat the room air. Then heat the room.
[0151]
    When only dehumidifying operation and humidifying operation are performed without cooling and heating, the on-off valve (SV) on the upstream side of the outdoor exchanger (22) is opened in the absorbent circuit (20), and the bypass passage (26 ) Is closed and the liquid absorbent circulates from the indoor exchanger (21) through the outdoor exchanger (22) to the circulation pump (23).Base technology 4Works as well.
[0152]
    In addition, when performing the cooling and dehumidifying operation and the heating and humidifying operation, both the on-off valve (SV) on the upstream side of the outdoor exchanger (22) and the on-off valve (SV) of the bypass passage (26) Open and allow liquid absorbent to flow through the outdoor exchanger (22) and the bypass passage (26) together.
[0153]
    Therefore, this embodiment4According to the present invention, since the bypass passage (26) is provided in the absorbent circuit (20), the liquid absorbent is used when only the sensible heat of the liquid absorbent is used during cooling operation or heating operation. Since it is not necessary to flow through the outdoor exchanger (22), high performance can be achieved. Other actions and effects are described above.Base technology 4It is the same.
[0154]
    <Embodiment 5>
    Next, a fifth embodiment of the present invention will be described.In the present embodiment, as shown in FIG.4On the outside of the absorbent circuit (20)Base technology 5And a heat recovery heat exchanger (25). That is, the heat recovery heat exchanger (25) is configured to exchange heat between the liquid absorbent flowing into the outdoor exchanger (22) and the liquid absorbent flowing out of the outdoor exchanger (22). ing.
[0155]
    Accordingly, during the dehumidifying operation, the low-temperature liquid absorbent is heated from the indoor exchanger (21) by the outdoor exchanger (22) and flows out of the outdoor exchanger (22). The warm heat of the liquid absorbent flowing out from (22) is recovered by the liquid absorbent flowing into the outdoor exchanger (22).
[0156]
    On the other hand, during humidification operation, the high-temperature liquid absorbent is cooled by the outdoor exchanger (22) from the indoor exchanger (21) and flows out of the outdoor exchanger (22). The cold heat of the liquid absorbent flowing out from (22) is recovered by the liquid absorbent flowing into the outdoor exchanger (22).
[0157]
    As a result, the amount of heat that is cooled by the heat source heat exchanger (35) and the air heat exchanger (37) or the amount of heat that is heated is reduced, and the operation efficiency can be improved. Other configurations, operations, and effects are the same as those in the above embodiment.4It is the same.
[0158]
    <Prerequisite technology 6>
    Next, another prerequisite technique 6 of the present invention will be described. Basic technologyAs shown in FIG.5The water supply means (40) is connected to the absorbent circuit (20). In addition, the outdoor exchanger (22) of FIG. 12 shows only the relationship of piping connection, and the above embodiment5As shown in FIG. 11, the outdoor exchanger (22) is disposed on the downstream side of the air in the air heat exchanger (37).
[0159]
    The water supply means (40) supplies supply water directly to the absorbent circuit (20), and includes a water supply tank (41) that stores the supply water, and the water supply tank (41) includes the absorbent. Water supply having a water supply valve (WV) in the water supply tank (41) while being connected to a circulation passage (24) on the suction side of the circulation pump (23) in the circuit (20) via a water supply pipe (42) System (43) is connected. Other configurations are the same as those in the above embodiment.5It is the same.
[0160]
        -Air conditioning operation and effects-
    Next, the air conditioning operation will be described. During the cooling and dehumidifying operation, the liquid absorbent is cooled by the heat source heat exchanger (35) and absorbs the moisture in the indoor air by the indoor exchanger (21). In the outdoor exchanger (22), the liquid absorbent is heated by the outdoor air heated by the air heat exchanger (37), and moisture is released to the outdoor air. In this cooling and dehumidifying operation, no makeup water is supplied to the water supply tank (41), and no water is supplied from the water supply means (40) to the liquid absorbent.
[0161]
    On the other hand, during the heating and humidifying operation and during the humidifying operation, the liquid absorbent is heated by the heat source heat exchanger (35) and releases moisture to the indoor air by the indoor exchanger (21), and the outdoor exchanger (22). Then, it is cooled by outdoor air and absorbs moisture from the outdoor air. In this case, even if the temperature of the outdoor air is low and moisture cannot be absorbed from the outdoor air, makeup water is supplied to the water supply tank (41), and the liquid absorbent is supplied from the water supply means (40). Moisture is supplied, and moisture is supplied from the indoor exchanger (21) to the room air to humidify the room.
[0162]
    So bookBase technology 6According to the above, even when moisture cannot be absorbed from the outdoor air, the makeup water is supplied by the water supply means (40), so that the humidification operation can be reliably performed.
[0163]
    Moreover, since it is possible to absorb moisture without cooling the liquid absorbent, cooling of the liquid absorbent can be omitted.
[0164]
    Further, since the water supply means (40) can be provided only outdoors, it is not necessary to introduce the water supply system (43) indoors, and the overall configuration can be simplified. Other functions and effects are the same as those of the above embodiment.5It is the same.
[0165]
    <Embodiment 6>
    Next, a sixth embodiment of the present invention will be described.In the present embodiment, as shown in FIG.Base technology 6Instead of supplying the replenishing water directly to the absorbent circuit (20) by the water supply means (40), a replenishment humidity exchanger (44) is provided.
[0166]
    That is, a replenishment humidity exchanger (44) is provided between the circulation pump (23) and the heat source heat exchanger (35) in the absorbent circuit (20), while the replenishment humidity exchanger (44 ) Is connected to the water supply pipe (42). The water supply pipe (42) is provided with a water supply valve (WV).
[0167]
    As shown in FIG. 14, the replenishment humidity exchanger (44) includes an outer tube (4a) and a moisture permeable membrane (4b) closed at both ends. The outer tube (4a) has a larger diameter than the circulation passage (24) of the absorbent circuit (20), and ends of the circulation passage (24) are inserted at both ends.
[0168]
    The moisture permeable membrane (4b) is provided in a cylindrical shape inside the outer tube (4a), and is provided across the end of the end of the circulation passage (24). Then, makeup water is supplied from the water supply pipe (42) between the outer tube (4a) and the moisture permeable membrane (4b), and the liquid absorbent flowing inside the moisture permeable membrane (4b) is supplied with moisture from the makeup water. Is configured to absorb.
[0169]
    Furthermore, a heat exchanger (45) for heating makeup water is provided in the middle of the water supply pipe (42). The heating heat exchanger (45) is connected to the refrigerant pipe (36) between the heat source heat exchanger (35) and the expansion valve (34) in the heat source circuit (30) to constitute a heating means. Yes. In the heat source circuit (30), the high-pressure refrigerant that has flowed from the compressor (31) through the heat source heat exchanger (35) heats the makeup water in the heating heat exchanger (45). It is configured to flow to the air heat exchanger (37) through the expansion valve (34).
[0170]
    In FIG. 14, the replenishment humidity exchanger (44) and the water supply tank (41) are connected, and the heating heat exchanger (45) is omitted. Other configurations are described aboveBase technology 6It is the same.
[0171]
        -Air conditioning operation and effects-
    Next, the air conditioning operation will be described. During the heating and humidifying operation and during the humidifying operation, makeup water is supplied to the water supply tank (41), and the makeup water is supplied from the water supply tank (41) to the supplementary humidity exchanger (44). Is supplied. Further, since this makeup water is heated by the heating heat exchanger (45), the liquid absorbent is more moisture than the makeup water through the moisture permeable membrane (4b) in the above humidity exchanger (44). To absorb.
[0172]
    Thereafter, the liquid absorbent that has absorbed moisture is heated by the regeneration heat exchanger (35), and then flows into the indoor exchanger (21). In the indoor exchanger (21), the liquid absorbent absorbs moisture in the room. Release to the air to humidify the room.
[0173]
    Therefore, according to the present embodiment, in the replenishment humidity exchanger (44), the liquid absorbent absorbs moisture from the makeup water through the moisture permeable membrane (4b). Can be prevented.
[0174]
    In addition, since the liquid absorbent is heated by the heating heat exchanger (45), moisture can be easily absorbed in the replenishment humidity exchanger (44). The water supply part of a membrane (4b) can be made into a small area. Other actions and effects are described above.Base technology 6It is the same.
[0175]
    <Embodiment 7>
    Next, a seventh embodiment of the present invention will be described.In the present embodiment, as shown in FIG.6Instead of heating the makeup water (40) by the heat source circuit (30), the makeup water is heated by the liquid absorbent.
[0176]
    That is, between the heat source heat exchanger (35) and the indoor exchanger (21) in the absorbent circuit (20), there is a heating heat exchanger (45) and a replenishment humidity exchanger (44). The replenishment humidity exchanger (44) provided as shown in FIG.6Similarly, the outer tube (4a) and the moisture permeable membrane (4b) are provided.
[0177]
    As shown in FIG. 16, the heating heat exchanger (45) has a double tube heat provided with a cylindrical casing (4c) provided outside the circulation passage (24) of the absorbent circuit (20). The casing (4c) is connected to a water supply pipe (42) and supplied with makeup water, and the casing (4c) is supplied with a supplementary humidity exchanger (44). The external tube (4a) is connected through a water supply pipe (42).
[0178]
    Therefore, while the liquid absorbent heated by the heat source heat exchanger (35) flows through the circulation passage (24) of the heating heat exchanger (45), the casing of the heating heat exchanger (45) ( In 4c), the makeup water is supplied, so the makeup water is heated. The heated make-up water is supplied to the make-up humidity exchanger (44), the liquid absorbent absorbs moisture from the make-up water, and releases the water with the indoor exchanger (21).
[0179]
    As a result, according to this embodiment, the embodiment6As compared with the heat source circuit (30), the circuit configuration can be simplified. Other configurations, operations, and effects are the same as those in the above embodiment.6It is the same.
[0180]
    <Embodiment 8>
    Next, an eighth embodiment of the present invention will be described.In the present embodiment, as shown in FIG.7Water supply means (40) instead of forming a heat exchanger (45) for heating and a humidity exchanger (44) for replenishment separately, and replacing the heat exchanger for heating (45) and replenishment humidity It is integrally formed with the vessel (44).
[0181]
    That is, as shown in FIG. 18, the external tube (4a) of the replenishment humidity exchanger (44) is extended, and both ends of the external tube (4a) are connected to the circulation passage (24) of the absorbent circuit (20). It is connected. Furthermore, a donut plate-like partition plate (4d) is provided at the central portion of the outer tube (4a), and a moisture permeable membrane (between the partition plate (4d) and the circulation passage (24) on one side is provided. 4b) is provided and is configured as a supply humidity exchanger (44).
[0182]
    On the other hand, a heat transfer tube (4e) is spirally housed between the partition plate (4d) and the other circulation passage (24) to constitute a heating heat exchanger (45). One end of the heat transfer pipe (4e) is connected to the water supply pipe (42), and the other end is connected to the replenishment humidity exchanger (44).
[0183]
    Therefore, the makeup water is heated by the liquid absorbent through the heat transfer tube (4e), and the heated makeup water is supplied to the humidity exchanger for replenishment (44). Is absorbed and water is released by the indoor exchanger (21).
[0184]
    As a result, according to this embodiment, the embodiment7The configuration can be further simplified. Other configurations, operations, and effects are the same as those in the above embodiment.7It is the same.
[0185]
    <Embodiment 9>
    Next, a ninth embodiment of the present invention will be described.In this embodiment, as shown in FIG. 19, a controller (50) for controlling the humidity of room air to a predetermined humidity control range is provided.
[0186]
    That is, the controller (50) controls the capacity of the compressor (31) of the heat source circuit (30), the opening of the expansion valve (34), etc., in addition to the circulation pump (23) of the absorbent circuit (20). To control the room temperature and humidity. In particular, the controller (50) sets the control lower limit value as an absolute humidity based on the dryness of the oral mucosa, and sets the control upper limit value as a relative humidity based on the degree of deterioration of the indoor air quality. Specifically, the lower limit is set to 0.0084 kg / kg ′, and the upper limit is set to 55% RH.
[0187]
    Therefore, a specific reason for setting the humidity control range described above will be described based on the air diagram of FIG. In the air diagram of FIG. 20, the horizontal axis represents air temperature, the vertical axis represents absolute humidity, and the thin line represents an isohumidity line of relative humidity.
[0188]
    Conventionally, the range in which the comfort of the occupant is taken into consideration (hereinafter referred to as the comfortable range) is shown in FIG. 20, and the growth of mold caused by ASHRAE, which causes mold growth if the humidity further increases. It is represented by a limit humidity line L1, a skin dry limit humidity line L2 by Ashley, which causes drying of the skin if the humidity is further reduced, and a region surrounded by lines L3 and L4 with constant new effective temperature. This new effective temperature is a thermal environment index that is calculated by modeling the human physiological temperature regulation action, assuming that the thermal environment with the same amount of heat released from the body surface gives the same cold / hot feeling, Adopted and widely used by Ashley.
[0189]
    On the other hand, the present inventor considered that the comfort range described above only considers the comfort of the occupants and does not consider any health aspects. The temperature and humidity are controlled within a range that is also considered (hereinafter referred to as the health range). This healthy range is a hatched area in FIG. 20, that is, the growth limit humidity line L5 of mold by Sugawara et al. It is represented by the region surrounded by the dry limit humidity line L6 of the oral mucosa by Winslow et al. And the new effective temperature constant line L4 that dryness of the oral mucosa occurs.
[0190]
    At this time, the above-described health range is narrower than the conventional comfortable range, and it is difficult to control the health range by the relative humidity as in the conventional method. The upper limit of the control range is set by relative humidity, and the lower limit is set by absolute humidity, and the indoor environment is controlled to a healthy range. Here, although not shown, the absolute humidity value is calculated from the detected temperature of the room air and the detected humidity value from the temperature sensor and the humidity sensor.
[0191]
    In this embodiment, the upper limit value of the humidity in the health range is set by the mold growth limit humidity line L5 by Sugawara et al., But may be set by the mold growth limit humidity line L1 by Ashley.
[0192]
    Therefore, according to the present embodiment, the lower limit value of humidity control is set as an absolute humidity based on the dryness of the oral mucosa, and the upper limit value of humidity control is set as a relative humidity based on the degree of deterioration of indoor air quality. Thus, it is possible to prevent the indoor humidity from becoming a low humidity state as in the conventional case, and it is possible to prevent the indoor humidity from being in a high humidity state as in the conventional case.
[0193]
    As a result, the indoor air condition can be controlled within a range where the health of the occupants can be maintained, so that a comfortable indoor environment suitable for health can be realized. That is, it is possible to prevent cold infection and to prevent generation of mold in the room.
[0194]
Other Embodiments of the Invention
    Claim1-claim9The described invention may perform only the cooling and dehumidifying operation or the heating and humidifying operation, that is, the heat source circuit (30) does not include the four-way switching valve (32), and the heat source heat exchanger (35 ), The liquid absorbent may be cooled or heated only.
[0195]
    Further, the heat source circuit (30) is not limited to the vapor compression refrigeration cycle, but may be an absorption refrigeration cycle, or may utilize various heat sources such as a boiler.
[Brief description of the drawings]
FIG. 1 of the present inventionPrerequisite technologyIt is a circuit diagram which shows the 1 absorber circuit and heat-source circuit.
FIG. 2 is a characteristic diagram of water vapor partial pressure with respect to the temperature of the liquid absorbent.
FIG. 3 of the present inventionPrerequisite technologyIt is a circuit diagram which shows the 2 absorber circuit and heat source circuit.
FIG. 4 is an embodiment of the present invention.1It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 5 shows an embodiment of the present invention.2It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 6 of the present inventionBase technology 3It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
[Fig. 7] of the present invention.Base technology 4It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
[Fig. 8] of the present inventionBase technology 5It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 9 shows an embodiment of the present invention.3It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 10 shows an embodiment of the present invention.4It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 11 shows an embodiment of the present invention.5It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 12 shows the present invention.Base technology 6It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 13 shows an embodiment of the present invention.6It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 14 is an embodiment.6It is an expanded block diagram which shows the water supply system of.
FIG. 15 shows an embodiment of the present invention.7It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 16 shows an embodiment.7It is an expanded block diagram which shows the water supply system of.
FIG. 17 shows an embodiment of the present invention.8It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 18 shows an embodiment.8It is an expanded block diagram which shows the water supply system of.
FIG. 19 shows an embodiment of the present invention.9It is a circuit diagram which shows an absorbent circuit and a heat source circuit.
FIG. 20 is an air diagram showing a control range of room humidity.
FIG. 21 is a characteristic diagram of water vapor partial pressure with respect to the temperature of a conventional liquid absorbent.
[Explanation of symbols]
10 Air conditioner
20 Absorbent circuit
21 Indoor exchanger (first exchanger)
21-h humidity exchanger
21-t sensible heat exchanger
22 Outdoor exchanger (second exchanger)
24 Circulation passage
25 Heat recovery heat exchanger
26 Bypass passage
30 Heat source circuit
31 Compressor
33 Regenerative heat exchanger (second heat source heat exchanger)
35 Heat exchanger for heat source (heat exchanger for first heat source)
37 Air heat exchanger
40 Water supply means
41 Water tank
44 Humidity exchanger for replenishment
45 Heat exchanger for heating (heating means)
4b Moisture permeable membrane
50 controller

Claims (14)

The first exchanger ( 21 ) is configured as a closed circuit in which the liquid absorbent is filled and the liquid absorbent circulates, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane. ) And a second exchanger ( 22 ) that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane . The first exchanger ( 21 ) and the second exchanger ( 22 ) an absorbent circuit ( 20 ) connected by a circulation passage ( 24 ) ;
The sensible heat of the liquid absorbent is provided in the circulation passage ( 24 ) on the upstream side of the first exchanger ( 21 ) , so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air. A heat exchanger for changing the heat source ( 35 ),
Said first exchanger (21), the humidity exchanger for humidity adjusting the first air by exchanging water vapor between the first air and the liquid absorbent and (21-h), the first air and liquid absorbent And an sensible heat exchanger (21-t) for adjusting the temperature of the first air by exchanging heat with the air conditioner. The air conditioner according to claim 1, wherein
An air conditioner characterized in that the humidity exchanger (21-h) and the sensible heat exchanger (21-t) are connected in series. The air conditioner according to claim 1, wherein
An air conditioner characterized in that the humidity exchanger (21-h) and the sensible heat exchanger (21-t) are connected in parallel. The air conditioner according to claim 2 or 3,
The sensible heat exchanger (21-t) is disposed above the humidity exchanger (21-h). The air conditioner according to claim 1, wherein
The liquid absorbent is controlled to a temperature equal to or higher than the dew point temperature of the first air. The first exchanger ( 21 ) is configured as a closed circuit in which the liquid absorbent is filled and the liquid absorbent circulates, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane. ) And a second exchanger ( 22 ) that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane . The first exchanger ( 21 ) and the second exchanger ( 22 ) an absorbent circuit ( 20 ) connected by a circulation passage ( 24 ) ;
The sensible heat of the liquid absorbent is provided in the circulation passage ( 24 ) on the upstream side of the first exchanger ( 21 ) , so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air. A heat exchanger for changing the heat source ( 35 ),
The heat source heat exchanger ( 35 ) is provided in a heat source circuit ( 30 ) through which the refrigerant circulates, and heat exchange for the first heat source that changes the sensible heat of the liquid absorbent flowing through the first exchanger ( 21 ) by the amount of refrigerant heat. While composed of vessel ( 35 )
The heat source circuit ( 30 ) is provided with a second heat source heat exchanger ( 33 ) that exchanges heat with the liquid absorbent flowing in the second exchanger ( 22 ) to change the sensible heat of the liquid absorbent ,
In the absorbent circuit (20), the bypass passage (26) has a second heat source heat exchange so that the liquid absorbent bypasses the second heat source heat exchanger (33) and the second exchanger (22). An air conditioner provided in parallel with the vessel (33) and the second exchanger (22). The first exchanger ( 21 ) is configured as a closed circuit in which the liquid absorbent is filled and the liquid absorbent circulates, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane. ) And a second exchanger ( 22 ) that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane . The first exchanger ( 21 ) and the second exchanger ( 22 ) an absorbent circuit ( 20 ) connected by a circulation passage ( 24 ) ;
The sensible heat of the liquid absorbent is provided in the circulation passage ( 24 ) on the upstream side of the first exchanger ( 21 ) , so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air. A heat exchanger for changing the heat source ( 35 ),
The heat source heat exchanger ( 35 ) is provided in a heat source circuit ( 30 ) through which the refrigerant circulates , and changes the sensible heat of the liquid absorbent by the amount of refrigerant heat,
The heat source circuit ( 30 ) is provided with an air heat exchanger ( 37 ) for exchanging heat with the second air ,
In the absorbent circuit (20), a bypass passage (26) is provided in parallel to the second exchanger (22) so that the liquid absorbent bypasses the second exchanger (22). An air conditioner characterized. The air conditioner according to claim 7,
Heat exchanger for heat source ( 35 ) Is the first exchanger ( twenty one ) Heat exchanger for the first heat source that changes the sensible heat of the liquid absorbent flowing in 35 )
Heat source circuit ( 30 ) Includes a second exchanger ( twenty two ) A heat exchanger for the second heat source that exchanges heat with the liquid absorbent flowing in the sensible heat to change the sensible heat of the liquid absorbent ( 33 ) Is provided
An air conditioner characterized by that. The first exchanger ( 21 ) is configured as a closed circuit in which the liquid absorbent is filled and the liquid absorbent circulates, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane. ) And a second exchanger ( 22 ) that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane . The first exchanger ( 21 ) and the second exchanger ( 22 ) an absorbent circuit ( 20 ) connected by a circulation passage ( 24 ) ;
The sensible heat of the liquid absorbent is provided in the circulation passage ( 24 ) on the upstream side of the first exchanger ( 21 ) , so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air. A heat exchanger for changing the heat source ( 35 ),
The heat source heat exchanger ( 35 ) is provided in a heat source circuit ( 30 ) through which the refrigerant circulates, and heat exchange for the first heat source that changes the sensible heat of the liquid absorbent flowing through the first exchanger ( 21 ) by the amount of refrigerant heat. While composed of vessel ( 35 )
The heat source circuit ( 30 ) is provided with a second heat source heat exchanger ( 33 ) that exchanges heat with the liquid absorbent flowing in the second exchanger ( 22 ) to change the sensible heat of the liquid absorbent ,
The absorbent circuit ( 20 ) is provided with a heat recovery heat exchanger ( 25 ) for recovering heat from the liquid absorbent flowing out from the second exchanger ( 22 ) , and the liquid absorbent is used as a heat recovery heat exchanger. The bypass passage (26) has a heat recovery heat exchanger (25) and a second heat source heat exchanger so as to bypass the heat exchanger (25), the second heat source heat exchanger (33), and the second exchanger (22). An air conditioner provided in parallel with (33) and the second exchanger (22). The first exchanger ( 21 ) is configured as a closed circuit in which the liquid absorbent is filled and the liquid absorbent circulates, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane. ) And a second exchanger ( 22 ) that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane . The first exchanger ( 21 ) and the second exchanger ( 22 ) an absorbent circuit ( 20 ) connected by a circulation passage ( 24 ) ;
The sensible heat of the liquid absorbent is provided in the circulation passage ( 24 ) on the upstream side of the first exchanger ( 21 ) , so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air. A heat exchanger for changing the heat source ( 35 ),
Connected to the absorbent circuit ( 20 ) is a water supply means ( 40 ) for supplying makeup water to the liquid absorbent ,
The air supply means (40) includes an air supply humidity exchanger (44) provided in the absorbent circuit (20) and supplying makeup water through the moisture permeable membrane (4b). Harmony device. The air conditioning apparatus according to claim 10, wherein
The air conditioner characterized in that the water supply means (40) includes a heating means (45) for heating the makeup water. The air conditioning apparatus according to claim 11, wherein
The air conditioner characterized in that the heating means (45) is configured to heat makeup water with a liquid absorbent. The air conditioning apparatus according to claim 12,
An air conditioner characterized in that the replenishment humidity exchanger (44) and the heating means (45) are integrally formed. The first exchanger ( 21 ) is configured as a closed circuit in which the liquid absorbent is filled and the liquid absorbent circulates, and exchanges water vapor between the first air and the liquid absorbent through a moisture permeable membrane. ) And a second exchanger ( 22 ) that exchanges water vapor between the second air and the liquid absorbent through a moisture permeable membrane . The first exchanger ( 21 ) and the second exchanger ( 22 ) an absorbent circuit ( 20 ) connected by a circulation passage ( 24 ) ;
The sensible heat of the liquid absorbent is provided in the circulation passage ( 24 ) on the upstream side of the first exchanger ( 21 ) , so that the liquid absorbent exchanges heat with the first air to generate temperature-conditioned conditioned air. Heat exchanger for changing heat source ( 35 ),
The first air humidity, the lower control limit by an absolute humidity based on the dryness of the oral mucosa, absorption so that the humidity control range defined between the upper control limit due to relative humidity based on the deterioration degree of the indoor air quality an air conditioning apparatus characterized by comprising a controller (50) for controlling the humidity adjusting agent circuit (20).

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