JP4206853B2 - Humidity control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a humidity controller with a refrigerant circuit, saving energy by improving the heat exchanging performance of a heat exchanger as an evaporator during operating a refrigerating cycle. <P>SOLUTION: In an upstream side space 92 of a casing 10, first and second adsorbing elements 81, 82 are provided. In an area adjacent to the upstream side space 92, right and left upper flow paths 65, 67 and lower flow paths 66, 68 are provided through which air flowing in and out of the adsorbing elements 81, 82 passes. The height of a downstream side space 91 partitioned into a first space 41 and a second space 42 is equal to the height of the casing 10. A first source heat exchanger 103 and a second source heat exchanger 104 are provided in the first space 41 and in the second space 42, respectively. Air flowing from the right and left upper flow paths 65, 67 into the first and second spaces 41, 42 passes through the source heat exchangers 103, 104 with its flow expanding in the direction of the height of the casing 10. <P>COPYRIGHT: (C)2005,JPO&amp;NCIPI

Description

  The present invention relates to a humidity control device that adjusts the humidity of air.

  Conventionally, as disclosed in Patent Document 1, a humidity control device that adjusts the humidity of air using an adsorbent is known. This humidity control apparatus performs dehumidification or humidification of air supplied to a room by using two adsorbing elements alternately by switching the flow path of outdoor air and room air.

  Specifically, the casing of the humidity control apparatus is partitioned into three spaces in the longitudinal direction by two partition members. Each of these three spaces is partitioned into upper and lower spaces in the height direction. A cooling heat exchanger functioning as an evaporator is provided in the space on the lowermost side and the innermost side in the lower space. In the central space, two adsorbing elements carrying an adsorbent and a regeneration heat exchanger functioning as a condenser are provided. The cooling heat exchanger and the regeneration heat exchanger are provided in the refrigerant circuit.

During the dehumidifying operation, moisture in the outdoor air is adsorbed by one of the adsorbing elements. The dehumidified air is cooled while passing through the cooling heat exchanger in the innermost space, and then supplied to the room. On the other hand, the taken-in room air absorbs the heat of adsorption generated by one of the adsorption elements, is heated by the regeneration heat exchanger, and is regenerated to the outside after regenerating the other adsorption element. During the humidifying operation, moisture in the room air is adsorbed by one of the adsorbing elements. The air deprived of moisture is cooled while passing through the cooling heat exchanger in the space on the front side, and then discharged outside the room. On the other hand, the taken-out outdoor air absorbs the heat of adsorption generated by one of the adsorption elements, is heated by the regeneration heat exchanger, and is supplied to the room after regenerating the other adsorption element.
JP 2003-139349 A

  In the humidity control apparatus disclosed in Patent Document 1, the casing is partitioned into two spaces in the vertical direction, and a cooling heat exchanger is provided in the lower space among them. For this reason, a cooling heat exchanger with a height less than half the height of the casing must be used, and the heat transfer area of the cooling heat exchanger that becomes an evaporator during refrigeration cycle operation is reduced. There was a problem that it could not be secured sufficiently. As a result, there has been a problem that the COP (coefficient of performance) of the refrigeration cycle is lowered and the energy required for the operation of the humidity control apparatus is increased.

  This invention is made | formed in view of this point, The place made into the objective is improving the heat exchange capability of the heat exchanger used as an evaporator in a refrigeration cycle in a humidity control apparatus provided with a refrigerant circuit. This is to save energy in the humidity control device.

In the first invention, air to be treated is circulated in a casing (10) in which a fan (95, 96) and an adsorbing element (81, 82) are provided, and the adsorbing element (81, 82) is used. This is intended for humidity control devices that adjust the humidity of the air to be treated. Then, in order to regenerate the adsorbing element (81, 82), it passes through the heating heat exchanger (102) for heating the air to be processed toward the adsorbing element (81, 82) and the adsorbing element (81, 82). The heat source heat exchanger (103, 104) for evaporating the refrigerant by heat exchange with the air to be treated is provided with a refrigerant circuit, while the casing (10) is formed in a rectangular parallelepiped shape. 10) includes an upstream space (92) in which the adsorption elements (81, 82) and a heat exchanger (102) for heating are installed, and a downstream side in which the heat exchanger for the heat source (103, 104) is installed. A space (91) is formed, and a portion of the casing (10) adjacent to the upstream space (92) has an inflow side passage (66) through which air to be processed toward the adsorption element (81, 82) flows. , 68) and the outflow side where the air to be treated that has passed through the adsorption element (81, 82) flows and is connected to the downstream space (91) Road and (65, 67) is formed to overlap, the height of the downstream space (91) is one that is equal to the height of the casing (10).

  According to a second aspect of the present invention, in the humidity control apparatus according to the first aspect, the fan (95, 96) is installed in the downstream space (91).

  According to a third aspect of the present invention, in the humidity control apparatus according to the first or second aspect, the downstream space (91) is formed along the front surface (11) of the casing (10), while the inflow side passage (66 , 68) and the outflow side passageway (65, 67) are formed along the side surface portion (71, 72) orthogonal to the front surface portion (11) of the casing (10), and the heat source heat exchanger (103, 104) The casing (10) is provided so as to be orthogonal to the front surface portion (11).

  According to a fourth aspect of the present invention, in the humidity control apparatus according to the first or second aspect, the downstream space (91) is formed along the front surface (11) of the casing (10), while the inflow side passage (66 , 68) and the outflow side passageway (65, 67) are formed along the side surface portion (71, 72) orthogonal to the front surface portion (11) of the casing (10), and the heat source heat exchanger (103, 104) The one side is located at the corner formed by the front surface portion (11) and the side surface portions (71, 72) of the casing (10) and is inclined with respect to the front surface portion (11) of the casing (10). Is to be placed.

  According to a fifth aspect of the present invention, in the humidity control apparatus according to any one of the first to fourth aspects, the heat source heat exchanger (103, 104) is provided to be inclined with respect to the bottom surface of the casing (10). Is.

  According to a sixth aspect of the present invention, in the humidity control apparatus according to claim 1 or 2, the downstream portion of the outflow side passageway (65, 66) gradually expands as the cross-sectional area approaches the downstream space (91). To do.

  According to a seventh aspect of the present invention, in the humidity control apparatus according to claim 1 or 2, the outflow side passage (65, 66) is formed above the inflow side passage (67, 68), and the heat source heat exchanger A drain pan (105, 106) for receiving drain water generated in the heat source heat exchanger (103, 104) is installed below (103, 104).

-Action-
In the first aspect of the invention, the downstream space (91) and the upstream space (92) are formed in the casing (10). A heat source heat exchanger (103, 104) is installed in the downstream space (91). In the upstream space (92), an adsorbing element (81, 82) and a heat exchanger for heating (102) are installed. Further, in the portion adjacent to the upstream space (92), the inflow side passage (66, 68) and the outflow side passage (65, 67) are formed so as to overlap each other.

  When the fan (95, 96) is driven, the air to be treated is taken into the casing (10). In the casing (10), the air to be processed flows into the adsorption element (81, 82) in the upstream space (92) through the inflow side passage (66, 68). When the air to be treated is supplied to the adsorption element (81, 82) as it is, the moisture in the air to be treated is adsorbed by the adsorption element (81, 82) and the air to be treated is dehumidified. On the other hand, when the air to be treated is heated by the heating heat exchanger (102) and supplied to the adsorption elements (81, 82), the air to be treated is humidified by moisture desorbed from the adsorption elements (81, 82).

  The air to be treated that has passed through the adsorption element (81, 82) is sent out from the upstream space (92) to the outflow passage (65, 67). The to-be-processed air flowing through the outflow side passage (65,67) flows into the downstream space (91), and after the flow expands in the direction of the inflow side passage (66,68), the heat source heat exchanger (103,104 )

  In the refrigerant circuit, a refrigeration cycle is performed in which the heating heat exchanger (102) serves as a condenser and the heat source heat exchanger (103, 104) serves as an evaporator. In the heating heat exchanger (102), the refrigerant dissipates heat to the air to be treated and condenses. In the heat source heat exchanger (103, 104), the refrigerant absorbs heat from the air to be treated and evaporates.

  In the second invention, the fan (95, 96) is installed in the downstream space (91). When the fan (95, 96) is operated, the air to be treated is drawn from the outflow side passage (65, 67) to the downstream space (91). And the to-be-processed air which flowed into the downstream side space (91) is sent out of the casing (10) after passing through the heat source heat exchanger (103, 104).

  In the third aspect of the invention, the downstream space (91) is formed along the front surface portion (11) of the casing (10), and the side surface portions (71, 72) orthogonal to the front surface portion (11) of the casing (10). An inflow side passageway (66, 68) and an outflow side passageway (65, 67) are formed along. In the downstream space (91), the heat source heat exchanger (103, 104) is provided so as to be orthogonal to the front surface portion (11) of the casing (10). That is, the heat source heat exchanger (103, 104) is provided in parallel with the side surface (71, 72) of the casing (10).

  The air to be treated that has passed through the adsorption element (81, 82) flows through the outflow passage (65, 67) along the side surface (71, 72) of the casing (10), and the casing in the downstream space (91). It flows into the portion sandwiched between the side surface portions (71, 72) of (10) and the heat source heat exchanger (103, 104). And the to-be-processed air which flowed into the downstream space (91) passes the heat exchanger (103,104) for heat sources.

  In the fourth aspect of the invention, the downstream space (91) is formed along the front surface portion (11) of the casing (10), and the side surface portions (71, 72) orthogonal to the front surface portion (11) of the casing (10). An inflow side passageway (66, 68) and an outflow side passageway (65, 67) are formed along. Also, in the downstream space (91), the heat source heat exchanger (103, 104) has one side located at the corner of the casing (10), and is viewed from the front surface (11) side of the casing (10). It is arranged diagonally toward the left back or right back.

  The air to be treated that flows into the downstream space (91) from the outflow passageway (65,67) along the side surface (71,72) of the casing (10) is a heat source heat exchanger (103,104) arranged obliquely. When passing through, the left or right direction is guided, and the flow direction is smoothly changed from the front-rear direction to the left-right direction when viewed from the front surface portion (11) of the casing (10).

  In the fifth aspect, the heat source heat exchanger (103, 104) is provided so as to be inclined with respect to the bottom surface of the casing (10). That is, the heat source heat exchangers (103, 104) are installed in an inclined posture rather than perpendicular to the bottom surface of the casing (10).

  In the sixth invention, the air to be treated after passing through the adsorption element (81, 82) flows into the downstream space (91) through the outflow passage (65, 67). The cross-sectional area of the downstream portion of the outflow passage (65, 67), that is, the portion closer to the downstream space (91) gradually increases as it approaches the downstream space (91). For this reason, the to-be-processed air which flows through an outflow side channel | path (65,67) expands gradually as the flow approaches the downstream space (91).

  In the seventh aspect, the drain pan (105, 106) for receiving the drain water generated in the heat source heat exchanger (103, 104) is provided below the heat source heat exchanger (103, 104). In the casing (10), the outflow side passages (65, 67) are provided above the inflow side passages (66, 68). The flow of the air to be treated that has flowed into the downstream space (91) from the outflow side passageway (65, 67) expands downward.

  In the present invention, the downstream side space (65, 67) is formed so as to overlap the inflow side passage (66, 68) in the upstream side space (92), and is connected to the outflow side passage (65, 67). A heat source heat exchanger (103, 104) is arranged at (91). Therefore, in the downstream space (91), the heat source heat exchanger (103, 104) can be provided from the side of the outflow side passage (65, 67) to the side of the inflow side passage (66, 68). . In addition, the heat transfer area in the heat source heat exchanger (103, 104) can be increased as compared with the conventional case where the heat source heat exchanger (103, 104) is provided in the relatively narrow outflow passage (65, 67). it can. Therefore, according to the present invention, in the humidity control apparatus including the refrigerant circuit, the heat exchange capacity of the heat exchanger that becomes an evaporator is improved during the refrigeration cycle, and the COP of the refrigeration cycle is improved. You can plan.

  In the second aspect of the invention, the heat source heat exchanger (103, 104) is disposed in the downstream space (91) where the fan (95, 96) is provided. That is, the fan (95, 96) is accommodated in the casing (10) using the downstream space (91) in which the heat source heat exchanger (103, 104) is installed. Therefore, according to the present invention, it is not necessary to separately secure a space for installing the fan (95, 96) in the casing (10), and the casing (10) can be downsized.

  In the third aspect of the invention, the air to be treated that flows into the downstream space (91) from the outflow side passage (65,67) flows into the outflow side passage (65,67) and the inflow side passage (66,68). And then pass through the heat source heat exchanger (103, 104). Therefore, according to the present invention, the air flow rate of the air to be treated can be made uniform over the entire surface of the heat source heat exchanger (103, 104), and the heat exchange capacity of the heat source heat exchanger (103, 104) can be sufficiently increased. It can be demonstrated.

  In the fourth aspect of the invention, the heat source heat exchanger (103, 104) is disposed obliquely in the downstream space (91), so that the flow of the air to be treated is smoothly changed by the heat source heat exchanger (103, 104). The That is, according to the present invention, it is possible to guide the flow of the air to be processed flowing into the downstream space (91) using the heat source heat exchangers (103, 104) arranged obliquely. For this reason, the pressure loss of the to-be-processed air at the time of passing downstream space (91) can be reduced, and the electric power required for a drive of a fan (95,96) can be reduced.

  Further, according to the present invention, by arranging the heat source heat exchanger (103, 104) obliquely, the length of the side perpendicular to the corner of the casing (10) in the heat source heat exchanger (103, 104) is It can be made larger than the depth of the downstream space (91) with respect to the front surface portion (11). Therefore, according to the present invention, the heat source heat exchanger (103, 104) can be enlarged to increase the heat transfer area, and the heat exchange capability of the heat source heat exchanger (103, 104) can be improved.

  According to the fifth aspect of the present invention, in the heat source heat exchanger (103, 104), the length of the side inclined with respect to the bottom surface portion of the casing (10) is set to the length of the casing (10) in the direction perpendicular to the bottom surface portion. It can be larger than the length of the side. Therefore, according to the present invention, the heat source heat exchanger (103, 104) can be enlarged to increase the heat transfer area without changing the size of the casing (10), and the heat source heat exchanger (103, 104) It is possible to improve the heat exchange capacity.

  According to the sixth aspect of the present invention, the flow of the air to be processed flowing through the outflow passage (65, 67) gradually expands as it approaches the downstream space (91). For this reason, the to-be-processed air which flows into downstream space (91) does not expand rapidly, but is introduced smoothly. Therefore, the pressure loss of the air to be treated when flowing into the downstream space (91) from the outflow passage (65, 67) is reduced. Further, the amount of air passing through the heat source heat exchanger (103, 104) can be made uniform over the entire surface, and the heat exchange capacity of the heat source heat exchanger (103, 104) can be improved.

  In the seventh aspect of the invention, the outflow side passageway (65, 67) is formed on the upper side in the casing (10), and when flowing from the outflow side passageway (65,67) into the downstream space (91), The flow of air to be treated expands downward. Here, when the outflow side passageway (65, 67) is formed in the lower side of the casing (10), the air to be treated that flows into the downstream space (91) from the outflow side passageway (65,67) Impinges on the drain pan (105, 106) at a high flow velocity, the flow of the air to be treated is greatly disturbed, and the pressure loss of the air to be treated increases.

  In contrast, in the present invention, the outflow side passageway (65, 67) is provided on the upper side of the casing (10), and the air to be treated flows into the downstream space (91) from the outflow side passageway (65,67). Yes. For this reason, the flow velocity of the air to be treated that collides with the drain pan (105, 106) installed below the heat source heat exchanger (103, 104) is lower than when the outflow side passageway (65, 67) is provided on the lower side. . Therefore, according to the present invention, it is possible to suppress an increase in ventilation resistance due to the installation of the drain pan (105, 106), and it is possible to reduce the electric power required for driving the fan (95, 96).

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1 of the Invention
The humidity control apparatus according to the present embodiment is configured to perform switching between a dehumidifying operation for supplying dehumidified air to the room and a humidifying operation for supplying the humidified air to the room. The humidity control apparatus includes a refrigerant circuit and two adsorbing elements (81, 82), and is configured to perform a so-called batch operation. Here, the configuration of the humidity control apparatus according to the present embodiment will be described with reference to FIGS. 1 and 6. In the description of the first embodiment, “up”, “down”, “left”, “right”, “front”, “rear”, “front”, and “back” refer to the humidity control apparatus shown in FIG. It means the one seen from the front side.

  As shown in FIG. 1, the humidity control apparatus includes a flat rectangular parallelepiped casing (10) having a low height. The casing (10) accommodates two adsorbing elements (81, 82) and a refrigerant circuit. 1A is a left side view, FIG. 1B is a plan view, and FIG. 1C is a right side view. This also applies to FIGS. 2 to 4 and 7 to 9.

  The refrigerant circuit includes a heating heat exchanger (102), a first heat source heat exchanger (103) that is a first heat source heat exchanger, and a second heat source heat that is a second heat source heat exchanger. An exchanger (104), a compressor (101), and an expansion valve are provided. In FIG. 1, only the heating heat exchanger (102), the first heat source heat exchanger (103), the second heat source heat exchanger (104), and the compressor (101) are illustrated. In this refrigerant circuit, the refrigeration cycle is performed by circulating the filled refrigerant. The refrigerant circuit performs an operation in which at least one of the first and second heat source heat exchangers (103, 104) serves as an evaporator. In the humidity control apparatus of the present embodiment, an operation in which the first heat source heat exchanger (103) serves as an evaporator and an operation in which the second heat source heat exchanger (104) serves as an evaporator are switched.

  As shown in FIG. 6, the adsorption element (81 82) is configured by alternately laminating flat plate members (83) and corrugated corrugated plate members (84). The corrugated plate members (84) are laminated so that the ridge line directions of the adjacent corrugated plate members (84) are shifted from each other by 90 degrees. And the adsorption | suction element (81,82) is formed in the rectangular parallelepiped shape thru | or square column shape as a whole.

  In the adhering element (81 82), the humidity adjusting side passageway (85) and the cooling side passageway (86) in the stacking direction of the flat plate member (83) and the corrugated plate member (84) are connected to the flat plate member (83). The sections are alternately formed with a sandwich. In this adsorption element (81, 82), the humidity adjusting side passageway (85) opens on the long side surface of the flat plate member (83), and the cooling side passageway (86) on the short side surface of the flat plate member (83). ) Is open.

  In the adsorption element (81, 82), on the surface of the flat plate member (83) facing the humidity adjustment side passage (85) and on the surface of the corrugated plate member (84) provided in the humidity adjustment side passage (85), An adsorbent for adsorbing water vapor is applied. Examples of this type of adsorbent include silica gel, zeolite, ion exchange resin and the like.

  As shown in FIG. 1, in the casing (10), a first panel (11) as a front surface portion is provided on the foremost side, and a second panel (12) is provided on the innermost side. Further, in the casing (10), the right side surface portion (71) is arranged at the end portions of the first panel (11) and the second panel (12) so as to be orthogonal to the first panel (11) and the second panel (12). ) And a left side surface portion (72).

  The first panel (11) has an exhaust port (14) as a first air outlet at the center on the right side, and an air supply port (16) as a second air outlet at the center on the left side. Is formed. On the other hand, the second panel (12) has an outdoor inlet (13) formed in the lower part near the right end, and an indoor inlet (15) formed in the lower part near the left end.

  The inside of the casing (10) is partitioned into a space on the first panel (11) side and a space on the second panel (12) side.

  A downstream space (91), which is a space formed on the first panel (11) side of the casing (10), is divided into two spaces on the left and right. Of these two spaces, the right space constitutes the first space (41), and the left space constitutes the second space (42).

  On the other hand, the space formed on the second panel (12) side of the casing (10) includes a right partition plate (20) and a left partition plate (30) provided in parallel with the right side surface portion (71) and the left side surface portion (72). Are divided into three spaces on the left and right.

  Of the downstream space (91), the first space (41) communicates with the outside through the exhaust port (14). In the first space (41), a refrigerant circuit compressor (101), an exhaust fan (95) as a first fan, and a first heat source heat exchanger (103) are arranged in this order from the left side. is set up.

  The first heat source heat exchanger (103) is a fin-and-tube heat exchanger formed in a thin rectangular parallelepiped shape, and allows air to pass therethrough. The first heat source heat exchanger (103) is provided so as to be orthogonal to the first panel (11). Further, the first heat source heat exchanger (103) is provided such that the right side surface thereof substantially coincides with the right partition plate (20). The first heat source heat exchanger (103) has a width substantially equal to the depth of the first space (41) and a height substantially equal to the height of the casing (10). A first drain pan (105) for receiving drain water generated in the first heat source heat exchanger (103) is provided below the first heat source heat exchanger (103).

  The second space (42) of the downstream space (91) communicates with the room through the air supply port (16). In the second space (42), an air supply fan (96) as a second fan and a second heat source heat exchanger (104) are installed in this order from the right side.

  Similar to the first heat source heat exchanger (103), the second heat source heat exchanger (104) is a fin-and-tube heat exchanger formed in a thin rectangular parallelepiped shape, Air can pass in the vertical direction. The second heat source heat exchanger (104) is provided to be orthogonal to the first panel (11). Further, the second heat source heat exchanger (104) is provided such that the left side surface thereof substantially coincides with the left partition plate (30). The second heat source heat exchanger (104) has a width substantially equal to the depth of the second space (42) and a height substantially equal to the height of the casing (10). A second drain pan (106) for receiving drain water generated in the second heat source heat exchanger (104) is provided below the second heat source heat exchanger (104).

  Of the space formed on the second panel (12) side of the casing (10), the space along the right side surface portion (71) on the right side of the right partition plate (20) is partitioned vertically. In this space, the upper space constitutes the upper right channel (65) as the outflow side passage, and the lower space constitutes the lower right channel (66) as the inflow side passage. The upper right channel (65) communicates with the first space (41). The lower right channel (66) communicates with the outdoor suction port (13) and is partitioned from the first space (41).

  The space along the left side surface portion (72) on the left side of the left partition plate (30) is partitioned vertically. In this space, the upper space constitutes the upper left channel (67) as the outflow side passage, and the lower space constitutes the lower left channel (68) as the inflow side passage. The upper left channel (67) communicates with the second space (42). The lower left channel (68) communicates with the indoor suction port (15) and is partitioned from the second space (42).

  An upstream space (92) is formed between the right partition plate (20) and the left partition plate (30). Two adsorbing elements (81, 82) are installed in the upstream space (92). These adsorbing elements (81, 82) are arranged in a state where they are lined up and down at a predetermined interval. Specifically, a first adsorption element (81), which is a first adsorption element, is provided near the first panel (11) on the near side, and a second adsorption element is arranged near the second panel (12) on the back side. A second adsorption element (82) is provided.

  The first and second adsorption elements (81, 82) are installed in a posture in which the laminating direction of the flat plate member (83) and the corrugated plate member (84) in each of them coincides with the horizontal direction of the casing (10). In each adsorbing element (81, 82) in this posture, the humidity adjustment side passageway (85) opens on the upper and lower side surfaces, and the cooling side passageway (86) opens on the front and rear side surfaces, while Neither channel (85, 86) is open.

  The upstream space (92) includes a first channel (51), a second channel (52), a first upper channel (53), a first lower channel (54), and a second upper channel (55). ), A second lower channel (56) and a central channel (57).

  The first flow path (51) is formed on the front side of the first adsorption element (81) and communicates with the cooling side passage (86) of the first adsorption element (81). The second flow path (52) is formed on the back side of the second adsorption element (82) and communicates with the cooling side passage (86) of the second adsorption element (82).

  The first upper flow path (53) is formed on the upper side of the first adsorption element (81) and communicates with the humidity adjustment side passageway (85) of the first adsorption element (81). The first lower flow path (54) is formed below the first adsorption element (81) and communicates with the humidity adjustment side passageway (85) of the first adsorption element (81). The second upper flow path (55) is formed above the second adsorption element (82) and communicates with the humidity adjustment side passage (85) of the second adsorption element (82). The second lower flow path (56) is formed below the second adsorption element (82) and communicates with the humidity adjustment side passageway (85) of the second adsorption element (82).

  The central flow path (57) is formed between the first adsorption element (81) and the second adsorption element (82) and communicates with the cooling side passageway (86) of both adsorption elements (81, 82). In the central flow path (57), the heat exchanger (102) for heating is installed in a state of standing substantially vertically. The heating heat exchanger (102) causes the air flowing through the central flow path (57) to exchange heat with the refrigerant in the refrigerant circuit. The heating heat exchanger (102) functions as a condenser and constitutes a heater for heating the air.

  A first shutter (61) is provided in a partition between the central channel (57) and the first lower channel (54). On the other hand, a second shutter (62) is provided in a partition between the central channel (57) and the second lower channel (56). Both the first shutter (61) and the second shutter (62) are configured to be openable and closable.

  The right partition plate (20) includes a first right opening (21), a second right opening (22), a first upper right opening (23), a first lower right opening (24), a second upper right opening (25), And the 2nd lower right opening (26) is formed. Each of these openings (21, 22,...) Includes an opening / closing shutter and is configured to be freely opened and closed.

  The first right opening (21) is provided in the lower part on the near side of the right partition plate (20). When the open / close shutter of the first right opening (21) is opened, the first flow path (51) and the lower right flow path (66) communicate with each other. The second right opening (22) is provided in the lower part on the back side of the right partition plate (20). In a state where the opening / closing shutter of the second right side opening (22) is opened, the second channel (52) and the lower right channel (66) communicate with each other.

  The first upper right opening (23) is provided in the upper part of the right partition plate (20) adjacent to the first adsorption element (81). In a state where the opening / closing shutter of the first upper right opening (23) is opened, the first upper channel (53) and the upper right channel (65) communicate with each other. The first lower right opening (24) is provided in the lower part of the right partition plate (20) adjacent to the first adsorption element (81). In a state where the opening / closing shutter of the first lower right opening (24) is opened, the first lower flow path (54) and the right lower flow path (66) communicate with each other.

  The second upper right opening (25) is provided in the upper part of the right partition plate (20) adjacent to the second adsorption element (82). When the open / close shutter of the second upper right opening (25) is opened, the second upper channel (55) and the upper right channel (65) communicate with each other. The second lower right opening (26) is provided in the lower part of the right partition plate (20) adjacent to the second adsorption element (82). When the open / close shutter of the second lower right opening (26) is opened, the second lower flow path (56) and the right lower flow path (66) communicate with each other.

  The left partition plate (30) includes a first left opening (31), a second left opening (32), a first upper left opening (33), a first lower left opening (34), a second upper left opening (35), and A second lower left opening (36) is formed. Each of these openings (31, 32,...) Includes an open / close shutter and is configured to be freely opened and closed.

  The first left opening (31) is provided in the lower part on the front side of the left partition plate (30). When the open / close shutter of the first left opening (31) is opened, the first flow path (51) and the lower left flow path (68) communicate with each other. The second left opening (32) is provided in the lower part on the back side of the left partition plate (30). When the open / close shutter of the second left side opening (32) is opened, the second channel (52) and the lower left channel (68) communicate with each other.

  The first upper left opening (33) is provided in the upper part of the left partition plate (30) adjacent to the first adsorption element (81). In a state where the opening / closing shutter of the first upper left opening (33) is opened, the first upper channel (53) and the upper left channel (67) communicate with each other. The first lower left opening (34) is provided in the lower part of the left partition plate (30) adjacent to the first adsorption element (81). When the open / close shutter of the first lower left opening (34) is opened, the first lower flow path (54) and the left lower flow path (68) communicate with each other.

  The second upper left opening (35) is provided in the upper part of the left partition plate (30) adjacent to the second adsorption element (82). When the open / close shutter of the second upper left opening (35) is opened, the second upper channel (55) and the upper left channel (67) communicate with each other. The second lower left opening (36) is provided in the lower part of the left partition plate (30) adjacent to the second adsorption element (82). When the open / close shutter of the second lower left opening (36) is opened, the second lower flow path (56) and the lower left flow path (68) communicate with each other.

-Driving action-
The operation of the humidity control apparatus will be described. This humidity control apparatus switches between a dehumidifying operation and a humidifying operation. The humidity control apparatus performs a dehumidifying operation and a humidifying operation by alternately repeating the first operation and the second operation.

《Dehumidification operation》
As shown in FIGS. 1 and 2, when the air supply fan (96) is driven during the dehumidifying operation, the outdoor air (OA) flows through the outdoor suction port (13) in the lower right channel (in the casing (10)). 66) is taken in as primary air. On the other hand, when the exhaust fan (95) is driven, the indoor air (RA) is taken as the second air into the lower left channel (68) in the casing (10) through the indoor suction port (15). In the dehumidifying operation, in the refrigerant circuit, the heating heat exchanger (102) serves as a condenser and the second heat source heat exchanger (104) serves as an evaporator, while the first heat source heat exchanger (103 ) Is paused.

(First operation)
The first operation of the dehumidifying operation will be described with reference to FIGS. In the first operation, an adsorption operation for the first adsorption element (81) and a regeneration operation for the second adsorption element (82) are performed. That is, in the first operation, air is dehumidified by the first adsorption element (81) and at the same time, the adsorbent of the second adsorption element (82) is regenerated.

  As shown in FIG. 1, in the right partition plate (20), the first lower right opening (24) and the second upper right opening (25) are in communication, and the remaining openings (21, 22, 23, 26) are in communication. Blocked state. In this state, the lower right channel (66) communicates with the first lower channel (54) by the first lower right opening (24), and the second upper channel (55) is communicated by the second upper right opening (25). And the upper right channel (65) communicate with each other.

  In the left partition plate (30), the first left opening (31) and the first upper left opening (33) are in communication with each other, and the remaining openings (32, 34, 35, 36) are in a blocking state. In this state, the lower left channel (68) communicates with the first channel (51) by the first left opening (31), and the first upper channel (53) and the upper left channel are communicated by the first upper left opening (33). The partial flow path (67) is communicated.

  The first shutter (61) is in a closed state, and the second shutter (62) is in an open state. In this state, the central channel (57) and the second lower channel (56) communicate with each other via the second shutter (62).

  The first air flows from the lower right channel (66) through the first lower right opening (24) to the first lower channel (54). On the other hand, the second air flows from the lower left channel (68) through the first left opening (31) to the first channel (51).

  As shown in FIG. 5 (a), the first air in the first lower flow path (54) flows into the humidity adjustment side passageway (85) of the first adsorption element (81). During the flow through the humidity adjusting side passageway (85), water vapor contained in the first air is adsorbed by the adsorbent. The first air dehumidified by the first adsorption element (81) flows into the first upper flow path (53).

  On the other hand, the second air in the first flow path (51) flows into the cooling side passage (86) of the first adsorption element (81). While flowing through the cooling side passage (86), the second air absorbs heat of adsorption generated when water vapor is adsorbed by the adsorbent in the humidity adjustment side passage (85). The second air deprived of heat of adsorption flows into the central flow path (57) and passes through the heating heat exchanger (102). At that time, in the heat exchanger for heating (102), the second air is heated by heat exchange with the refrigerant. Thereafter, the second air flows from the central channel (57) into the second lower channel (56).

  The second air heated by the first adsorption element (81) and the heating heat exchanger (102) is introduced into the humidity adjustment side passageway (85) of the second adsorption element (82). In the humidity adjustment side passageway (85), the adsorbent is heated by the second air, and water vapor is desorbed from the adsorbent. That is, the regeneration of the second adsorption element (82) is performed. The water vapor desorbed from the adsorbent flows into the second upper flow path (55) together with the second air.

  As shown in FIG. 1, the dehumidified first air that has flowed into the first upper channel (53) flows into the upper left channel (67) through the first upper left opening (33), and then It flows into the second space (42). When the first air flows from the upper left passage (67) into the second space (42), the flow expands in the height direction of the casing (10). In the second space (42), the flow of the first air turns to the right. Then, the first air passes through the second heat source heat exchanger (104) and is cooled by heat exchange with the refrigerant. The dehumidified and cooled first air is sucked into the air supply fan (96), and then supplied into the room through the air supply port (16).

  On the other hand, the second air flowing into the second upper channel (55) flows into the upper right channel (65) through the second upper right opening (25), and then flows into the first space (41). . When the second air flows from the upper right passage (65) into the first space (41), the flow expands in the height direction of the casing (10). In the first space (41), the flow of the second air turns to the left. Then, the second air passes through the first heat source heat exchanger (103). At that time, the first heat source heat exchanger (103) is inactive, and the second air is neither heated nor cooled. The second air used for cooling the first adsorbing element (81) and regenerating the second adsorbing element (82) is sucked into the exhaust fan (95) and then discharged to the outside through the exhaust port (14). Is done.

(Second operation)
The second operation of the dehumidifying operation will be described with reference to FIGS. In the second operation, contrary to the first operation, an adsorption operation for the second adsorption element (82) and a regeneration operation for the first adsorption element (81) are performed. That is, in the second operation, air is dehumidified by the second adsorption element (82), and at the same time, the adsorbent of the first adsorption element (81) is regenerated.

  As shown in FIG. 2, in the right partition plate (20), the first upper right opening (23) and the second lower right opening (26) are in communication, and the remaining openings (21, 22, 24, 25) are in communication. Blocked state. In this state, the first upper channel (53) and the upper right channel (65) are communicated with each other by the first upper right opening (23), and the lower right channel (66) is communicated with the second lower right opening (26). The second lower channel (56) communicates with the second lower channel (56).

  In the left partition plate (30), the second left opening (32) and the second upper left opening (35) are in communication, and the remaining openings (31, 33, 34, 36) are in a blocking state. In this state, the lower left channel (68) communicates with the second channel (52) by the second left opening (32), and the second upper channel (55) and the upper left channel are communicated by the second upper left opening (35). The partial flow path (67) is communicated.

  The first shutter (61) is in an open state, and the second shutter (62) is in a closed state. In this state, the central channel (57) and the first lower channel (54) communicate with each other via the first shutter (61).

  The first air flows from the lower right channel (66) through the second lower right opening (26) to the second lower channel (56). On the other hand, the second air flows from the lower left channel (68) through the second left opening (32) into the second channel (52).

  As shown also in FIG.5 (b), the 1st air of a 2nd lower flow path (56) flows in into the humidity control side channel | path (85) of a 2nd adsorption | suction element (82). During the flow through the humidity adjusting side passageway (85), water vapor contained in the first air is adsorbed by the adsorbent. The first air dehumidified by the second adsorption element (82) flows into the second upper flow path (55).

  On the other hand, the second air in the second flow path (52) flows into the cooling side passage (86) of the second adsorption element (82). While flowing through the cooling side passage (86), the second air absorbs heat of adsorption generated when water vapor is adsorbed by the adsorbent in the humidity adjustment side passage (85). The second air deprived of heat of adsorption flows into the central flow path (57) and passes through the heating heat exchanger (102). At that time, in the heat exchanger for heating (102), the second air is heated by heat exchange with the refrigerant. Thereafter, the second air flows from the central channel (57) into the first lower channel (54).

  The second air heated by the second adsorption element (82) and the heating heat exchanger (102) is introduced into the humidity adjustment side passageway (85) of the first adsorption element (81). In the humidity adjustment side passageway (85), the adsorbent is heated by the second air, and water vapor is desorbed from the adsorbent. That is, the regeneration of the first adsorption element (81) is performed. The water vapor desorbed from the adsorbent flows into the first upper flow path (53) together with the second air.

  As shown in FIG. 2, the dehumidified first air that has flowed into the second upper channel (55) flows into the upper left channel (67) through the second upper left opening (35), and then It flows into the second space (42). When the first air flows from the upper left passage (67) into the second space (42), the flow expands in the height direction of the casing (10). In the second space (42), the flow of the first air turns to the right. Then, the first air passes through the second heat source heat exchanger (104) and is cooled by heat exchange with the refrigerant. The dehumidified and cooled first air is sucked into the air supply fan (96), and then supplied into the room through the air supply port (16).

  On the other hand, the second air flowing into the first upper flow path (53) flows into the upper right flow path (65) through the first upper right opening (23), and then flows into the first space (41). . When the second air flows from the upper right passage (65) into the first space (41), the flow expands in the height direction of the casing (10). In the first space (41), the flow of the second air turns to the left. Then, the second air passes through the first heat source heat exchanger (103). At that time, the first heat source heat exchanger (103) is inactive, and the second air is neither heated nor cooled. The second air used for regeneration of the first adsorbing element (81) and cooling of the second adsorbing element (82) is sucked into the exhaust fan (95) and then discharged to the outside through the exhaust port (14). Is done.

《Humidification operation》
As shown in FIGS. 3 and 4, when the air supply fan (96) is driven during the humidifying operation, the outdoor air (OA) flows through the outdoor suction port (13) in the lower right channel (in the casing (10)). 66) as second air. On the other hand, when the exhaust fan (95) is driven, the indoor air (RA) is taken as the first air into the lower left flow path (68) in the casing (10) through the indoor suction port (15). During the humidification operation, in the refrigerant circuit, the heating heat exchanger (102) serves as a condenser and the first heat source heat exchanger (103) serves as an evaporator, while the second heat source heat exchanger (104 ) Is paused.

(First operation)
The first operation of the humidifying operation will be described with reference to FIGS. In the first operation, an adsorption operation for the first adsorption element (81) and a regeneration operation for the second adsorption element (82) are performed. That is, in the first operation, air is humidified by the second adsorption element (82), and the adsorbent of the first adsorption element (81) adsorbs water vapor.

  As shown in FIG. 3, in the right partition plate (20), the first right opening (21) and the first upper right opening (23) are in communication, and the remaining openings (22, 24, 25, 26) are blocked. It is in a state. In this state, the lower right channel (66) communicates with the first channel (51) by the first right opening (21), and the first upper channel (53) and the upper right channel are communicated by the first upper right opening (23). The partial flow path (65) is communicated.

  In the left partition plate (30), the first lower left opening (34) and the second upper left opening (35) are in communication, and the remaining openings (31, 32, 33, 36) are in a blocked state. In this state, the lower left channel (68) communicates with the first lower channel (54) by the first lower left opening (34), and the second upper channel (55) is communicated by the second upper left opening (35). The upper left channel (67) communicates.

  The first shutter (61) is in a closed state, and the second shutter (62) is in an open state. In this state, the central channel (57) and the second lower channel (56) communicate with each other via the second shutter (62).

  The first air flows from the lower left channel (68) through the first lower left opening (34) into the first lower channel (54). On the other hand, the second air flows from the lower right channel (66) through the first right opening (21) into the first channel (51).

  As shown in FIG. 5 (a), the first air in the first lower flow path (54) flows into the humidity adjustment side passageway (85) of the first adsorption element (81). During the flow through the humidity adjusting side passageway (85), water vapor contained in the first air is adsorbed by the adsorbent. The first air deprived of moisture by the first adsorption element (81) flows into the first upper flow path (53).

  On the other hand, the second air in the first flow path (51) flows into the cooling side passage (86) of the first adsorption element (81). While flowing through the cooling side passage (86), the second air absorbs heat of adsorption generated when water vapor is adsorbed by the adsorbent in the humidity adjustment side passage (85). The second air deprived of heat of adsorption flows into the central flow path (57) and passes through the heating heat exchanger (102). At that time, in the heat exchanger for heating (102), the second air is heated by heat exchange with the refrigerant. Thereafter, the second air flows from the central channel (57) into the second lower channel (56).

  The second air heated by the first adsorption element (81) and the heating heat exchanger (102) is introduced into the humidity adjustment side passageway (85) of the second adsorption element (82). In the humidity adjustment side passageway (85), the adsorbent is heated by the second air, and water vapor is desorbed from the adsorbent. That is, the regeneration of the second adsorption element (82) is performed. Then, water vapor desorbed from the adsorbent is applied to the second air, and the second air is humidified. The second air humidified by the second adsorption element (82) then flows into the second upper flow path (55).

  As shown in FIG. 3, the second air that has flowed into the second upper flow path (55) flows into the upper left flow path (67) through the second upper left opening (35), and then the second space ( 42). When the second air flows from the upper left passage (67) into the second space (42), the flow expands in the height direction of the casing (10). In the second space (42), the flow of the second air turns to the right. Then, the second air passes through the second heat source heat exchanger (104). At that time, the second heat source heat exchanger (104) is at rest, and the second air is neither heated nor cooled. The humidified second air is sucked into the air supply fan (96) and then supplied to the room through the air supply port (16).

  On the other hand, the first air flowing into the first upper flow path (53) flows into the upper right flow path (65) through the first upper right opening (23), and then flows into the first space (41). . When the first air flows from the upper right passage (65) into the first space (41), the flow expands in the height direction of the casing (10). In the first space (41), the flow of the first air turns leftward. The first air passes through the first heat source heat exchanger (103) and is cooled by heat exchange with the refrigerant. The first air deprived of moisture and heat is sucked into the exhaust fan (95), and then discharged to the outside through the exhaust port (14).

(Second operation)
The second operation of the humidifying operation will be described with reference to FIGS. In the second operation, contrary to the first operation, an adsorption operation for the second adsorption element (82) and a regeneration operation for the first adsorption element (81) are performed. That is, in this second operation, air is humidified by the first adsorption element (81), and the adsorbent of the second adsorption element (82) adsorbs water vapor.

  As shown in FIG. 4, in the right partition plate (20), the second right opening (22) and the second upper right opening (25) are in communication, and the remaining openings (21, 23, 24, 26) are blocked. It is in a state. In this state, the lower right channel (66) communicates with the second channel (52) by the second right opening (22), and the second upper channel (55) and the upper right channel are communicated by the second upper right opening (25). The partial flow path (65) is communicated.

  In the left partition plate (30), the first upper left opening (33) and the second lower left opening (36) are in communication, and the remaining openings (31, 32, 34, 35) are in a blocked state. In this state, the first upper channel (53) and the upper left channel (67) communicate with each other by the first upper left opening (33), and the lower left channel (68) and the first lower channel (68) communicate with each other by the second lower left opening (36). 2 The lower channel (56) communicates with the lower channel (56).

  The first shutter (61) is in an open state, and the second shutter (62) is in a closed state. In this state, the central channel (57) and the first lower channel (54) communicate with each other via the first shutter (61).

  The first air flows from the lower left channel (68) through the second lower left opening (36) to the second lower channel (56). On the other hand, the second air flows from the lower right channel (66) through the second right opening (22) into the second channel (52).

  As shown also in FIG.5 (b), the 1st air of a 2nd lower flow path (56) flows in into the humidity control side channel | path (85) of a 2nd adsorption | suction element (82). During the flow through the humidity adjusting side passageway (85), water vapor contained in the first air is adsorbed by the adsorbent. The first air deprived of moisture by the second adsorption element (82) flows into the second upper flow path (55).

  On the other hand, the second air in the second flow path (52) flows into the cooling side passage (86) of the second adsorption element (82). While flowing through the cooling side passage (86), the second air absorbs heat of adsorption generated when water vapor is adsorbed by the adsorbent in the humidity adjustment side passage (85). The second air deprived of heat of adsorption flows into the central flow path (57) and passes through the heating heat exchanger (102). At that time, in the heat exchanger for heating (102), the second air is heated by heat exchange with the refrigerant. Thereafter, the second air flows from the central channel (57) into the first lower channel (54).

  The second air heated by the second adsorption element (82) and the heating heat exchanger (102) is introduced into the humidity adjustment side passageway (85) of the first adsorption element (81). In the humidity adjustment side passageway (85), the adsorbent is heated by the second air, and water vapor is desorbed from the adsorbent. That is, the regeneration of the first adsorption element (81) is performed. Then, water vapor desorbed from the adsorbent is applied to the second air, and the second air is humidified. The second air humidified by the first adsorption element (81) then flows into the first upper flow path (53).

  As shown in FIG. 4, the second air that has flowed into the first upper flow path (53) flows into the left upper flow path (67) through the first upper left opening (33), and then the second space ( 42). When the second air flows from the upper left passage (67) into the second space (42), the flow expands in the height direction of the casing (10). In the second space (42), the flow of the second air turns to the right. Then, the second air passes through the second heat source heat exchanger (104). At that time, the second heat source heat exchanger (104) is at rest, and the second air is neither heated nor cooled. The humidified second air is sucked into the air supply fan (96) and then supplied to the room through the air supply port (16).

  On the other hand, the first air flowing into the second upper channel (55) flows into the upper right channel (65) through the second upper right opening (25), and then flows into the first space (41). . When the first air flows from the upper right passage (65) into the first space (41), the flow expands in the height direction of the casing (10). In the first space (41), the flow of the first air turns leftward. The first air passes through the first heat source heat exchanger (103) and is cooled by heat exchange with the refrigerant. The first air deprived of moisture and heat is sucked into the exhaust fan (95), and then discharged to the outside through the exhaust port (14).

-Effect of Embodiment 1-
In the present embodiment, the heights of the first space (41) and the second space (42) in which the first and second heat source heat exchangers (103, 104) are installed are equal to the height of the casing (10). ing. For this reason, in the first space (41) and the second space (42), the first and second heat source heat exchangers (103, 104) having the same height as the casing (10) can be installed. it can. Therefore, the heat transfer area in the first and second heat source heat exchangers (103, 104) can be expanded as compared with the conventional case where a heat exchanger having a half or less height of the casing (10) is used. . Therefore, according to the present embodiment, in the humidity control apparatus including the refrigerant circuit, the heat exchange capability of the heat exchanger serving as an evaporator is improved during the refrigeration cycle operation, and the COP of the refrigeration cycle is improved. Can be achieved.

  In the present embodiment, the first and second heat source heat exchangers (103, 104) are arranged in the downstream space (91) in which the exhaust fan (95) and the air supply fan (96) are provided. That is, the exhaust fan (95) and the air supply fan (96) are accommodated in the casing (10) using the downstream space (91) in which the first and second heat source heat exchangers (103, 104) are installed. Yes. Therefore, according to this embodiment, it is not necessary to separately secure a space for installing the exhaust fan (95) and the air supply fan (96) in the casing (10), and the casing (10) can be downsized. be able to.

  In this embodiment, the air flowing into the first space (41) from the upper right channel (65) expands in the height direction of the casing (10), and then heat exchange for the first heat source. Through the vessel (103). Similarly, the air flowing into the second space (42) from the upper left channel (67) expands in the height direction of the casing (10), and then the second heat source heat exchanger (104). Pass through. Therefore, according to the present embodiment, the amount of air passing air can be made uniform over the entire surface of the first and second heat source heat exchangers (103, 104), and the first and second heat source heat exchangers ( 103, 104) can be fully exhibited.

  Furthermore, in the present embodiment, the upper right channel (65) and the upper left channel (67) are formed on the upper side in the casing (10), and the upper right channel (65) and the upper left channel (67). ) Flows into the first space (41) or the second space (42), the air flow expands downward.

  Here, when the upper right channel (65) is formed on the lower side in the casing (10), the air flowing into the first space (41) from the upper right channel (65) has a high flow velocity. In this state, it collides with the first drain pan (105), the air flow is greatly disturbed, and the pressure loss of the air increases. In addition, even when the upper left channel (67) is formed on the lower side in the casing (10), the air flowing into the second space (42) from the upper left channel (67) is the second drain pan (106). ) And the same problem occurs.

  On the other hand, in the present embodiment, the upper right channel (65) and the upper left channel (67) are provided above the casing (10), and the upper right channel (65) to the first space (41) Air flows into the second space (42) from the upper left channel (67). For this reason, the flow velocity of the air that collides with the first and second drain pans (105, 106) installed below the first and second heat source heat exchangers (103, 104) is the upper right flow path (65) and the upper left flow. This is lower than when the path (67) is provided below. Therefore, according to this embodiment, it is possible to suppress an increase in ventilation resistance due to the installation of the drain pan (105, 106), and to reduce the power required to drive the fan (95, 96).

<< Embodiment 2 of the Invention >>
The second embodiment of the present invention is obtained by changing the configuration of the first and second heat source heat exchangers (103, 104) in the humidity control apparatus of the first embodiment. Here, the difference between the present embodiment and the first embodiment will be described.

  As shown in FIG. 7, in the humidity control apparatus of the present embodiment, the first heat source heat exchanger (103) installed in the first space (41) has one side on the near side as the first panel (11). It is located at the corner of the casing (10) formed by the right side surface (71). Further, the one side on the back side of the first heat source heat exchanger (103) is located on the left side of the one side on the near side. That is, the first heat source heat exchanger (103) is provided so as to obliquely cross the first space (41) from the near side toward the left side. The height of the first heat source heat exchanger (103) is substantially equal to the height of the casing (10).

  On the other hand, the second heat source heat exchanger (104) installed in the second space (42) has a casing (10) in which one side on the front side is formed by the first panel (11) and the left side surface portion (72). It is located in the corner. Further, the one side on the back side of the second heat source heat exchanger (104) is located to the right of the one side on the near side. That is, the second heat source heat exchanger (104) is provided so as to obliquely cross the second space (42) from the near side to the right back side. The height of the second heat source heat exchanger (104) is approximately equal to the height of the casing (10).

  When the air passing through the upper right passage (65) flows into the first space (41), the flow expands downward. In the first space (41), the air is guided to the left when passing through the heat exchanger (103) for the first heat source, and the direction of the flow is smooth from the front-rear direction to the left-right direction of the casing (10). Changed to On the other hand, when the air passing through the upper left passage (67) flows into the second space (42), the flow expands downward. In the second space (42), air is guided to the right when passing through the second heat source heat exchanger (104), and the direction of the flow is smooth from the front-rear direction to the left-right direction of the casing (10). Changed to In the first space (41) and the second space (42), the air whose direction of flow has changed is sucked into the exhaust fan (95) and the air supply fan (96).

  Thus, in the present embodiment, the first and second heat source heat exchangers (103, 104) are arranged obliquely, and the air flow is exhausted by the exhaust fan (103, 104) by the first and second heat source heat exchangers (103, 104). 95) and air supply fan (96). That is, according to the present embodiment, the air flowing into the first space (41) and the second space (42) using the first and second heat source heat exchangers (103, 104) disposed obliquely is used. It is possible to guide in the direction of the exhaust fan (95) and the air supply fan (96). For this reason, the pressure loss of the air at the time of passing through the first space (41) and the second space (42) can be reduced, and the power required for driving the fans (95, 96) can be reduced.

  In addition, according to the present embodiment, the first and second heat source heat exchangers (103, 104) are arranged obliquely so that the first space (41) and the second space (42) have the first and second heat exchangers. The length of the horizontal side in the heat source heat exchanger (103, 104) can be made larger than the depth of the first space (41) and the second space (42). Therefore, according to the present embodiment, the first and second heat exchangers (103, 104) can be enlarged to increase the heat transfer area, and the first and second heat exchangers (103, 104) can exchange heat. Ability can be improved.

-Modification of Embodiment 2-
In the humidity control apparatus of the second embodiment, the configuration of the first and second heat source heat exchangers (103, 104) may be changed. Here, this modification will be described with respect to differences from the first embodiment.

  As shown in FIG. 8, in the present modification, the first heat source heat exchanger (103) installed in the first space (41) is bent toward the right side surface (71) near the center thereof. "". Further, the second heat source heat exchanger (104) installed in the second space (42) is formed in a “<” shape that is bent toward the left side surface portion (72) near the center thereof.

  According to this modification, the length of the horizontal side in the first and second heat source heat exchangers (103, 104) can be increased, and the heat transfer area can be further expanded. Therefore, according to the present modification, the heat exchange capability of the first and second heat source heat exchangers (103, 104) can be further improved.

<< Other Embodiments >>
-First modification-
In the humidity control apparatus of the first and second embodiments, the configurations of the first and second heat source heat exchangers (103, 104) may be changed.

  Specifically, in the humidity control apparatus, in the first space (41) and the second space (42), the first and second heat source heat exchangers (103, 104) are connected to the bottom surface of the casing (10). It may be installed in an inclined posture. In this modification, the first and second heat source heat exchangers (103, 104) are provided over the entire height direction of the first space (41) and the second space (42). That is, in the first and second heat source heat exchangers (103, 104), the length of the side inclined with respect to the bottom surface portion of the casing (10) is larger than the height of the casing (10).

  According to this modification, in the first and second heat source heat exchangers (103, 104), the length of the side inclined with respect to the bottom surface of the casing (10) is made larger than the height of the casing (10). be able to. Therefore, according to this modification, the heat transfer area can be increased by increasing the size of the first and second heat source heat exchangers (103, 104) without changing the size of the casing (10). The heat exchange capacity of the second heat source heat exchanger (103, 104) can be improved.

-Second modification-
In the humidity control apparatus of the first and second embodiments, the configurations of the upper right channel (65) and the upper left channel (67) may be changed. Here, a case where the present modification is applied to the first embodiment will be described.

  As shown in FIG. 9, in the humidity control apparatus of the present modification, the height of the downstream portion of the upper right channel (65) and the upper left channel (67), that is, the portion near the downstream space (91). However, it gradually increases as it approaches the downstream space (91). That is, in the upper right channel (65) and the upper left channel (67), the cross-sectional area of the downstream portion thereof gradually increases as it approaches the downstream space (91).

  Specifically, the upper right channel (65) and the upper left channel (67) are inclined at a constant angle toward the lower right channel (66) and the lower left channel (68). is doing. Further, the upper right channel (65) and the upper left channel (67) are not limited to this, and the downstream portion thereof is inclined toward the lower right channel (66) and the lower left channel (68). The angle may gradually increase.

  According to this modification, the air flowing through the upper right channel (65) and the upper left channel (67) gradually expands as it approaches the downstream space (91). For this reason, the air flowing into the downstream space (91) does not rapidly expand, but is smoothly introduced into the entire height direction of the casing (10). Therefore, the pressure loss of air when flowing into the first space (41) or the second space (42) from the upper right channel (65) and the upper left channel (67) is reduced. Further, the amount of air passing through the first and second heat source heat exchangers (103, 104) can be made uniform over the entire surface, and the heat exchange capacity of the first and second heat source heat exchangers (103, 104) can be improved. it can.

  As described above, the present invention is useful for a humidity control apparatus that includes a refrigerant circuit in which a refrigeration cycle is performed and performs humidity adjustment of air.

It is a schematic block diagram which shows the structure of the humidity control apparatus which concerns on Embodiment 1, and the flow of the air in 1st operation | movement at the time of a dehumidification driving | operation. It is a schematic block diagram which shows the structure of the humidity control apparatus which concerns on Embodiment 1, and the flow of the air in 2nd operation | movement at the time of a dehumidification driving | operation. It is a schematic block diagram which shows the structure of the humidity control apparatus which concerns on Embodiment 1, and the flow of the air in 1st operation | movement at the time of a humidification driving | operation. It is a schematic block diagram which shows the structure of the humidity control apparatus which concerns on Embodiment 1, and the flow of the air in 2nd operation | movement at the time of a humidification driving | operation. It is a principal part enlarged view of the humidity control apparatus which concerns on Embodiment 1. FIG. It is a schematic perspective view which shows the structure of the adsorption | suction element of the humidity control apparatus which concerns on Embodiment 1. FIG. It is a schematic block diagram which shows the structure of the humidity control apparatus which concerns on Embodiment 2, and the flow of the air in 1st operation | movement at the time of a dehumidification driving | operation. It is a schematic block diagram which shows the structure of the humidity control apparatus which concerns on Embodiment 2, and the flow of the air in 1st operation | movement at the time of a dehumidification driving | operation. It is a schematic block diagram which shows the structure of the humidity control apparatus which concerns on other embodiment, and the flow of the air in 1st operation | movement at the time of a dehumidification driving | operation.

Explanation of symbols

(10) Casing (11) Front (first panel)
(66,68) Inflow side passage (lower right channel, lower left channel)
(65,67) Outflow side passage (upper right channel, upper left channel)
(71,72) Side (right side, left side)
(81,82) Adsorption element (first adsorption element, second adsorption element)
(91) Downstream space (92) Upstream space (95,96) Fan (exhaust fan, exhaust fan)
(102) Heat exchanger for heating (103,104) Heat exchanger for heat source (first heat source heat exchanger, second heat source heat exchanger)
(105,106) drain pan (first drain pan, second drain pan)

Claims (7)

The air to be treated is circulated in the casing (10) in which the fan (95, 96) and the adsorption element (81, 82) are provided, and the humidity of the air to be treated is obtained using the adsorption element (81, 82). A humidity control device for adjusting,
In order to regenerate the adsorbing element (81, 82), a heat exchanger (102) for heating the air to be processed toward the adsorbing element (81, 82), and a target that has passed through the adsorbing element (81, 82). While comprising a refrigerant circuit connected to a heat source heat exchanger (103, 104) for evaporating the refrigerant by heat exchange with the processing air,
The casing (10) is formed in a rectangular parallelepiped shape,
In the casing (10), an upstream space (92) in which the adsorbing elements (81, 82) and a heat exchanger (102) for heating are installed, and a heat exchanger (103, 104) for the heat source are installed. A downstream space (91) is formed,
In a portion of the casing (10) adjacent to the upstream space (92), an inflow side passage (66, 68) through which air to be processed toward the adsorption element (81, 82) flows, and the adsorption element ( 81, 82) is formed by overlapping with the outflow passage (65, 67) connected to the downstream space (91) through which the air to be treated flows .
A humidity control apparatus in which the height of the downstream space (91) is equal to the height of the casing (10) . The humidity control apparatus according to claim 1,
The fan (95, 96) is a humidity control device installed in the downstream space (91). The humidity control apparatus according to claim 1 or 2,
While the downstream space (91) is formed along the front surface (11) of the casing (10),
The inflow side passage (66,68) and the outflow side passage (65,67) are formed along the side surface portion (71,72) orthogonal to the front surface portion (11) of the casing (10),
The heat source heat exchanger (103, 104) is a humidity control device provided so as to be orthogonal to the front surface portion (11) of the casing (10). The humidity control apparatus according to claim 1 or 2,
While the downstream space (91) is formed along the front surface (11) of the casing (10),
The inflow side passage (66,68) and the outflow side passage (65,67) are formed along the side surface portion (71,72) orthogonal to the front surface portion (11) of the casing (10),
One side of the heat source heat exchanger (103, 104) is located at a corner formed by the front surface portion (11) and the side surface portion (71, 72) of the casing (10), and the front surface portion ( 11) Humidity control device arranged in a tilted position. The humidity control apparatus according to any one of claims 1 to 4,
The heat source heat exchanger (103, 104) is a humidity control device provided to be inclined with respect to the bottom surface of the casing (10). The humidity control apparatus according to claim 1 or 2,
The downstream portion of the outflow side passageway (65, 66) is a humidity control apparatus whose cross-sectional area gradually increases as it approaches the downstream side space (91). The humidity control apparatus according to claim 1 or 2,
The outflow side passage (65, 66) is formed above the inflow side passage (67, 68).
A humidity control apparatus in which a drain pan (105, 106) for receiving drain water generated in the heat source heat exchanger (103, 104) is installed below the heat source heat exchanger (103, 104).

Images