JP2016211753A - Humidity adjustment device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accelerate air-conditioning in simple ventilation operation.SOLUTION: In simple ventilation operation, an air supply fan 23 is driven in a state where a humidity adjustment unit 50 is stopped, and air taken in from outside is supplied to inside without adjusting humidity at the humidity adjustment unit 50. A fan control unit 43, in the simple ventilation operation, sets the air quantity of the air supply fan 23 to any one of a predetermined first air quantity and a second air quantity that is larger than the first air quantity.SELECTED DRAWING: Figure 1

Description

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

  Conventionally, a humidity control apparatus that adjusts the humidity of air using an adsorbent is known. For example, Patent Document 1 describes a humidity control apparatus including a refrigerant circuit having first and second adsorption heat exchangers. In this humidity control apparatus, a first operation in which the second air passes through the first adsorption heat exchanger functioning as a radiator and the first air passes through the second adsorption heat exchanger functioning as an evaporator, and the radiator A second operation is performed in which the second air passes through the second adsorption heat exchanger functioning as the first air and the first air passes through the first adsorption heat exchanger functioning as the evaporator. The outdoor air sucked as one of the first air and the second air is supplied to the indoor space, and the indoor air sucked as the other of the first air and the second air is discharged to the outdoor space.

  Moreover, in the humidity control apparatus of patent document 1, based on the success or failure of predetermined conditions, humidity control operation (dehumidification operation and humidification operation), sensible heat treatment operation (cooling operation and heating operation), simple ventilation operation, Is selectively performed. In the humidity control operation, the first operation and the second operation are alternately repeated for each first predetermined time. In the sensible heat treatment operation, only one of the first operation and the second operation is performed. In the simple ventilation operation, the outdoor air is supplied to the indoor space while the compressor is stopped, and the indoor air is discharged to the outdoor space.

JP 2014-66375 A

  In the humidity control apparatus of Patent Document 1, it is not necessary to adjust the humidity of the outdoor air, and when the outdoor air temperature is lower than the indoor air temperature, by performing a simple ventilation operation, the indoor air cooling (so-called outdoor air cooling) is performed. It can be done auxiliary. Further, when the outdoor air humidity adjustment is unnecessary and the outdoor air temperature is higher than the indoor air temperature, indoor heating (so-called outdoor air heating) can be supplementarily performed by performing simple ventilation operation. .

  However, in the humidity control apparatus of Patent Document 1, since the air conditioning capacity (cooling capacity or heating capacity) of the humidity control apparatus cannot be increased in simple ventilation operation, it is possible to promote indoor air conditioning (cooling or heating). could not.

  Therefore, an object of the present invention is to provide a humidity control device capable of promoting indoor air conditioning in simple ventilation operation.

  1st invention is equipped with the humidity control part (50) which can adjust the humidity of air, and the air supply fan (23) for supplying air indoors, The said humidity control part (50) and said air supply A humidity control operation in which the fan (23) is driven and air whose humidity is adjusted in the humidity control section (50) is supplied indoors, and the air supply fan in a state where the humidity control section (50) is stopped (23) is a humidity control apparatus that performs a simple ventilation operation in which air taken in from outside is supplied to the room without being adjusted in humidity in the humidity control section (50), In operation, the fan control unit sets the air volume of the air supply fan (23) to one of a predetermined first air volume (Q1) and a second air volume (Q2) larger than the first air volume (Q1). (43) It is provided with the humidity control apparatus characterized by the above-mentioned.

  In the first aspect of the invention, the air conditioning capacity (cooling capacity) of the humidity controller is set by setting the air volume of the air supply fan (23) to the second air volume (Q2) larger than the first air volume (Q1) in the simple ventilation operation. Or heating capacity) can be increased.

  In a second aspect based on the first aspect, the fan control section (43) increases the air volume of the air supply fan (23) from the first air volume (Q1) to the second air volume (Q2). The air conditioning operation efficiency (η1) obtained by dividing the increase in air conditioning capacity (ΔΦ) of the humidity control apparatus by the increase in power consumption (ΔW) of the humidity control apparatus is a predetermined reference operation efficiency ( If the air flow exceeds the standard operating efficiency (η0), the air flow rate of the air supply fan (23) is set to the second air volume (Q2) in the simple ventilation operation, and the air conditioning operating efficiency (η1) exceeds the reference operating efficiency (η0). If not, the humidity control device is characterized in that, in the simple ventilation operation, the air volume of the air supply fan (23) is set to the first air volume (Q1).

  In the second aspect of the invention, when the air-conditioning operation efficiency (η1) exceeds the standard operation efficiency (η0), the air volume of the supply fan (23) is set to the second air volume (Q2), so that the air supply in the simple ventilation operation is achieved. The air volume of the air fan (23) can be increased effectively. Thereby, the air conditioning capability of the humidity control apparatus (10) can be effectively increased in the simple ventilation operation.

  A third invention is the humidity control apparatus according to the first or second invention, wherein the second air volume (Q2) is variable.

  In the third aspect, by making the second air volume (Q2) variable, the amount of increase in the air volume of the air supply fan (23) in the simple ventilation operation can be arbitrarily set. Thereby, the air-conditioning capability of the humidity control apparatus (10) in simple ventilation operation can be increased appropriately.

  In a fourth aspect based on the first aspect, the fan control section (43) increases the air volume of the air supply fan (23) from the first air volume (Q1) to the second air volume (Q2). The air conditioning operation efficiency (η1) obtained by dividing the increase in air conditioning capacity (ΔΦ) of the humidity control apparatus by the increase in power consumption (ΔW) of the humidity control apparatus is a predetermined reference operation efficiency ( The second air volume (Q2) is determined so as to be η0), and the air volume of the supply fan (23) is set to the second air volume (Q2) in the simple ventilation operation. It is.

  In the fourth aspect of the invention, by determining the second air volume (Q2) so that the air-conditioning operation efficiency (η1) becomes the standard operation efficiency (η0), the air volume of the air supply fan (23) is effective in the simple ventilation operation. Can be increased. Thereby, the air conditioning capability of the humidity control apparatus (10) can be effectively increased in the simple ventilation operation.

  According to a fifth invention, in any one of the first to fourth inventions, the compressor (30) and the first and second adsorption heat exchangers (31, 32) having an adsorbent supported on the surface thereof. The compressor (30) is driven, the first adsorption heat exchanger (31) becomes a condenser, humidifies the air, and the second adsorption heat exchanger (32) becomes an evaporator. The first refrigeration cycle operation for dehumidifying the air, the compressor (30) is driven, the first adsorption heat exchanger (31) serves as an evaporator to dehumidify the air, and the second adsorption heat exchanger (32 ) Serves as a condenser and performs a second refrigeration cycle operation for humidifying air, and the humidity control section (50) includes the first and second adsorption heat exchangers (31, 32). In the humidity control operation, the compressor (30) and the air supply fan (23) are driven, and the refrigerant circuit (21) is operated in the first refrigeration cycle and the second refrigeration. When the first refrigeration cycle operation is performed, air that has passed through one of the first and second adsorption heat exchangers (31, 32) is supplied indoors and the second operation is performed. When the refrigeration cycle operation is performed, the air passing through the other of the first and second adsorption heat exchangers (31, 32) is supplied to the room, and the compressor (30) is stopped in the simple ventilation operation. In this state, the air supply fan (23) is driven, and air taken in from the outside passes through one of the first and second adsorption heat exchangers (31, 32) and is supplied indoors. The humidity control apparatus characterized by the above.

  In the fifth aspect of the invention, when the compressor (30) is driven, humidity control (adjustment of air humidity) is performed in the first and second adsorption heat exchangers (31, 32), and the compressor (30 ) Is stopped, the humidity control process is stopped in the first and second adsorption heat exchangers (31, 32). That is, by driving / stopping the compressor (30), the humidity control section (50) constituted by the first and second adsorption heat exchangers (31, 32) can be driven / stopped.

  According to the first invention, since the air conditioning capability (cooling capability or heating capability) of the humidity control apparatus can be increased, indoor air conditioning (cooling or heating) can be promoted in the simple ventilation operation.

  According to the second aspect of the invention, the air conditioning capability of the humidity control apparatus (10) can be effectively increased in the simple ventilation operation, so that indoor air conditioning can be effectively promoted.

  According to the third aspect of the invention, since the air conditioning capability of the humidity control apparatus (10) in the simple ventilation operation can be appropriately increased, indoor air conditioning can be appropriately promoted.

  According to the fourth aspect of the present invention, the air conditioning capacity of the humidity control apparatus (10) can be effectively increased in the simple ventilation operation, so that indoor air conditioning can be effectively promoted.

  According to the fifth aspect of the present invention, the humidity control section (50) constituted by the first and second adsorption heat exchangers (31, 32) is driven / stopped by driving / stopping the compressor (30). Therefore, the humidity control section (50) can be driven in the humidity control operation, and the humidity control section (50) can be stopped in the simple ventilation operation.

The piping system figure which showed the structural example of the humidity control apparatus by Embodiment 1. FIG. Schematic which showed the example of installation of a humidity control apparatus. The schematic perspective view which showed the external appearance of the humidity control apparatus. The schematic perspective view which showed the internal structure of the humidity control apparatus. The schematic partial perspective view which showed the internal structure of the lower part of a humidity control apparatus. The schematic partial perspective view which showed the internal structure of the intermediate part of a humidity control apparatus. The schematic partial perspective view which showed the internal structure of the upper part of a humidity control apparatus. The figure for demonstrating the operation | movement by the operation mode determination part. 3 is a flowchart showing air volume setting processing in the first embodiment. The graph which showed the relationship between fan rotation speed, fan air volume, and power consumption. The graph which showed the relationship between fan air volume, air-conditioning capacity increase, and power consumption increase. 9 is a flowchart showing air volume setting processing in the second embodiment.

  Hereinafter, embodiments will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and description thereof will not be repeated.

(Embodiment 1)
1 and 2 show a configuration example and an installation example of the humidity control apparatus (10) according to the first embodiment. The humidity control device (10) performs indoor humidity adjustment and indoor ventilation, sucks outdoor air (OA) from outside and supplies supply air (SA) to the room, and also supplies indoor air ( RA) is sucked in and exhaust air (EA) is discharged outside the room. Moreover, the humidity control apparatus (10) is installed in the building (for example, detached house) with the air conditioner (80). The air conditioner (80) includes an indoor unit (81) and an outdoor unit (82), and is configured to selectively perform indoor cooling and heating.

  In this example, the humidity controller (10) includes a casing (11), a refrigerant circuit (21), a flow path switching mechanism (22), an air supply fan (23), an exhaust fan (24), An air filter (25) and a controller (40) are provided. The refrigerant circuit (21) is accommodated in the casing (11), and the flow path switching mechanism (22) is provided in the casing (11). The humidity control device (10) is provided with an outside air temperature sensor (51), an outside air humidity sensor (52), an inside air temperature sensor (53), and an inside air humidity sensor (54).

[Refrigerant circuit]
The refrigerant circuit (21) performs a refrigeration cycle operation by circulating refrigerant, and includes a compressor (30), first and second adsorption heat exchangers (31, 32) carrying an adsorbent, An expansion valve (33) and a four-way switching valve (34) are provided. And the refrigerant circuit (20) is comprised so that 1st refrigeration cycle operation | movement and 2nd refrigeration cycle operation | movement can be performed. In the first refrigeration cycle operation, the first adsorption heat exchanger (31) serves as an evaporator to dehumidify air, and the second adsorption heat exchanger (32) serves as a condenser to humidify the air. In the second refrigeration cycle operation, the first adsorption heat exchanger serves as a condenser to humidify the air, and the second adsorption heat exchanger (32) serves as an evaporator to dehumidify the air. In the following description, the generic name of the first and second adsorption heat exchangers (31, 32) is simply referred to as “adsorption heat exchanger (31, 32)”.

《Compressor》
The compressor (30) compresses and discharges the refrigerant, and is configured to be able to change its operating frequency (rotation speed). For example, the compressor (30) is constituted by a variable capacity compressor (rotary, swing, scroll, etc. compressor) whose operating frequency can be adjusted by an inverter circuit (not shown).

《Adsorption heat exchanger》
The adsorption heat exchanger (31, 32) is configured by supporting an adsorbent on the surface of a heat exchanger (for example, a cross fin type fin-and-tube heat exchanger). The adsorbent may be composed of zeolite, silica gel, activated carbon, an organic polymer material having a hydrophilic functional group, or a material having not only a function of adsorbing moisture but also a function of absorbing moisture (so-called so-called , A sorbent).

《Expansion valve》
The expansion valve (33) is provided between the liquid ends of the first and second adsorption heat exchangers (31, 32). The expansion valve (33) is configured such that its opening degree can be adjusted, and the pressure and flow rate of the refrigerant are adjusted by adjusting the opening degree. For example, the expansion valve (33) is configured by an electronic expansion valve (motor valve).

<4-way switching valve>
The four-way switching valve (34) has first to fourth ports, the first port is connected to the discharge pipe of the compressor (30), and the second port is connected to the suction pipe of the compressor (30). The third port is connected to the gas end of the second adsorption heat exchanger (32), and the fourth port is connected to the gas end of the first adsorption heat exchanger (31). The four-way switching valve (34) has a first communication state (state shown by a solid line in FIG. 1) in which the first port and the third port communicate with each other and the second port and the fourth port communicate with each other. The first port and the fourth port communicate with each other, and the second port and the third port communicate with each other. The second communication state (the state indicated by the broken line in FIG. 1) can be set.

<< First refrigeration cycle operation >>
In the first refrigeration cycle operation, the four-way switching valve (34) is set to the first communication state (the state indicated by the solid line in FIG. 1), the compressor (30) is set to the driving state, and the expansion valve (33). Is adjusted to a predetermined opening. Thereby, in a refrigerant circuit (21), a 1st adsorption heat exchanger (31) becomes a condenser and a 2nd adsorption heat exchanger (32) becomes an evaporator. Specifically, the refrigerant discharged from the compressor (30) passes through the four-way switching valve (34), and then dissipates heat and condenses in the first adsorption heat exchanger (31). Thereby, in the first adsorption heat exchanger (31), the adsorbent is heated by the heat radiation of the refrigerant, the moisture of the adsorbent is released into the air, and the air is humidified. The refrigerant that has passed through the first adsorption heat exchanger (31) is depressurized in the expansion valve (33), and then absorbs heat in the second adsorption heat exchanger (32) to evaporate. Thereby, in the second adsorption heat exchanger (32), the adsorbent is cooled by the heat absorption of the refrigerant, moisture in the air is adsorbed by the adsorbent, and the air is dehumidified. The refrigerant that has passed through the second adsorption heat exchanger (32) passes through the four-way switching valve (34), and then is sucked into the compressor (30) and compressed.

<< Second refrigeration cycle operation >>
In the second refrigeration cycle operation, the four-way switching valve (34) is set to the second communication state (the state indicated by the broken line in FIG. 1), the compressor (30) is set to the driving state, and the expansion valve (33). Is adjusted to a predetermined opening. Thereby, in a refrigerant circuit (21), a 1st adsorption heat exchanger (31) becomes an evaporator, and a 2nd adsorption heat exchanger (32) becomes a condenser. Specifically, the refrigerant discharged from the compressor (30) passes through the four-way switching valve (34), and then dissipates heat and condenses in the second adsorption heat exchanger (32). As a result, in the second adsorption heat exchanger (32), the adsorbent is heated by the heat radiation of the refrigerant, the moisture of the adsorbent is released into the air, and the air is humidified. The refrigerant that has passed through the second adsorption heat exchanger (32) is depressurized in the expansion valve (33), and then absorbs heat in the first adsorption heat exchanger (31) to evaporate. Thereby, in the first adsorption heat exchanger (31), the adsorbent is cooled by the heat absorption of the refrigerant, moisture in the air is adsorbed by the adsorbent, and the air is dehumidified. The refrigerant that has passed through the first adsorption heat exchanger (31) passes through the four-way switching valve (34), and then is sucked into the compressor (30) and compressed.

  In this way, the air passing through the adsorption heat exchanger (31, 32), which is an evaporator, is deprived of moisture by the adsorbent of the adsorption heat exchanger (31, 32), and the humidity decreases. It is cooled by the endothermic action of the refrigerant flowing through the heat exchanger (31, 32), and the temperature also decreases. The air passing through the adsorption heat exchanger (31, 32), which is a condenser, is given moisture from the adsorbent of the adsorption heat exchanger (31, 32), and the humidity rises. Heated by the heat dissipation action of the refrigerant flowing through the vessel (31, 32), the temperature also rises. That is, the first and second adsorption heat exchangers (31, 32) constitute a humidity control section (50) that adjusts the humidity of the air.

  In addition, when the compressor (30) is set to the driving state, the first and second adsorption heat exchangers (31, 32) perform humidity conditioning (air humidity adjustment), and the compressor (30) is stopped. Is set, the humidity control process is stopped in the first and second adsorption heat exchangers (31, 32). That is, by driving / stopping the compressor (30), the humidity control section (50) constituted by the first and second adsorption heat exchangers (31, 32) can be driven / stopped.

[Flow path switching mechanism]
The flow path switching mechanism (22) includes a first path (a path indicated by a solid line in FIG. 1) and a second path (a path indicated by a broken line in FIG. 1) as air circulation paths in the humidity control apparatus (10). It is configured so that it can be set to. In this example, the flow path switching mechanism (22) has first to eighth dampers (D1 to D8) capable of switching between an open state and a closed state.

<First route>
The first, fourth, sixth and seventh dampers (D1, D4, D6, D7) are set in the open state, and the second, third, fifth, eighth dampers (D2, D3, D5, D8) ) Is set to the closed state, the air flow path in the humidity control apparatus (10) is set to the first path (the path indicated by the solid line in FIG. 1). Thereby, the outdoor air (OA) passes through the first adsorption heat exchanger (31) and is supplied indoors, and the indoor air (RA) passes through the second adsorption heat exchanger (32) and goes outside. Discharged.

<Second route>
The second, third, fifth, and eighth dampers (D2, D3, D5, and D8) are set to the open state, and the first, fourth, sixth, and seventh dampers (D1, D4, D6, and D7) are set. ) Is set to the closed state, the air flow path in the humidity control apparatus (10) is set to the second path (path indicated by the broken line in FIG. 1). Thus, outdoor air (OA) passes through the second adsorption heat exchanger (32) and is supplied indoors, and indoor air (RA) passes through the first adsorption heat exchanger (31) and goes outside. Discharged.

[Air supply fan]
The air supply fan (23) is configured to supply air into the room. In addition, the air supply fan (23) is configured to be able to change the amount of air blown. Specifically, the air supply fan (23) is configured to be able to change its rotational speed, and the amount of blown air is changed by changing the rotational speed. For example, the air supply fan (23) is constituted by a centrifugal multiblade fan (so-called sirocco fan).

[Exhaust fan]
The exhaust fan (24) is configured to exhaust air to the outside. Further, the exhaust fan (24) is configured to be able to change the amount of air blown. Specifically, the exhaust fan (24) is configured to be able to change its rotational speed, and the amount of blown air is changed by changing the rotational speed. For example, the exhaust fan (24) is constituted by a centrifugal multiblade fan (so-called sirocco fan).

(Air supply filter)
The air supply filter (25) is configured to clean air. Specifically, the air supply filter (25) is configured by a net-like member, and traps dust in the air to clean the air.

[Various sensors]
The outdoor temperature sensor (51) is configured to detect the temperature of outdoor air (OA). The outdoor air humidity sensor (52) is configured to detect the humidity (relative humidity) of outdoor air (OA). The room temperature sensor (53) is configured to detect the temperature of the room air (RA). The room air humidity sensor (54) is configured to detect the humidity (relative humidity) of the room air (RA).

[Structure of humidity control device]
Next, the structure of the humidity control apparatus (10) will be described with reference to FIGS. Note that “upper”, “lower”, “left”, “right”, “front”, and “rear” used in the following description mean directions when the casing (11) is viewed from the front side. 3 is a schematic perspective view showing the appearance of the humidity control apparatus (10) viewed from the upper left front, and FIG. 4 is an internal structure (casing (11) of the humidity control apparatus (10) viewed from the upper left front. It is the schematic perspective view which showed the structure in (). FIG. 5 and FIG. 6 are schematic partial perspective views showing the internal structure of the lower part and the middle part of the humidity control device (10) as viewed from the upper left front, and FIG. 7 shows the humidity control device (10 from the rear upper right). It is the general | schematic fragmentary perspective view which showed the internal structure of the upper part. For simplification of illustration, the outside air temperature sensor (51), the outside air humidity sensor (52), the inside air temperature sensor (53), and the inside air humidity sensor (54) are not shown in FIGS. . Further, in FIG. 7, the first to eighth dampers (D1 to D8), the air supply fan (23), and the exhaust fan (24) are omitted.

<casing>
As shown in FIG. 3, the casing (11) is formed in a vertically long rectangular parallelepiped box shape. The top plate of the casing (11) is provided with an outside air connection port (61), an inside air connection port (62), an air supply connection port (63), and an exhaust connection port (64). The outside air connection port (61) is arranged on the left rear side, and communicates with the outdoor space via an outside air duct (not shown). The room air connection port (62) is disposed on the left front side and communicates with the indoor space via a room air duct (not shown). The air supply connection port (63) is disposed on the right front side, and communicates with the indoor space via an air supply duct (not shown). The exhaust connection port (64) is disposed on the right rear side, and communicates with the outdoor space via an exhaust duct (not shown). With such a configuration, outdoor air (OA) is sucked into the outdoor air connection port (61) from the outside, and indoor air (RA) is sucked into the indoor air connection port (62) from the room. Further, supply air (SA) is blown into the room from the air supply connection port (63), and exhaust air (EA) is blown out from the exhaust connection port (64) to the outside of the room.

<First and second upper and lower partition plates>
As shown in FIG. 4, first and second upper and lower partition plates (101, 102) are provided in the casing (11). The first and second upper and lower partition plates (101, 102) are arranged at predetermined intervals in the vertical direction, and divide the internal space of the casing (11) into three spaces in the vertical direction. The first upper and lower partition plates (101) are disposed near the bottom plate of the casing (11), and the second upper and lower partition plates (102) are disposed near the top plate of the casing (11). With such a configuration, the space sandwiched between the bottom plate of the casing (11) and the first upper and lower partition plates (101) constitutes the lower space (S1), and the first upper and lower partition plates (101) and the second partition plate (101). The space sandwiched between the upper and lower partition plates (102) constitutes an intermediate space (S2), and the space sandwiched between the second upper and lower partition plates (102) and the top plate of the casing (11) is the upper part. It constitutes a space (S3).

<duct>
A duct (60) is accommodated in the casing (11). The duct (60) passes through the left rear part of the first and second upper and lower partition plates (101, 102) along the left rear corner of the casing (11) and extends vertically from the top plate to the bottom plate of the casing (11). It extends to. The upper end portion of the duct (60) opens upward and communicates with the outside air connection port (61). An opening that opens forward is formed at the lower end of the duct (60).

<Lower space>
As shown in FIG. 5, the lower partition (103) is provided in the lower space (S1). The lower partition plate (103) is formed in a flat plate shape that extends vertically from the bottom plate of the casing (11) to the lower surface of the first upper and lower partition plate (101), and is bent in an L shape in plan view in the vertical direction. Yes. The lower partition plate (103) has one end edge (left end edge) connected to the left plate of the casing (11) and the other end edge (front end edge) connected to the front plate of the casing (11). The space (S1) is divided into two spaces in plan view in the vertical direction. With such a configuration, the space facing the front surface and the left surface of the lower partition plate (103) forms the filter chamber (S11), and the space facing the rear surface and the right surface of the lower partition plate (103) is the machine chamber (S12). Is configured.

<Filter room>
A lower guide plate (104) is provided in the filter chamber (S11). The lower guide plate (104) is formed in a flat plate shape extending in the front-rear direction from one plate surface portion (plate surface portion extending in the left-right direction) of the lower partition plate (103) to the front plate of the casing (11). A space along the left plate is vertically divided. Specifically, one side edge (right side edge) of the lower guide plate (104) is connected to the left plate of the casing (11), and the other side edge (left side edge) is the other plate of the lower partition plate (103). It faces the surface portion (plate surface portion extending in the front-rear direction) with a predetermined interval. The lower end portion of the duct (60) is sandwiched between the rear plate of the casing (11) and the one plate surface portion of the lower partition plate (103). A communication port (103a) for communicating the lower space of the lower guide plate (104) and the opening of the duct (60) is formed on one plate surface portion of the lower partition plate (103). With such a configuration, the air flowing into the filter chamber (S11) from the duct (60) through the communication port (103a) bypasses the lower guide plate (104) and is directed upward to the filter chamber (S11). Flowing.

《Air supply filter, outside air temperature sensor, outside air humidity sensor》
The filter chamber (S11) is provided with an air supply filter (25), an outside air temperature sensor (51), and an outside air humidity sensor (52). The air supply filter (25) passes through the air supply filter (25) from the duct (60) through the communication port (103a) through the communication port (103a) and passes above the filter chamber (S11). It arrange | positions under the lower guide plate (104) so that it may flow toward. The outdoor air temperature sensor (51) is installed on the downstream side of the air supply filter (25), and detects the temperature of air at the installation location as the temperature of outdoor air (OA). The outdoor air humidity sensor (52) is installed on the downstream side of the air supply filter (25), and detects the humidity of the air at the installation location as the humidity of the outdoor air (OA).

"machine room"
A compressor (30), a four-way selector valve (34), and an electrical component box (65) are installed in the machine room (S12). In the electrical component box (65), a printed circuit board provided with an electric circuit (for example, a power supply circuit for driving the motor of the compressor (30)) or an electric circuit provided on the printed circuit board is electrically connected. An electrical component (for example, a reactor) to be connected is accommodated.

<Intermediate space>
As shown in FIG. 6, the intermediate space (S2) is provided with first and second intermediate left and right partition plates (105, 106), first and second intermediate wall portions (107, 108), and an intermediate front and rear partition plate (109). It has been.

  The first and second intermediate left and right partition plates (105, 106) are formed in a flat plate shape extending forward and backward from the front plate to the rear plate of the casing (11). The first and second intermediate left and right partition plates (105, 106) are arranged at predetermined intervals in the left and right direction, and the space along the upper surface of the first upper and lower partition plate (101) is divided into three spaces in the left and right direction. It is partitioned. The first intermediate left and right partition plates (105) are disposed near the left plate of the casing (11), and the second intermediate left and right partition plates (106) are disposed near the right plate of the casing (11).

  The first and second intermediate wall portions (107, 108) are formed in a rectangular parallelepiped shape extending in the front-rear direction from the front plate to the rear plate of the casing (11). The first and second intermediate wall portions (107, 108) are arranged at a predetermined interval in the left-right direction, the first intermediate wall portion (107) is connected to the left plate of the casing (11), and the second intermediate wall portion The wall (108) is connected to the right plate of the casing (11). Further, the first intermediate wall portion (107) is sandwiched between the upper end edge of the first intermediate left and right partition plate (105) and the lower surface of the second upper and lower partition plate (102), and the second intermediate wall portion (108). Is sandwiched between the upper edge of the second intermediate left and right partition plate (106) and the lower surface of the second upper and lower partition plate (102).

  The intermediate front / rear partition plate (109) is formed in a flat plate shape extending vertically from the upper surface of the first upper / lower partition plate (101) to the lower surface of the second upper / lower partition plate (102). A space surrounded by the plates (105, 106) and the first and second intermediate wall portions (107, 108) is divided forward and backward.

  With the configuration as described above, the space facing the front surface of the intermediate front and rear partition plate (109) forms the first humidity control chamber (S21), and the space facing the rear surface of the intermediate front and rear partition plate (109) is the second control chamber. The space that constitutes the wet chamber (S22) and faces the left side of the first intermediate left and right partition plate (105) constitutes the outside air communication chamber (S23) and faces the right side of the second intermediate left and right partition plate (106) Constitutes the exhaust communication chamber (S24).

  In addition, the left front part of the first upper and lower partition plates (101) is formed with a notch for communicating the outside air communication chamber (S23) and the filter chamber (S11). A notch constituting an exhaust passage (S25) communicating with the exhaust communication chamber (S24) is formed in the right rear portion of the second upper and lower partition plate (102) and the right rear portion of the second intermediate wall portion (108). . A notch through which the duct (60) is inserted is formed in the left rear portion of the first vertical partition plate (101), the left rear portion of the second vertical partition plate (102), and the left rear portion of the first intermediate wall portion (107). Is formed.

《First to fourth damper》
The first intermediate left and right partition plates (105) are provided with first and second dampers (D1, D2), and the second intermediate left and right partition plates (106) are provided with third and fourth dampers (D3, D2). D4) is installed. The first damper (D1) is disposed closer to the front than the intermediate front / rear partition plate (109), and the second damper (D2) is disposed closer to the rear than the intermediate front / rear partition plate (109). The third damper (D3) is disposed closer to the front than the intermediate front / rear partition plate (109), and the fourth damper (D4) is disposed closer to the rear than the intermediate front / rear partition plate (109).

<< First and second adsorption heat exchangers >>
The first and second humidity control chambers (S21, S22) are provided with first and second adsorption heat exchangers (31, 32), respectively. The first and second adsorption heat exchangers (31, 32) are formed in a flat rectangular parallelepiped shape, and in a posture parallel to the first and second upper and lower partition plates (101, 102), the first intermediate wall (107) It is sandwiched between the second intermediate wall portion (108).

<Upper space>
As shown in FIGS. 4 and 7, the upper space (S3) is provided with an upper left and right partition plate (110), an upper front and rear partition plate (111), and an upper auxiliary partition plate (112).

  The upper left and right partition plates (110) are formed in a flat plate shape extending forward and backward from the front plate to the rear plate of the casing (11), and divide the upper space (S3) to the left and right. Specifically, the upper left and right partition plates (110) are composed of a lower vertical plate portion (110a), a horizontal plate portion (110b), and an upper vertical plate portion (110c). The lower vertical plate portion (110a) extends upward from the central portion in the left-right direction of the second upper and lower partition plate (102), and divides a space along the upper surface of the second upper and lower partition plate (102) into the left and right. Yes. The horizontal plate portion (110b) extends leftward from the upper end edge of the lower vertical plate portion (110a). The upper vertical plate portion (110c) extends upward from the left end edge of the horizontal plate portion (110b), and divides a space along the top plate of the casing (11) to the left and right. The upper end of the duct (60) is sandwiched between the upper left and right partition plates (110) and the left plate of the casing (11).

  The upper front and rear partition plates (111) are formed in a flat plate shape extending from the right surface of the upper left and right partition plates (110) to the right plate of the casing (11), and the upper left and right partition plates (110) and the casing (11) A space sandwiched between the right plate and the front is divided forward and backward. The upper auxiliary partition plate (112) is formed in a flat plate shape extending in the front-rear direction from the rear surface of the upper front / rear partition plate (111) to the rear plate of the casing (11). The upper auxiliary partition plate (112) is bent in an L shape in a plan view in the front-rear direction, one end edge (lower end edge) is connected to the upper surface of the second upper and lower partition plate (102), and the other end edge ( The left edge) is connected to the right side of the upper left and right partition plates (110).

  With the above configuration, the internal space at the upper end of the duct (60) constitutes the outside air suction chamber (S31), and the space facing the front surface of the duct (60) and the left surface of the upper vertical plate (110c) The space that forms the inside air suction chamber (S32) and faces the right side of the upper vertical plate (110c) and the front of the upper front and rear partition plates (111) forms the indoor air supply chamber (S33), and the upper vertical plate The space facing the right surface of (110c) and the rear surface of the upper front and rear partition plate (111) constitutes the outdoor exhaust chamber (S34). The space facing the right surface of the lower vertical plate portion (110a) and the upper surface of the second upper and lower partition plate (102) constitutes the air supply communication chamber (S35), and the left surface of the lower vertical plate portion (110a). And the space facing the upper surface of the second upper and lower partition plate (102) constitutes the inside air communication chamber (S36).

  The outside air suction chamber (S31) communicates with the outside air communication chamber (S23) through the internal space of the duct (60) and the filter chamber (S11), and the inside air suction chamber (S32) communicates with the inside air communication chamber (S36). Communicate. The indoor air supply chamber (S33) communicates with the air supply communication chamber (S35), and the outdoor exhaust chamber (S34) communicates with the exhaust communication chamber (S24) through the exhaust passage (S25).

<< 5th to 8th damper >>
The second upper and lower partition plates (102) are provided with fifth to eighth dampers (D5 to D8). The fifth damper (D5) is disposed to the left of the upper left and right partition plates (110) and to the front of the intermediate front and rear partition plates (109), and the sixth damper (D6) is disposed to the upper left and right partition plates (110). ) And further to the left than the intermediate front and rear partition plates (109). The seventh damper (D7) is disposed more to the right than the upper left and right partition plates (110) and closer to the front than the middle front and rear partition plates (109), and the eighth damper (D8) is disposed on the upper left and right partition plates (110). ) And further to the right than the intermediate front and rear partition plates (109).

《Air supply fan, exhaust fan》
An air supply fan (23) is installed in the indoor air supply chamber (S33), and an exhaust fan (24) is installed in the outdoor exhaust chamber (S34). The air supply fan (23) is arranged to blow out the air sucked from the indoor air supply chamber (S33) as supply air (SA) to the air supply connection port (63), and the exhaust fan (24) is an outdoor exhaust chamber. It arrange | positions so that the air suck | inhaled from (S34) may be blown out to exhaust connection port (64) as exhaust air (EA).

《Inside air temperature sensor, Inside air humidity sensor》
Further, an inside air temperature sensor (53) and an inside air humidity sensor (54) are installed in the inside air communication chamber (S36) (not shown). The room temperature sensor (53) is installed in the vicinity of the fifth and sixth dampers (D5, D6), and detects the temperature of the air at the installation location as the temperature of the room air (RA). The room air humidity sensor (54) is installed in the vicinity of the fifth and sixth dampers (D5, D6), and detects the humidity of the air at the installation location as the humidity of the room air (RA).

<First route>
The first, fourth, sixth and seventh dampers (D1, D4, D6, D7) are set in the open state, and the second, third, fifth, eighth dampers (D2, D3, D5, D8) ) Is set to the closed state, the outside air communication chamber (S23), the first humidity control chamber (S21), and the air supply communication chamber (S35) communicate with each other, and the inside air communication chamber (S36) and the second humidity control chamber (S22) communicates with the exhaust communication room (S24). As a result, a first route (route indicated by a solid line in FIG. 1) is configured. That is, the outdoor air (OA) sucked into the outside air suction chamber (S31) from the outside is the internal space of the duct (60), the filter chamber (S11), the inside air communication chamber (S36), and the first humidity control chamber (S21). And the air supply communication chamber (S35) and the indoor air supply chamber (S33) are sequentially passed through and supplied to the room as supply air (SA). On the other hand, the room air (RA) sucked into the room air suction room (S32) from the room is the room air communication room (S36), the second humidity control room (S22), the air communication room (S24), and the air passage (S25). It passes through the outdoor exhaust chamber (S34) in order, and is discharged out of the room as exhaust air (EA).

<Second route>
The second, third, fifth, and eighth dampers (D2, D3, D5, and D8) are set to the open state, and the first, fourth, sixth, and seventh dampers (D1, D4, D6, and D7) are set. ) Is set to the closed state, the outside air communication chamber (S23), the second humidity control chamber (S22) and the air supply communication chamber (S35) communicate with each other, and the inside air communication chamber (S36) and the first humidity control chamber (S21) communicates with the exhaust communication room (S24). As a result, a second route (route indicated by a solid line in FIG. 1) is configured. That is, the outdoor air (OA) sucked into the outside air suction chamber (S31) from the outside is the internal space of the duct (60), the filter chamber (S11), the inside air communication chamber (S36), and the second humidity control chamber (S22). And the air supply communication chamber (S35) and the indoor air supply chamber (S33) are sequentially passed through and supplied to the room as supply air (SA). On the other hand, the room air (RA) sucked into the room air suction room (S32) from the room is the room air communication room (S36), the first humidity control room (S21), the air communication room (S24), and the air passage (S25). It passes through the outdoor exhaust chamber (S34) in order, and is discharged out of the room as exhaust air (EA).

〔controller〕
The controller (40) receives detection values of various sensors (inside air humidity sensor (54), inside air temperature sensor (53), outside air humidity sensor (52), outside air temperature sensor (51)). The controller (40) also receives detection values of other various sensors such as a refrigerant temperature sensor and a refrigerant pressure sensor (not shown) provided in the refrigerant circuit (21). Further, the controller (40) includes a signal indicating the operating state of the air conditioner (80) (for example, a signal indicating whether or not the air conditioner (80) is operating, and the operation of the air conditioner (80)). A signal indicating whether the operation is cooling or heating). The controller (40) controls the operation of the humidity control apparatus (10) based on these detection values and signals. In this example, the controller (40) includes an operation mode determination unit (41), an operation control unit (42), a fan control unit (43), and a storage unit (44).

<Operation mode determination unit>
An operation mode determination part (41) determines the operation (operation mode) which a humidity control apparatus (10) should perform. In this example, the humidity control apparatus (10) selectively performs a humidifying operation, a dehumidifying operation, a heating operation, a cooling operation, and a simple ventilation operation. The humidification operation and the dehumidification operation are humidity control operations for adjusting the humidity (absolute humidity) of air. The heating operation and the cooling operation are sensible heat treatment operations for adjusting the air temperature. The simple ventilation operation is an operation for ventilating the room. And an operation mode determination part (41) selects the operation which a humidity control apparatus (10) should perform from these operations. The operation by the operation mode determination unit (41) will be described in detail later.

<Operation control unit>
The operation control unit (42) controls the refrigerant circuit (21) and the flow path switching mechanism (22) in response to the determination of the operation mode by the operation mode determination unit (41). Specifically, the operation control unit (42) controls the compressor (30), the expansion valve (33), the four-way switching valve (34), and the first to eighth dampers (D1 to D8). The operation by the operation control unit (42) will be described in detail later.

<Fan control unit>
The fan control unit (43) controls the supply fan (23) and the exhaust fan (24) in response to the determination of the operation mode by the operation mode determination unit (41). The operation by the fan control unit (43) will be described in detail later.

<Storage unit>
The storage unit (44) includes data used for control of the humidity control device (10) (for example, target values for various parameter values, function expressions for calculating control values and target values used for control, and various parameters). A correspondence table showing the correspondence between values).

[Operation by the operation mode determination unit]
Next, the operation by the operation mode determination unit (41) will be described with reference to FIG. An operation mode determination part (41) determines the operation which a humidity control apparatus (10) should perform every time predetermined | prescribed determination time (for example, 10 minutes) passes. In the following explanation, the absolute humidity of outdoor air (OA) is described as “outdoor absolute humidity”, the absolute humidity of indoor air (RA) is described as “indoor absolute humidity”, and the target of indoor air (RA) The absolute humidity is described as “target absolute humidity”, the temperature of outdoor air (OA) is described as “outdoor temperature”, and the temperature of indoor air (RA) is described as “room temperature”. The outdoor absolute humidity can be calculated based on the detection value of the outdoor air humidity sensor (52) and the detection value of the outdoor air temperature sensor (51). It is possible to calculate based on the detected value and the detected value of the inside air temperature sensor (53). The target absolute humidity can be calculated based on the target temperature of the room air (RA) and the target relative humidity of the room air (RA). The outdoor air temperature is detected by the outdoor air temperature sensor (51), and the indoor air temperature is detected by the indoor air temperature sensor (53).

  First, an operation mode determination part (41) determines the success or failure of condition (1-1). The condition (1-1) is a condition that “the outdoor absolute humidity is equal to or higher than the target absolute humidity and the outdoor absolute humidity is equal to or higher than a predetermined reference humidity (9 g / kg (DA) in this example)”. .

  When the condition (1-1) is satisfied, the operation mode determination unit (41) determines whether the condition (2-1) and the condition (2-2) are satisfied. Condition (2-1) is a condition that “the target frequency of the compressor (30) is equal to or higher than the minimum frequency”, and condition (2-2) is that “the target frequency of the compressor (30) is less than the minimum frequency. It is a condition of “is”. The target frequency of the compressor (30) is set based on detection values of various sensors. The minimum frequency of the compressor (30) corresponds to the lower limit value of the adjustment range of the operating frequency of the compressor (30).

  When the condition (2-1) is satisfied, the operation mode determination unit (41) selects the dehumidifying operation as an operation to be performed by the humidity control apparatus (10). On the other hand, when the condition (2-2) is satisfied, the operation mode determination unit (41) determines whether the condition (3-2) and the condition (3-3) are satisfied. The condition (3-2) is a condition that “the outdoor temperature is equal to or higher than the room temperature”, and the condition (3-3) is a condition that “the outdoor temperature is less than the room temperature”.

  When the condition (3-2) is satisfied, the operation mode determination unit (41) selects the cooling operation as an operation to be performed by the humidity control apparatus (10). On the other hand, when the condition (3-3) is satisfied, the operation mode determination unit (41) selects the simple ventilation operation as the operation to be performed by the humidity control apparatus (10).

  When the condition (1-1) is not satisfied, the operation mode determination unit (41) determines whether the condition (1-4) is satisfied. The condition (1-4) is a condition that “the outdoor absolute humidity is equal to or lower than the target absolute humidity and the outdoor absolute humidity is equal to or lower than a predetermined reference humidity (9 g / kg (DA) in this example)”. .

  When the condition (1-4) is satisfied, the operation mode determination unit (41) determines whether the condition (2-4) and the condition (2-5) are satisfied. The condition (2-4) is a condition that “the target frequency of the compressor (30) is equal to or higher than the minimum frequency”, and the condition (2-5) is “the target frequency of the compressor (30) is less than the minimum frequency” It is a condition of “is”.

  When the condition (2-4) is satisfied, the operation mode determination unit (41) selects the humidification operation as an operation to be performed by the humidity control apparatus (10). On the other hand, when the condition (2-5) is satisfied, the operation mode determination unit (41) determines whether the condition (3-5) and the condition (3-6) are satisfied. The condition (3-5) is a condition that “the outdoor temperature is equal to or lower than the room temperature”, and the condition (3-6) is a condition that “the outdoor temperature exceeds the room temperature”.

  When the condition (3-5) is satisfied, the operation mode determination unit (41) selects the heating operation as an operation to be performed by the humidity control apparatus (10). On the other hand, when the condition (3-6) is satisfied, the operation mode determination unit (41) selects the simple ventilation operation as the operation to be performed by the humidity control apparatus (10).

  When the condition (1-1) and the condition (1-4) are not satisfied, the operation mode determination unit (41) determines whether the condition (1-7) is satisfied. Condition (1-7) is that “the outdoor temperature is equal to or higher than the indoor temperature, the outdoor temperature is equal to or higher than the target cooling temperature of the air conditioner (80), and the air conditioner (80) performs the cooling operation. It is a condition that

  When the condition (1-7) is satisfied, the operation mode determination unit (41) selects the cooling operation as an operation to be performed by the humidity control apparatus (10).

  When all of the condition (1-1), the condition (1-4), and the condition (1-7) are not satisfied, the operation mode determination unit (41) determines whether or not the condition (1-8) is satisfied. The condition (1-8) is “the outdoor temperature is lower than the indoor temperature, the outdoor temperature is lower than the target heating temperature of the air conditioner (80), and the air conditioner (80) performs the heating operation. It is a condition that

  When the condition (1-8) is satisfied, the operation mode determination unit (41) selects the heating operation as the operation to be performed by the humidity control apparatus (10).

  When all of the condition (1-1), the condition (1-4), the condition (1-7), and the condition (1-8) are not satisfied, the operation mode determination unit (41) Select simple ventilation operation as the operation to be performed.

[Operations by operation control unit and fan control unit]
Next, operations by the operation control unit (42) and the fan control unit (43) will be described. The operation control unit (42) and the fan control unit (43) respond to the determination of the operation mode by the operation mode determination unit (41), the refrigerant circuit (21), the flow path switching mechanism (22), and the air supply fan ( 23) and the exhaust fan (24) are controlled.

<Humidification operation>
When the humidification operation is selected as the operation to be performed by the humidity control apparatus (10), the fan control unit (43) sets the air supply fan (23) and the exhaust fan (24) to the driving state. The fan control unit (43) performs a constant air volume control operation in the humidifying operation. In the constant air volume control operation, the fan control section (43) causes the air supply fan (23) so that the air volume of the air supply fan (23) becomes a predetermined target air supply air volume (for example, the first air volume (Q1)). ) To adjust the air volume of the exhaust fan (24) so that the air volume of the exhaust fan (24) becomes a predetermined target exhaust air volume.

  When the humidifying operation is selected as the operation to be performed by the humidity control apparatus (10), the operation control unit (42) sets the compressor (30) to the driving state and opens the opening of the expansion valve (33). Adjust. The operation control unit (42) performs an operation frequency adjustment operation in the humidification operation. In the operation frequency adjustment operation, the operation control unit (42) sets the target frequency of the compressor (30) based on the detection values of various sensors, and compresses the compressor (30) so that the operation frequency becomes the target frequency. Adjust the operating frequency of the machine (30). Specifically, the operation control unit (42) includes the absolute humidity of the indoor air (RA), the absolute humidity of the outdoor air (OA), the target absolute humidity of the indoor air (RA), and the current compressor (30 ) To set the target frequency of the compressor (30). That is, when it is necessary to increase the dehumidification amount or humidification amount to bring the absolute humidity of the room air (RA) close to the target absolute humidity, the operation control unit (42) compresses the target frequency of the compressor (30) to the current compression. Set to a value higher than the operating frequency of the machine (30). On the other hand, when the absolute humidity of the room air (RA) is already at the same level as the target absolute humidity and the dehumidification amount or the humidification amount needs to be reduced, the operation control unit (42) sets the target frequency of the compressor (30). Is set to a value lower than the operating frequency of the current compressor (30). Furthermore, the operation control unit (42) alternately and repeatedly performs the first humidification operation and the second humidification operation at a predetermined time interval (for example, every 3 minutes) in the humidification operation.

  In the first humidification operation, the operation control unit (42) sets the four-way switching valve (34) to the first communication state (the state indicated by the solid line in FIG. 1). Thereby, a 1st freezing cycle operation | movement is performed in a refrigerant circuit (21), a 1st adsorption heat exchanger (31) becomes a condenser, and a 2nd adsorption heat exchanger (32) becomes an evaporator. Further, the operation control unit (42) controls the flow path switching mechanism (22) to set the air flow path in the humidity control apparatus (10) to the first path (the path indicated by the solid line in FIG. 1). . Thereby, the outdoor air (OA) taken in from the outside passes through the air supply filter (25), is purified, and passes through the first adsorption heat exchanger (31) serving as a condenser and is humidified. Then, it is supplied indoors as supply air (SA). On the other hand, the indoor air (RA) taken in from the room passes through the second adsorption heat exchanger (32) serving as an evaporator, is dehumidified, and then is discharged outside the room as exhaust air (EA).

  In the second humidification operation, the operation control unit (42) sets the four-way switching valve (34) to the second communication state (the state indicated by the broken line in FIG. 1). Thereby, a 2nd freezing cycle operation is performed in a refrigerant circuit (21), the 1st adsorption heat exchanger (31) serves as an evaporator, and the 2nd adsorption heat exchanger (32) serves as a condenser. The operation control unit (42) controls the flow path switching mechanism (22) to set the air flow path in the humidity control apparatus (10) to the second path (the path indicated by the broken line in FIG. 1). . Thereby, the outdoor air (OA) taken in from the outside passes through the air supply filter (25), is purified, and passes through the second adsorption heat exchanger (32) serving as a condenser and is humidified. Then, it is supplied indoors as supply air (SA). On the other hand, the indoor air (RA) taken in from the room passes through the first adsorption heat exchanger (31) serving as an evaporator, is dehumidified, and is then discharged to the outside as exhaust air (EA).

  Thus, in the humidification operation, the humidity control unit (50), the air supply fan (23), and the exhaust fan (24) configured by the first and second adsorption heat exchangers (31, 32) are driven, Outdoor air (OA) taken from outside is humidified (ie, humidity is adjusted) in the humidity control section (50), and air humidified (ie, air whose humidity is adjusted) is supplied in the humidity control section (50) Supplied indoors as air (SA). Further, the indoor air (RA) taken from the room is dehumidified in the humidity control section (50), and the air dehumidified in the humidity control section (50) is discharged outside as the exhaust air (EA).

<Dehumidifying operation>
When the dehumidifying operation is selected as the operation to be performed by the humidity control apparatus (10), the fan control unit (43) sets the air supply fan (23) and the exhaust fan (24) to the driving state. The fan control unit (43) performs a constant air volume control operation in the dehumidifying operation.

  When the dehumidifying operation is selected as the operation to be performed by the humidity control apparatus (10), the operation control unit (42) sets the compressor (30) to the driving state and opens the opening of the expansion valve (33). Adjust. The operation control unit (42) performs an operation frequency adjustment operation in the dehumidifying operation. Further, the operation control unit (42) repeatedly performs the first dehumidifying operation and the second dehumidifying operation alternately at a predetermined time interval (for example, every 3 minutes) in the dehumidifying operation.

  In the first dehumidifying operation, the operation control unit (42) sets the four-way switching valve (34) to the second communication state (the state indicated by the broken line in FIG. 1). Thereby, a 2nd freezing cycle operation is performed in a refrigerant circuit (21), the 1st adsorption heat exchanger (31) serves as an evaporator, and the 2nd adsorption heat exchanger (32) serves as a condenser. Further, the operation control unit (42) controls the flow path switching mechanism (22) to set the air flow path in the humidity control apparatus (10) to the first path (the path indicated by the solid line in FIG. 1). . Thereby, the outdoor air (OA) taken in from the outside passes through the air supply filter (25), is purified, and passes through the first adsorption heat exchanger (31) serving as a condenser and is dehumidified. Then, it is supplied indoors as supply air (SA). On the other hand, the indoor air (RA) taken in from the room passes through the second adsorption heat exchanger (32) serving as an evaporator, is humidified, and is then discharged to the outside as exhaust air (EA).

  In the second dehumidifying operation, the operation control unit (42) sets the four-way switching valve (34) to the first communication state (the state indicated by the solid line in FIG. 1). Thereby, a 1st freezing cycle operation | movement is performed in a refrigerant circuit (21), a 1st adsorption heat exchanger (31) becomes a condenser, and a 2nd adsorption heat exchanger (32) becomes an evaporator. The operation control unit (42) controls the flow path switching mechanism (22) to set the air flow path in the humidity control apparatus (10) to the second path (the path indicated by the broken line in FIG. 1). . Thereby, the outdoor air (OA) taken in from the outside passes through the air supply filter (25), is purified, and passes through the second adsorption heat exchanger (32) serving as a condenser and is dehumidified. Then, it is supplied indoors as supply air (SA). On the other hand, indoor air (RA) taken in from the room passes through the first adsorption heat exchanger (31) serving as an evaporator, is humidified, and is then discharged to the outside as exhaust air (EA).

  Thus, in the dehumidifying operation, the humidity control unit (50), the air supply fan (23), and the exhaust fan (24) configured by the first and second adsorption heat exchangers (31, 32) are driven, The outdoor air (OA) taken from outside is dehumidified (humidity adjusted) in the humidity control section (50), and the air dehumidified in the humidity control section (50) (that is, air whose humidity is adjusted) is supplied air ( SA) is supplied indoors. Moreover, the indoor air (RA) taken in from the room is humidified in the humidity control section (50), and the air humidified in the humidity control section (50) is discharged to the outside as exhaust air (EA).

<Heating operation>
When the heating operation is selected as the operation to be performed by the humidity control apparatus (10), the fan control unit (43) sets the air supply fan (23) and the exhaust fan (24) to the driving state. The fan control unit (43) performs a constant air volume control operation in the heating operation.

  When the dehumidifying operation is selected as the operation to be performed by the humidity control apparatus (10), the operation control unit (42) sets the compressor (30) to the driving state and opens the opening of the expansion valve (33). Adjust. The operation control unit (42) performs an operation frequency adjustment operation in the heating operation. Furthermore, the operation control unit (42) performs only one of the first heating operation and the second heating operation in the heating operation.

  In the first heating operation, similarly to the first humidifying operation, the operation control unit (42) sets the four-way switching valve (34) to the first communication state (the state shown by the solid line in FIG. 1). Thereby, a 1st freezing cycle operation | movement is performed in a refrigerant circuit (21), a 1st adsorption heat exchanger (31) becomes a condenser, and a 2nd adsorption heat exchanger (32) becomes an evaporator. Further, the operation control unit (42) controls the flow path switching mechanism (22) to set the air flow path in the humidity control apparatus (10) to the first path (the path indicated by the solid line in FIG. 1). . Thereby, outdoor air (OA) taken in from the outside passes through the air supply filter (25), is purified, and passes through the first adsorption heat exchanger (31) serving as a condenser and is heated. Then, it is supplied indoors as supply air (SA). On the other hand, the indoor air (RA) taken in from the room is cooled by passing through the second adsorption heat exchanger (32) serving as an evaporator, and then discharged to the outside as exhaust air (EA).

  In the second heating operation, similarly to the second humidification operation, the operation control unit (42) sets the four-way switching valve (34) to the second communication state (the state indicated by the broken line in FIG. 1). Thereby, a 2nd freezing cycle operation is performed in a refrigerant circuit (21), the 1st adsorption heat exchanger (31) serves as an evaporator, and the 2nd adsorption heat exchanger (32) serves as a condenser. Moreover, the flow path switching mechanism (22) is controlled to set the air circulation path in the humidity control apparatus (10) to the second path (path indicated by the broken line in FIG. 1). Thereby, the outdoor air (OA) taken in from the outside passes through the air supply filter (25), is purified, and passes through the second adsorption heat exchanger (32) serving as a condenser and is heated. Then, it is supplied indoors as supply air (SA). On the other hand, the indoor air (RA) taken in from the room passes through the first adsorption heat exchanger (31) serving as an evaporator, is cooled, and is then discharged to the outside as exhaust air (EA).

  In the first and second heating operations, the amount of moisture contained in the adsorbent of the adsorption heat exchanger (31, 32) serving as a condenser gradually decreases with time. Further, in the adsorption heat exchanger (31, 32) serving as a condenser, moisture is less likely to be released from the adsorbent into the air as the moisture content of the adsorbent decreases. When the duration time of the first and second heating operations is increased (for example, about 20 minutes), the moisture content of the adsorbent in the adsorption heat exchanger (31, 32) serving as a condenser is extremely low. As a result, almost no moisture of the adsorbent is released into the air passing through the adsorption heat exchanger (31, 32) serving as a condenser. Therefore, in the first and second heating operations, the air passing through the adsorption heat exchanger (31, 32) serving as a condenser is heated by the heat radiation action of the refrigerant flowing through the adsorption heat exchanger (31, 32). The temperature rises, but the humidity does not rise so much.

  As described above, in the heating operation, the humidity control section (50), the air supply fan (23), and the exhaust fan (24) configured by the first and second adsorption heat exchangers (31, 32) are driven, Outdoor air (OA) taken from the outside is heated (temperature adjustment) in the humidity control section (50), and air heated in the humidity control section (50) (that is, temperature-controlled air) is supplied air ( SA) is supplied indoors. Moreover, the indoor air (RA) taken in from the room is cooled in the humidity control section (50), and the air cooled in the humidity control section (50) is discharged outside the room as exhaust air (EA).

<Cooling operation>
When the cooling operation is selected as the operation to be performed by the humidity control apparatus (10), the fan control unit (43) sets the air supply fan (23) and the exhaust fan (24) to the driving state. The fan control unit (43) performs a constant air volume control operation in the cooling operation.

  When the cooling operation is selected as the operation to be performed by the humidity control apparatus (10), the operation control unit (42) sets the compressor (30) to the driving state and opens the opening of the expansion valve (33). Adjust. Further, the operation control unit (42) performs an operation frequency adjustment process in the cooling operation. Furthermore, the operation control unit (42) performs only one of the first cooling operation and the second cooling operation in the cooling operation.

  In the first cooling operation, as in the first dehumidifying operation, the operation control unit (42) sets the four-way switching valve (34) to the second communication state (the state indicated by the broken line in FIG. 1). Thus, the second refrigeration cycle operation is performed in the refrigerant circuit (21), the first adsorption heat exchanger (31) serves as a condenser, and the second adsorption heat exchanger (32) serves as an evaporator. Further, the operation control unit (42) controls the flow path switching mechanism (22) to set the air flow path in the humidity control apparatus (10) to the first path (the path indicated by the solid line in FIG. 1). . Thereby, outdoor air (OA) taken in from the outside is purified by passing through the air supply filter (25), and cooled by passing through the first adsorption heat exchanger (31) serving as an evaporator. Then, it is supplied indoors as supply air (SA). On the other hand, the indoor air (RA) taken in from the room is heated by passing through the second adsorption heat exchanger (32) serving as a condenser, and then discharged outside the room as exhaust air (EA).

  In the second cooling operation, as in the second dehumidifying operation, the operation control unit (42) sets the four-way switching valve (34) to the first communication state (the state indicated by the solid line in FIG. 1). Thereby, a 1st freezing cycle operation | movement is performed in a refrigerant circuit (21), a 1st adsorption heat exchanger (31) becomes a condenser, and a 2nd adsorption heat exchanger (32) becomes an evaporator. In the operation control unit (42), the flow path switching mechanism (22) sets the air flow path in the humidity control apparatus (10) to the second path (the path indicated by the broken line in FIG. 1). Thereby, the outdoor air (OA) taken in from the outside passes through the air supply filter (25), is purified, and passes through the second adsorption heat exchanger (32) serving as an evaporator and is cooled. Then, it is supplied indoors as supply air (SA). On the other hand, the indoor air (RA) taken in from the room passes through the first adsorption heat exchanger (31) serving as a condenser, is heated, and is then discharged to the outside as exhaust air (EA).

  In the first and second cooling operations, the amount of moisture contained in the adsorbent of the adsorption heat exchanger (31, 32) serving as an evaporator gradually increases with time. Further, in the adsorption heat exchanger (31, 32) serving as an evaporator, the moisture in the air becomes difficult to be adsorbed by the adsorbent as the moisture content of the adsorbent increases. When the duration time of the first and second cooling operations becomes longer (for example, about 20 minutes), the adsorbent of the adsorption heat exchanger (31, 32) serving as the evaporator is substantially saturated. Thus, moisture in the air passing through the adsorption heat exchanger (31, 32) serving as an evaporator is hardly adsorbed by the adsorbent. Therefore, in the first and second cooling operations, the air passing through the adsorption heat exchanger (31, 32) serving as an evaporator is cooled by the endothermic action of the refrigerant flowing through the adsorption heat exchanger (31, 32). The temperature drops, but the humidity does not drop that much.

  As described above, in the cooling operation, the humidity control unit (50), the air supply fan (23), and the exhaust fan (24) configured by the first and second adsorption heat exchangers (31, 32) are driven, Outdoor air (OA) taken from the outside is cooled (temperature adjusted) in the humidity control section (50), and air cooled in the humidity control section (50) (that is, temperature-controlled air) is supplied air ( SA) is supplied indoors. Moreover, the indoor air (RA) taken in from the room is heated in the humidity control section (50), and the air heated in the humidity control section (50) is discharged outside the room as exhaust air (EA).

<Simple ventilation operation>
When the simple ventilation operation is selected as the operation to be performed by the humidity control apparatus (10), the fan control unit (43) sets the air supply fan (23) and the exhaust fan (24) to the driving state. The fan control unit (43) sets the air volume of the air supply fan (23) to one of a predetermined first air volume (Q1) and second air volume (Q2) in simple ventilation operation. Process. The second air volume (Q2) is set to be larger than the first air volume (Q1). The air volume setting process will be described in detail later.

  When the simple ventilation operation is selected as the operation to be performed by the humidity control apparatus (10), the operation control unit (42) sets the compressor (30) to the stop state and fully opens the expansion valve (33). Set to state. Further, the operation control unit (42) fixes the four-way switching valve (34) to either one of the first communication state and the second communication state. Further, the operation control unit (42) controls the flow path switching mechanism (22) to fix the air flow path in the humidity control apparatus (10) to one of the first path and the second path.

  When the air circulation path in the humidity control apparatus (10) is fixed to the first path (the path indicated by the solid line in FIG. 1), the outdoor air (OA) taken in from the outside is supplied to the air supply filter (25 ) Through the first adsorption heat exchanger (31), and then supplied to the room as supply air (SA). On the other hand, room air (RA) taken in from the room passes through the second adsorption heat exchanger (32), and is then supplied to the outside as exhaust air (EA).

  When the air circulation path in the humidity control apparatus (10) is fixed to the second path (the path indicated by the broken line in FIG. 1), the outdoor air (OA) taken from the outside is supplied to the air supply filter (25 ) Through the second adsorption heat exchanger (32) and then supplied indoors as supply air (SA). On the other hand, room air (RA) taken in from the room passes through the first adsorption heat exchanger (31), and is then supplied to the outside as exhaust air (EA).

  Thus, in the simple ventilation operation, the air supply fan (23) is driven in a state where the humidity control section (50) constituted by the first and second adsorption heat exchangers (31, 32) is stopped, and from outside the room. The taken outdoor air (OA) is supplied indoors as supply air (SA) without adjusting the humidity in the humidity control section (50). Moreover, the indoor air (RA) taken in from the room is discharged outside the room as exhaust air (EA) without adjusting the humidity in the humidity control section (50).

  When the outdoor air (OA) humidity adjustment is unnecessary and the outdoor air temperature is lower than the indoor air temperature (for example, when the condition (3-6) is satisfied), simple ventilation operation is performed. Indoor cooling (so-called outside air cooling) can be performed supplementarily. Further, when the outdoor air (OA) humidity adjustment is unnecessary and the outdoor air temperature is higher than the indoor air temperature (for example, when the condition (3-3) is satisfied), simple ventilation operation is performed. Indoor heating (so-called outside air heating) can be performed in an auxiliary manner.

[Airflow setting operation]
Next, with reference to FIG. 9, the operation (air volume setting operation) by the fan control unit (43) will be described. The fan control unit (43) performs the air volume setting operation every time a predetermined time (for example, 10 minutes) elapses in the simple ventilation operation. The storage unit (44) stores the first air volume (Q1), the second air volume (Q2), and the reference operating efficiency (η0).

<Step (ST11)>
First, the fan control unit (43) increases the air conditioning capacity of the humidity control device (10) as the air volume of the air supply fan (23) increases from the first air volume (Q1) to the second air volume (Q2) ( ΔΦ) and the increase in power consumption (ΔW) of the humidity controller (10) due to the increase in the air volume of the air supply fan (23) from the first air volume (Q1) to the second air volume (Q2), The air conditioning operation efficiency (η1) is obtained by dividing the increase in air conditioning capacity (ΔΦ) of the humidity control device (10) by the increase in power consumption (ΔW) of the humidity control device (10).

  The amount of increase in air conditioning capacity (ΔΦ) of the humidity control device (10) is “the air conditioning capacity of the humidity control device (10) when the air volume of the air supply fan (23) is set to the first air volume (Q1)”. And “the air conditioning capacity of the humidity control apparatus (10) when the air volume of the air supply fan (23) is set to the second air volume (Q2)”. In addition, the air conditioning capacity (heating capacity or cooling capacity) of the humidity control device (10) is the temperature difference (absolute value) between the indoor air (RA) and the outdoor air (OA) and the air volume of the air supply fan (23). Tend to be proportional to Therefore, the increase amount (ΔΦ) of the air conditioning capacity of the humidity control apparatus (10) can be expressed as the following Expression 1.

  “C” is a proportional constant, “To” is the temperature of outdoor air (OA), “Tr” is the temperature of indoor air (RA), and “Q1” is the first air volume (Q1). Yes, “Q2” is the second air volume (Q2).

  The increase in power consumption (ΔW) of the humidity control device (10) is “the power consumption of the humidity control device (10) when the air flow of the air supply fan (23) is set to the first air flow (Q1) ( “First power consumption (W1))” and “Power consumption of the humidity control device (10) when the air volume of the air supply fan (23) is set to the second air volume (Q2) (second power consumption (W2)) ) ". Also, as shown in FIG. 10, the air volume of the air supply fan (23) is proportional to the rotational speed of the air supply fan (23), and the power consumption of the humidity control device (10) is that of the air supply fan (23). It tends to be proportional to the cube of the number of revolutions. Therefore, the increase amount (ΔW) of the power consumption of the humidity control apparatus (10) can be expressed as the following Expression 2.

  “D” is a proportional constant, “R1” is the first rotation speed (R1) corresponding to the first air volume (Q1), and “R2” is the second rotation corresponding to the second air volume (Q2). Number (R2).

  As described above, the amount of increase in air conditioning capacity (ΔΦ) of the humidity control apparatus (10) can be calculated based on Equation 1. Further, the amount of increase in power consumption (ΔW) of the humidity control apparatus (10) can be calculated based on Equation 2. Specifically, the fan control unit (43) selects the first air volume (Q1) and the air volume from the correspondence table in which the rotation speed of the air supply fan (23) and the air volume of the air supply fan (23) are associated with each other. Select the first rotation speed (R1) and the second rotation speed (R2) respectively corresponding to the second air volume (Q2), and calculate the amount of increase in power consumption (ΔW) of the humidity controller (10) based on Equation 2 calculate.

<Step (ST12)>
Next, the fan control unit (43) determines whether or not the air conditioning operation efficiency (η1) exceeds a predetermined reference operation efficiency (η0). The standard operating efficiency (η0) is the air conditioning operating efficiency when it is considered that the air conditioning capacity of the humidity control device (10) can be effectively increased even if the power consumption of the humidity control device (10) increases. Corresponds to (η1). For example, the reference operating efficiency (η0) is set to a positive number larger than 1. If the air-conditioning operation efficiency (η1) exceeds the reference operation efficiency (η0), the process proceeds to step (ST13). Otherwise, the process proceeds to step (ST14).

  The increase in air conditioning capacity (ΔΦ) of the humidity controller (10) is proportional to the difference between the first air volume (Q1) and the second air volume (Q2), and the power consumption of the humidity controller (10) is increased. The amount (ΔW) is proportional to the cube of the difference between the first air volume (Q1) and the second air volume (Q2). Therefore, as shown in FIG. 11, when the second air volume (Q2) is set to an air volume value between the first air volume (Q1) and the air volume threshold (Qth), the power consumption of the humidity control device (10). When the amount of air increase (ΔW) is equal to or greater than the amount of air conditioning capacity increase (ΔΦ) of the humidity control device (10), but the second air volume (Q2) is set to an air volume value greater than the air volume threshold (Qth) The amount of increase in power consumption (ΔW) of the humidity control device (10) is smaller than the amount of increase in air conditioning capacity (ΔΦ) of the humidity control device (10).

<Step (ST13)>
When the air conditioning operation efficiency (η1) exceeds the reference operation efficiency (η0), the fan control unit (43) sets the air volume of the supply fan (23) to the second air volume (Q2) in the simple ventilation operation. Specifically, the fan control unit (43) sets the target air supply amount to the second air amount (Q2), and the air supply fan (23) so that the air amount of the air supply fan (23) becomes the target air supply amount. ) Adjust the air volume (rotation speed).

<Step (ST14)>
On the other hand, if the air-conditioning operation efficiency (η1) does not exceed the standard operation efficiency (η0), the fan control unit (43) sets the air volume of the supply fan (23) to the first air volume (Q1) in the simple ventilation operation. . Specifically, the fan control unit (43) sets the target air supply amount to the first air amount (Q1), and the air supply fan (23) so that the air amount of the air supply fan (23) becomes the target air supply amount. ) Adjust the air volume.

[Effects of the embodiment]
As described above, by setting the air volume of the air supply fan (23) to the second air volume (Q2) larger than the first air volume (Q1) in the simple ventilation operation, the air conditioning capacity (cooling capacity or heating capacity) of the humidity controller is set. Ability). Thereby, indoor air conditioning (cooling or heating) can be promoted in the simple ventilation operation.

  In addition, when the air-conditioning operation efficiency (η1) exceeds the standard operation efficiency (η0), the air supply fan (23) is set to the second air volume (Q2) to set the air supply fan (23) to the air supply fan (23). Can effectively increase the air volume. Thereby, the air conditioning capability of the humidity control apparatus (10) can be effectively increased in the simple ventilation operation, and as a result, indoor air conditioning can be effectively promoted.

  Moreover, since the humidity control part (50) comprised by the 1st and 2nd adsorption heat exchanger (31,32) can be driven / stopped by driving / stopping the compressor (30), The humidity control section (50) can be set to the driving state in the wet operation, and the humidity control section (50) can be set to the stop state in the simple ventilation operation.

  The second air volume (Q2) may be variable (variable value). In this way, by making the second air volume (Q2) variable, it is possible to arbitrarily set the amount of increase in the air volume of the air supply fan (23) in the simple ventilation operation. Thereby, the air conditioning capability of the humidity control apparatus (10) in the simple ventilation operation can be appropriately increased, and as a result, indoor air conditioning can be appropriately promoted. The second air volume may be fixed (fixed value).

(Embodiment 2)
The humidity control apparatus (10) according to the second embodiment is different from the humidity control apparatus (10) according to the first embodiment in the operation (air volume setting operation) by the fan control unit (43). Other configurations are the same as the configuration of the humidity control apparatus (10) according to the first embodiment.

[Airflow setting operation]
Next, with reference to FIG. 12, the operation | movement (air volume setting operation | movement) by the fan control part (43) in Embodiment 2 is demonstrated. The fan control unit (43) performs the air volume setting operation every time a predetermined time (for example, 10 minutes) elapses in the simple ventilation operation.

<Step (ST21)>
First, the fan control unit (43) determines the second air volume (Q2) so that the air-conditioning operation efficiency (η1) becomes a predetermined reference operation efficiency (η0). The air-conditioning operation efficiency (η1) is the amount of increase in the air-conditioning capacity (ΔΦ) of the humidity controller that accompanies the increase in the air volume of the air supply fan (23) from the first air volume (Q1) to the second air volume (Q2). This corresponds to a value obtained by dividing by the amount of increase in power consumption (ΔW) of the humidity controller.

  As described above, the air volume of the air supply fan (23) tends to be proportional to the rotational speed of the air supply fan (23). Therefore, the air volume (Φ) of the air supply fan (23) can be expressed as the following Expression 3.

  “E” is a proportionality constant, and “R” is the rotation speed of the air supply fan (23).

  Further, the amount of increase in power consumption (ΔW) of the humidity control apparatus (10) can be expressed as the following Expression 4.

“F” is a proportionality constant, and F = D / E ³ .

  The air-conditioning operation efficiency (η1) can be expressed as the following formula 5.

  When Equation 5 is solved for the second air volume (Q2), the following Equation 6 is obtained.

  As described above, the second air volume (Q2) can be calculated based on Equation 6.

<Step (ST22)>
Next, the fan control unit (43) sets the air volume of the air supply fan (23) to the second air volume (second air volume (Q2 determined in step (ST21)) in the simple ventilation operation. Specifically, the fan control unit (43) sets the target air supply amount to the second air amount (Q2) determined in step (ST21), and the air amount of the air supply fan (23) is equal to the target air supply amount. Adjust the air volume (rotation speed) of the air supply fan (23) so that

[Effects of Embodiment 2]
As described above, by determining the second air volume (Q2) so that the air-conditioning operation efficiency (η1) becomes the standard operation efficiency (η0), the air volume of the supply fan (23) is effectively reduced in the simple ventilation operation. Can be increased. Thereby, the air conditioning capability of the humidity control apparatus (10) can be effectively increased in the simple ventilation operation, and as a result, indoor air conditioning can be effectively promoted.

(Other embodiments)
In the above description, the fan control unit (43) changes the air volume of the exhaust fan (24) according to the change of the air volume of the air supply fan (23) so that the atmospheric pressure in the room is kept constant. It may be configured as follows. Specifically, the fan control unit (43) increases the air volume of the supply fan (23) from the first air volume (Q1) to the second air volume (Q2), and the air volume of the exhaust fan (24) is a predetermined amount. It may be configured to decrease by (for example, the difference between the first air volume (Q1) and the second air volume (Q2)).

  The above embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

  As described above, the humidity control apparatus described above is useful as a humidity control apparatus installed in a building (for example, a detached house).

DESCRIPTION OF SYMBOLS 10 Humidity control apparatus 21 Refrigerant circuit 22 Flow path switching mechanism 23 Supply air fan 24 Exhaust fan 25 Supply filter 30 Compressor 31 1st adsorption heat exchanger 32 2nd adsorption heat exchanger 33 Expansion valve 34 Four-way switching valve 40 Controller 41 Operation mode determination unit 42 Operation control unit 43 Fan control unit 44 Storage unit 50 Humidity adjustment unit

Claims (5)

Humidity adjustment part (50) that can adjust humidity of air,
An air supply fan (23) for supplying air into the room,
A humidity control operation in which the humidity control section (50) and the air supply fan (23) are driven, and air whose humidity is adjusted in the humidity control section (50) is supplied indoors;
The air supply fan (23) is driven in a state where the humidity control section (50) is stopped, and the air taken in from the outside is supplied indoors without adjusting the humidity in the humidity control section (50). A humidity control device that performs simple ventilation operation,
In the simple ventilation operation, the air volume of the supply fan (23) is set to one of a predetermined first air volume (Q1) and a second air volume (Q2) greater than the first air volume (Q1). A humidity control apparatus comprising a fan control unit (43). In claim 1,
The fan control unit (43) is configured to increase an air conditioning capacity of the humidity control apparatus as the air volume of the air supply fan (23) increases from the first air volume (Q1) to the second air volume (Q2) ( When the air conditioning operation efficiency (η1) obtained by dividing ΔΦ) by the increase in power consumption (ΔW) of the humidity control device exceeds a predetermined reference operation efficiency (η0), the simple ventilation operation When the air volume of the air supply fan (23) is set to the second air volume (Q2) and the air conditioning operation efficiency (η1) does not exceed the reference operation efficiency (η0), the air supply fan in the simple ventilation operation A humidity control apparatus, wherein the air volume of (23) is set to the first air volume (Q1). In claim 1 or 2,
The humidity control apparatus characterized in that the second air volume (Q2) is variable. In claim 1,
The fan control unit (43) is configured to increase an air conditioning capacity of the humidity control apparatus as the air volume of the air supply fan (23) increases from the first air volume (Q1) to the second air volume (Q2) ( The second air volume (Q2) so that the air-conditioning operation efficiency (η1) obtained by dividing ΔΦ) by the increase in power consumption (ΔW) of the humidity control apparatus becomes a predetermined reference operation efficiency (η0). And the air volume of the air supply fan (23) is set to the second air volume (Q2) in the simple ventilation operation. In any one of Claims 1-4,
A compressor (30), and first and second adsorption heat exchangers (31, 32) each having an adsorbent supported on the surface, the compressor (30) being driven to drive the first adsorption heat exchanger (31) becomes a condenser to humidify the air, and the second adsorption heat exchanger (32) becomes an evaporator to dehumidify the air, and the compressor (30) is driven. A refrigerant circuit that performs a second refrigeration cycle operation in which the first adsorption heat exchanger (31) serves as an evaporator to dehumidify air and the second adsorption heat exchanger (32) serves as a condenser to humidify the air. (21)
The humidity control part (50) is constituted by the first and second adsorption heat exchangers (31, 32),
In the humidity control operation, the compressor (30) and the air supply fan (23) are driven, and the refrigerant circuit (21) alternately performs the first refrigeration cycle operation and the second refrigeration cycle operation. When the first refrigeration cycle operation is performed, air that has passed through one of the first and second adsorption heat exchangers (31, 32) is supplied indoors, and the second refrigeration cycle operation is performed. The air passing through the other of the first and second adsorption heat exchangers (31, 32) is supplied into the room,
In the simple ventilation operation, the air supply fan (23) is driven in a state where the compressor (30) is stopped, and the air taken in from the outdoor is the first and second adsorption heat exchangers (31, 32). A humidity control apparatus that passes through one of the above and is supplied indoors.

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