JP7193356B2 - Outside air processing device - Google Patents

Description

The present invention relates to an outdoor air processing device for adjusting the indoor humidity and temperature of a target room.

In recent years, as the airtightness of houses increases, 24-hour ventilators that ventilate between indoors and outdoors for 24 hours a day have been adopted. A 24-hour ventilator is desired to have a dehumidification function and a humidification function in addition to a heating function and a cooling function from the viewpoint of improving the comfort of residents.

In Patent Document 1, an outdoor air processing device (outdoor air conditioner) having a refrigerant circuit detects the temperature and humidity of the outdoor air with a sensor, and depending on the detected outdoor temperature and humidity, dehumidification ventilation mode, It is disclosed that a humidification ventilation mode and a ventilation mode are switched to enhance indoor comfort.

JP 2012-83086 A

However, in the prior art disclosed in Patent Document 1, the operation mode of the air conditioner is set based on the relationship between the outdoor air temperature and the absolute humidity with reference to the psychrometric chart. Humidity is not considered. For this reason, in air conditioners installed indoors, there is a possibility that problems such as a loss of comfort and an increase in power consumption may occur when performing indoor air conditioning.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object thereof is to provide an outside air processing apparatus that does not impair comfort and is excellent in energy saving. .

In order to achieve the above object, the present invention provides a first air flow path for supplying outdoor air to a room, a second air flow path for discharging indoor air to the outside, and a an outdoor temperature detection means for detecting an outdoor temperature (To) that is the temperature of the air in the first air flow path, an outdoor humidity detection means for detecting an outdoor humidity (Ho) that is the absolute humidity of the air introduced into the first air flow path, Room temperature detection means for detecting room temperature (Ti), which is the temperature of the air introduced into the second air flow path, and room humidity (Hi), which is the absolute humidity of the air introduced into the second air flow path and an indoor humidity detecting means for detecting the first air flow path and the second air flow path, one of the first air flow path and the second air flow path rotary moisture adsorption means for adsorbing moisture in the air flowing through the air passage and releasing the moisture to the air flowing in the other air passage; A plurality of temporary operation modes, which are temporarily set based on the refrigerant circuit that heats and cools the air flowing through the other, and the relationship between the outdoor temperature (To) and the outdoor humidity (Ho), are set in advance. a storage unit for storing, wherein the temporary operation mode is a first temporary total heat exchange mode set when the outdoor humidity (Ho) is lower than a predetermined first reference outdoor humidity (h1o) (p1) and a fourth reference outdoor humidity (h4o) higher than the first reference outdoor humidity (h1o), and the fourth reference outdoor humidity (h4o) set when higher than the fourth reference outdoor humidity (h4o) 2 temporary total heat exchange mode (p7) and a third reference outdoor humidity (h3o) that is higher than the first reference outdoor humidity (h1o) and lower than the fourth reference outdoor humidity (h4o) is set, and the outdoor humidity (Ho) is higher than the third reference outdoor humidity (h3o) and a temporary dehumidification mode (p6) set when lower than the fourth reference outdoor humidity (h4o) And further, when the outdoor temperature (To) and the outdoor humidity (Ho) are acquired, one temporary operation mode is set from the plurality of temporary operation modes based on these relationships , based on the one provisional operation mode, the indoor temperature (Ti), and the indoor humidity (Hi) , (A) the moisture adsorption means is rotated, the refrigerant circuit is operated, and the first air (B) a humidification mode in which the moisture adsorption means is rotated to operate the refrigerant circuit to heat the first air flow path; (C) the moisture adsorption means is stopped; , operating said refrigerant circuit (D) a heating mode in which the moisture adsorption means is stopped and the refrigerant circuit is operated to heat the first air flow path; (E (F) a total heat exchange mode in which the moisture adsorption means is rotated at high speed, the refrigerant circuit is stopped, and total heat is exchanged between the first air flow path and the second air flow path; Control means for controlling at least one of the moisture adsorption means and the refrigerant circuit by selecting one of the operation modes of the adsorption means and a purge mode in which the refrigerant circuit is stopped and only ventilation is performed. and

ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the external air processing apparatus which is excellent in energy saving property, without impairing comfort.

FIG. 1 is a flow diagram schematically showing air flow in an outside air processing device according to an embodiment of the present invention. FIG. 2 is an explanatory diagram showing the configuration of a refrigerant circuit mounted on the outside air processing device according to the embodiment of the present invention. FIG. 3 is a block diagram showing the configuration of the main control section and its peripheral devices provided in the outside air processing apparatus according to the embodiment of the present invention. FIG. 4 is an explanatory diagram showing the flow of refrigerant when the refrigerant circuit is in dehumidification mode or cooling mode. FIG. 5 is an explanatory diagram showing the flow of refrigerant when the refrigerant circuit is in the humidification mode or the heating mode. FIG. 6 is an explanatory diagram showing motor operation, compressor operation, four-way valve switching, EA fan operation, and SA fan operation in each operation mode. FIG. 7 is a psychrometric chart of outdoor temperature and outdoor humidity, and is an explanatory diagram showing the area of the temporary operation mode. FIG. 8 is an air diagram of indoor temperature and indoor humidity, and is an explanatory diagram showing the area of the actual operation mode when the provisional low-humidity total heat exchange mode p1 is set. FIG. 9 is an air diagram of indoor temperature and indoor humidity, and is an explanatory diagram showing the area of the actual operation mode when the temporary humidification mode p2 is set. FIG. 10 is an air diagram of indoor temperature and indoor humidity, and is an explanatory diagram showing the area of the actual operation mode when the provisional cooling mode p3 is set. FIG. 11 is a psychrometric diagram of indoor temperature and indoor humidity, and is an explanatory diagram showing the area of the actual operation mode when the temporary heating mode p4 is set. FIG. 12 is a psychrometric diagram of indoor temperature and indoor humidity, and is an explanatory diagram showing the area of the actual operation mode when the temporary purge mode p5 is set. FIG. 13 is a psychrometric diagram of indoor temperature and indoor humidity, and is an explanatory diagram showing the area of the actual operation mode when the temporary dehumidification mode p6 is set. FIG. 14 is a psychrometric diagram of indoor temperature and indoor humidity, and is an explanatory diagram showing the area of the actual operation mode when the temporary high-humidity total heat exchange mode p7 is set. FIG. 15 is a flow chart showing the process of setting the temporary operation mode in the outside air processing device according to the embodiment of the present invention. FIG. 16 is a flowchart showing the process of setting the actual operation mode when the provisional low humidity total heat exchange mode p1 is set. FIG. 17 is a flow chart showing the process of setting the actual operation mode when the temporary humidification mode p2 is set. FIG. 18 is a flow chart showing the process of setting the actual operation mode when the provisional cooling mode p3 is set. FIG. 19 is a flow chart showing the process of setting the actual operation mode when the temporary heating mode p4 is set. FIG. 20 is a flow chart showing the process of setting the actual operation mode when the temporary purge mode p5 is set. FIG. 21 is a flow chart showing the process of setting the actual operation mode when the temporary dehumidification mode p6 is set. FIG. 22 is a flowchart showing the process of setting the actual operation mode when the temporary high-humidity total heat exchange mode p7 is set.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[Description of air flow path of outside air processing device]
FIG. 1 is a flow diagram schematically showing air flow in an outside air processing device 100 according to an embodiment of the present invention. As shown in FIG. 1, this outdoor air treatment device 100 has a first air flow path 12 directed from the outside to the inside and a second air flow path 13 directed from the inside to the outside of the room to be air-conditioned. I have.

The first air flow path 12 is a flow path for supplying outdoor air (OA; Out Air) indoors by an SA (Supply Air) fan 10 provided downstream thereof, and the first heat exchanger 5, Outdoor air is supplied indoors via a rotary desiccant rotor 8 (moisture adsorption means), the second heat exchanger 7 and the SA fan 10 . The desiccant rotor 8 is arranged across the first air flow path 12 and the second air flow path 13, and is rotated by the driving force of a motor 20 (see FIG. 3), which will be described later. replace the humidity of

The second air flow path 13 is a flow path for discharging indoor air (RA; Return Air) to the outside of the room by an EA (Exhaust Air) fan 9 provided downstream thereof, and the third heat exchanger 4, Room air is discharged to the outside via the desiccant rotor 8, the fourth heat exchanger 6, and the EA fan 9.
In the following description, the air flowing into the first air flow path 12 (that is, the outdoor air) is referred to as "OA", and the air that is discharged from the first air flow path 12 and supplied indoors (that is, the supplied air) is referred to as " SA”, indoor air flowing into the second air flow path 13 (i.e., indoor air) as “RA”, and air discharged from the second air flow path 13 and discharged to the outside (i.e., exhaust air) as “ EA”.

[Description of Desiccant Rotor]
Next, the desiccant rotor 8 shown in FIG. 1 will be described. The desiccant rotor 8 is a rotary desiccant and can be rotationally driven by a motor 20 (see FIG. 3). By rotating the desiccant rotor 8, sensible heat and latent heat in the air flowing through the first air flow path 12 and the second air flow path 13 can be exchanged. When the motor 20 is rotated at normal speed, it functions as a normal rotary desiccant. On the other hand, if the motor 20 is rotated at a high speed (for example, 10 times the normal rotation speed), it operates with a function equivalent to that of a total heat exchanger.
That is, the desiccant rotor 8 is driven at a normal rotational speed to mainly exchange moisture (humidity) in the air, and is rotated at a high speed to enable total heat exchange of both latent heat and sensible heat. Become.

[Explanation of refrigerant circuit]
FIG. 2 is an explanatory diagram showing the configuration of a refrigerant circuit mounted in the outside air processing device 100 according to this embodiment. The configuration of the refrigerant circuit 90 provided in the outside air processing device 100 according to the present embodiment will be described below with reference to FIG. 2 . For convenience of explanation, in FIG. 2, the first air flow path 12 shown in FIG. described in

As shown in FIG. 2, the outside air processing device 100 according to the present embodiment is a heat pump device, and includes a refrigerant circuit 90 for circulating refrigerant, a desiccant rotor 8, an SA fan 10, and an EA fan 9. there is

The refrigerant circuit 90 includes a compressor 1 that compresses and outputs refrigerant, an accumulator 2 that is provided upstream of the compressor 1 and temporarily stores the refrigerant to be supplied to the compressor 1, and a refrigerant that is sent out from the compressor 1. A four-way valve 3 is provided for switching to output the compressed refrigerant to either the first air flow path 12 side or the second air flow path 13 side of the heat exchanger.

Furthermore, the refrigerant circuit 90 includes a first heat exchanger 5 provided upstream of the desiccant rotor 8 in the first air flow path 12, a second heat exchanger 7 provided downstream of the desiccant rotor 8, a second A third heat exchanger 4 provided on the upstream side of the desiccant rotor 8 in the air flow path 13 and a fourth heat exchanger 6 provided on the downstream side of the desiccant rotor 8 are provided.

Further, the refrigerant circuit 90 includes the first expansion valve 18, the second expansion valve 19, the outdoor temperature sensor 23 (outdoor temperature detection means) for detecting the temperature of the air flowing through the first air flow path 12, and the first air flow path. An outdoor humidity sensor 24 (outdoor humidity detection means) is provided to detect the absolute humidity of the air flowing through 12 . The outdoor temperature sensor 23 and the outdoor humidity sensor 24 are arranged in front of the first heat exchanger 5, that is, on the outside air introduction side. Therefore, the sensors 23 and 24 can respectively detect the temperature and absolute humidity of the air introduced into the outdoor air processing device 100 from the outside.

Furthermore, the refrigerant circuit 90 includes an indoor temperature sensor 25 (indoor temperature detection means) that detects the temperature of the air flowing through the second air flow path 13, and an indoor humidity sensor that detects the absolute humidity of the air flowing through the second air flow path 13. A sensor 26 (indoor humidity detection means) is provided. These indoor temperature sensor 25 and indoor humidity sensor 26 are arranged on the inlet side of the third heat exchanger 4 . Therefore, the sensors 25 and 26 can respectively detect the temperature and absolute humidity of the air entering the outside air processing apparatus 100 from inside the room.

The first expansion valve 18 is provided in the path of the pipe connecting the first heat exchanger 5 and the third heat exchanger 4, and reduces the pressure of the refrigerant flowing between the heat exchangers 5 and 4 while increasing the flow rate of the refrigerant. adjust.
The second expansion valve 19 is provided in the path of the piping connecting the second heat exchanger 7 and the fourth heat exchanger 6, and reduces the pressure of the refrigerant flowing between the heat exchangers 7 and 6 while increasing the flow rate of the refrigerant. adjust. In addition, the flow direction of the refrigerant of the first expansion valve 18 and the second expansion valve 19 can be adjusted in either direction.

Furthermore, the outside air treatment device 100 includes a main control section 31 (control means) that controls the processing of the outside air treatment device 100 . The main control unit 31 acquires the detection signals of the sensors 23, 24, 25, and 26 (that is, the outdoor temperature To, the outdoor humidity Ho, the indoor temperature Ti, and the indoor humidity Hi), and based on the acquired detection signals, , various operation modes (details of which will be described later) are set, and the compressor 1, the four-way valve 3, the first expansion valve 18, and the second expansion valve 19 are controlled. Further, the main control unit 31 controls the driving and stopping of the EA fan 9 and the SA fan 10 shown in FIG. 1, the driving and stopping of the motor 20 that rotates the desiccant rotor 8, and the normal rotation and high-speed rotation of the motor 20. .

[Description of the main controller]
FIG. 3 is a block diagram showing the configuration of the main control unit 31 provided in the outside air processing device 100 according to this embodiment and its peripheral devices. The main control section 31 can be configured as an integrated computer including, for example, a central processing unit (CPU) and storage means such as a RAM, a ROM, and a hard disk.

As shown in FIG. 3, the main control unit 31 includes a sensor input unit 31a that inputs detection signals detected by the sensors 23, 24, 25, and 26, an EA fan 9, an SA fan 10, a motor 20, a four-way valve 3. An operation unit 31 b that controls the driving/stopping of the compressor 1 and controls the opening degrees of the first expansion valve 18 and the second expansion valve 19 . Then, as described above, based on the detection signals (outdoor temperature To, outdoor humidity Ho, indoor temperature Ti, indoor humidity Hi) detected by the sensors 23, 24, 25, and 26, various operation modes (to be described later) are selected. actual operation mode). Furthermore, the operation of the compressor 1, the four-way valve 3, the first expansion valve 18, and the second expansion valve 19 is controlled according to the set operation mode.

The main control unit 31 also executes a process of calculating the indoor relative humidity Hr based on the indoor temperature Ti detected by the indoor temperature sensor 25 and the indoor humidity Hi (absolute humidity) detected by the indoor humidity sensor 26. .
The main control section 31 further includes a storage section 31c. The storage unit 31c stores various data used for control executed by the main control unit 31 . For example, temperature data and humidity data detected by each sensor 23, 24, 25, 26 are temporarily stored. The storage unit 31c also stores the relationship between the psychrometric diagrams shown in FIGS. 7 to 14 and each operation mode (provisional operation mode, actual operation mode).

[Description of each operation mode]
The outside air treatment device 100 according to the present embodiment has a purge mode (indicated by symbol q1), a dehumidification mode (indicated by symbol q2), a humidification mode (indicated by symbol q3), a cooling mode (indicated by symbol q4), and a heating mode. (indicated by symbol q5) and total heat exchange mode (indicated by symbol q6). Each operation mode will be described in detail below.

[Purge mode q1]
The purge mode q1 is a mode in which target indoor air is exhausted and outdoor air (OA) is taken into the room. Therefore, in the purge mode q1, the motor 20 is stopped and the desiccant rotor 8 is not rotated. Furthermore, the refrigerant circuit 90 is stopped. Only the EA fan 9 and the SA fan 10 are operated to exhaust and supply air. The purge mode q1 is an operation mode when the ventilator does not require dehumidification, humidification, cooling, or heating, and only ventilation of the room is required. This is the operation mode in the middle period, which is the period when Moreover, since the desiccant rotor 8 and the refrigerant circuit 90 are stopped, power consumption can be significantly reduced.

[Dehumidification mode q2]
The dehumidification mode q2 is a mode in which outdoor air (OA) is dehumidified and supplied indoors. That is, in the dehumidification mode q2, the outdoor air (OA) is passed through the first heat exchanger 5, the desiccant rotor 8, and the second heat exchanger 7 in this order in the first air flow path 12, and the outdoor air (OA) is is lowered, and the supply air (SA) with lowered humidity is supplied indoors by the SA fan 10. - 特許庁Furthermore, the second air flow path 13 allows the indoor air (RA) to pass through the third heat exchanger 4, the desiccant rotor 8, and the fourth heat exchanger 6 in this order, and exhaust heat generated by the operation of the refrigerant circuit 90 is removed. It is included in exhaust air (EA) and exhausted. Furthermore, in the dehumidification mode q2, the desiccant rotor 8 is rotated at a normal speed, and moisture in the air flowing through the first air flow path 12 is transferred to the air flowing through the second air flow path 13 and discharged.

A detailed operating state of the refrigerant circuit 90 at this time will be described with reference to FIG. FIG. 4 is a flow chart showing the flow of refrigerant in the refrigerant circuit 90 in the dehumidification mode q2 and the cooling mode q4, which will be described later. In the dehumidification mode q2, the first heat exchanger 5 and the second heat exchanger 7 in the first air flow path 12 become evaporators, the refrigerant evaporates to lower the air temperature, and the heat exchangers 5 and 7 condensate and reduce humidity. The third heat exchanger 4 and the fourth heat exchanger 6 of the second air flow path 13 function as condensers and discharge the amount of heat taken from the first air flow path 12 .

More specifically, under the control of the main control unit 31, the four-way valve 3 is connected to the piping leading from the discharge side of the compressor 1 to the third heat exchanger 4 and the fourth heat exchanger 6, as indicated by the arrows in FIG. Connected. That is, the refrigerant output from the compressor 1 is branched into two systems, one of which is introduced into the third heat exchanger 4 and the other of which is introduced into the fourth heat exchanger 6 .

In the dehumidification mode q2, the compressed refrigerant output from the compressor 1 is of high temperature and high pressure. Therefore, by introducing the compressed refrigerant into the third heat exchanger 4 and the fourth heat exchanger 6 which act as condensers, heat exchange occurs between the compressed refrigerant and the air passing through the second air flow path 13. done. Therefore, the temperature of the air flowing through the second air flow path 13 rises. The refrigerant output from the heat exchangers 4 and 6 becomes a high-pressure liquid refrigerant. After that, the refrigerant output from the third heat exchanger 4 is depressurized and expanded by passing through the first expansion valve 18 to become a low-temperature, low-pressure gas-liquid mixed refrigerant. This refrigerant is introduced into the first heat exchanger 5 .

Similarly, the refrigerant output from the fourth heat exchanger 6 is also decompressed and expanded by passing through the second expansion valve 19 to become a low-temperature and low-pressure gas-liquid mixed refrigerant, which is introduced into the second heat exchanger 7. be.

The refrigerant introduced into the first heat exchanger 5 evaporates, reduces the temperature of the air introduced from the outside and flows through the first air flow path 12 (air temperature upstream of the desiccant rotor 8), and turns into gas. Phase change. The refrigerant output from the first heat exchanger 5 is returned to the accumulator 2 via the four-way valve 3 . At this time, the temperature of the air (that is, the outdoor air (OA)) flowing through the first air flow path 12 is lowered due to the evaporation of the refrigerant. Also, when dew condensation occurs, the humidity in the air decreases.

On the other hand, the refrigerant introduced into the second heat exchanger 7 reduces the temperature of the air that has passed through the desiccant rotor 8 in the first air flow path 12 (air temperature downstream of the desiccant rotor 8) with evaporation, Phase change to gas. The refrigerant discharged from the second heat exchanger 7 joins the refrigerant discharged from the first heat exchanger 5 and is returned to the compressor 1 via the four-way valve 3 and the accumulator 2 . At this time, the temperature of the air flowing through the first air flow path 12 is lowered due to the evaporation of the refrigerant. Also, when dew condensation occurs, the humidity in the air decreases.

That is, in the dehumidifying mode, the refrigerant output from the compressor 1 is returned to the compressor 1 via the third heat exchanger 4, the first expansion valve 18, and the first heat exchanger 5, and the fourth Two parallel flow paths are formed through the heat exchanger 6 , the second expansion valve 19 , the second heat exchanger 7 and back to the compressor 1 .

Furthermore, in the desiccant rotor 8 on the route of the first air flow path 12, the air whose temperature has been lowered by the first heat exchanger 5, that is, the air whose relative humidity has been increased is the adsorbent retained in the elements of the desiccant rotor 8. Moisture is absorbed by the air, and the amount of moisture in the air decreases. At this time, the adsorbent of the desiccant rotor 8 causes an exothermic reaction due to moisture absorption, and heats the air. The temperature of this air is lowered again by the second heat exchanger 7 arranged downstream of the desiccant rotor 8 . After that, the SA fan 10 supplies the air to the room.

In the desiccant rotor 8 on the path of the second air flow path 13, the air whose temperature has been raised by the third heat exchanger 4, that is, the air whose relative humidity has been lowered passes through the desiccant rotor 8. Moisture is released from the adsorbent held in the elements of the air, and the moisture in the air rises. At this time, the adsorbent of the desiccant rotor 8 undergoes an endothermic reaction due to its dehumidifying action, thereby cooling the air. However, the temperature of this air rises again as it passes through the fourth heat exchanger 6 arranged downstream of the desiccant rotor 8 and then is exhausted to the outside by the EA fan 9 .

As described above, in the dehumidification mode q2 in the present embodiment, the first air flow path 12 reduces the latent heat and sensible heat of the outdoor air (OA) due to the action of the refrigerant circuit 90 and the action of the desiccant rotor 8. Air can be supplied to the room.

[Description of Humidification Mode q3]
Humidification mode q3 is a mode in which outdoor air (OA) is humidified and supplied indoors. That is, in the humidification mode q3, the outdoor air (OA) is passed through the first heat exchanger 5, the desiccant rotor 8, and the second heat exchanger 7 in the order of the first air flow path 12, and the outdoor air (OA) is Increase humidity. After that, the air with increased humidity is supplied into the room by the SA fan 10 as supply air (SA).

Furthermore, by the second air flow path 13, the indoor air (RA) is passed through the third heat exchanger 4, the desiccant rotor 8, and the fourth heat exchanger 6 in this order, and the cold heat generated by the operation of the refrigerant circuit 90 is transferred to the room. Contained in air (RA) and discharged.
Furthermore, in the humidification mode q3, the desiccant rotor 8 is rotated at a normal rotational speed to move the moisture in the air flowing through the second air flow path 13 to the air flowing through the first air flow path 12 and supply it indoors. .

A detailed operating state of the refrigerant circuit 90 at this time will be described with reference to FIG. FIG. 5 is a flow chart showing the refrigerant flow in the refrigerant circuit 90 in the humidification mode q3 and the heating mode q5, which will be described later. During the humidification mode, the first heat exchanger 5 and the second heat exchanger 7 in the first air flow path 12 function as condensers, and the refrigerant is condensed to raise the air temperature. The third heat exchanger 4 and the fourth heat exchanger 6 of the second air flow path 13 serve as evaporators to transfer heat to the first air flow path 12, and absorb heat to lower the air temperature.

More specifically, under the control of the main control unit 31, the four-way valve 3 is connected to the piping leading from the discharge side of the compressor 1 to the first heat exchanger 5 and the second heat exchanger 7 as indicated by the arrows in FIG. be done. That is, the refrigerant output by the compressor 1 is branched into two systems, one of which is introduced into the first heat exchanger 5 and the other of which is introduced into the second heat exchanger 7 .

In the humidification mode q3, high-temperature and high-pressure refrigerant is introduced into the first heat exchanger 5 and the second heat exchanger 7 acting as condensers, so the air passing through the first air flow path 12 is heated. After that, the refrigerant output from the first heat exchanger 5 is depressurized and expanded by passing through the first expansion valve 18 to become a low-temperature, low-pressure gas-liquid mixed refrigerant. This refrigerant is introduced into the third heat exchanger 4 . Similarly, the refrigerant output from the second heat exchanger 7 is also decompressed and expanded by passing through the second expansion valve 19 to become a low-temperature, low-pressure gas-liquid mixed refrigerant, which is introduced into the fourth heat exchanger 6. be.

The refrigerant introduced into the third heat exchanger 4 is accompanied by evaporation, and the temperature of the indoor air (RA) flowing through the second air flow path 13 returned from the room (air temperature on the upstream side of the desiccant rotor 8) is lowered. and changes phase to gas. Refrigerant output from the third heat exchanger 4 is returned to the accumulator 2 via the four-way valve 3 . At this time, the temperature of the air flowing through the second air flow path 13 drops due to the evaporation of the refrigerant.

On the other hand, the refrigerant introduced into the fourth heat exchanger 6 reduces the temperature of the air that has passed through the desiccant rotor 8 in the second air flow path 13 (air temperature downstream of the desiccant rotor 8) with evaporation. , changes phase to gas. The refrigerant output from the fourth heat exchanger 6 joins with the refrigerant output from the third heat exchanger 4 and is returned to the compressor 1 via the four-way valve 3 and the accumulator 2 . At this time, the temperature of the air flowing through the second air flow path 13 is lowered due to the evaporation of the refrigerant.

That is, in the humidification mode q3, the refrigerant output from the compressor 1 is returned to the compressor 1 via the first heat exchanger 5, the first expansion valve 18, and the third heat exchanger 4; Two parallel flow paths are formed, a flow path returning to the compressor 1 via the second heat exchanger 7 , the second expansion valve 19 and the fourth heat exchanger 6 .

Furthermore, in the desiccant rotor 8 on the route of the second air flow path 13, the air whose temperature has been lowered by the third heat exchanger 4, that is, the air whose relative humidity has been increased is the adsorbent retained in the elements of the desiccant rotor 8. Moisture in the air is reduced by adsorption. At this time, the adsorbent of the desiccant rotor 8 causes an exothermic reaction due to moisture absorption, and heats the air. However, the temperature of this air is lowered again by the fourth heat exchanger 6 arranged downstream of the desiccant rotor 8 . Then, the air is exhausted to the outside by the EA fan 9 .

In the desiccant rotor 8 on the route of the first air flow path 12, the air whose temperature has been raised by the first heat exchanger 5, that is, the air whose relative humidity has been lowered, is absorbed by the adsorbent held in the elements of the desiccant rotor 8. Moisture is released and the moisture in the air rises. At this time, the adsorbent of the desiccant rotor 8 causes an endothermic reaction due to the moisture releasing action, thereby cooling the air. However, the temperature of this air is raised again by the second heat exchanger 7 arranged downstream of the desiccant rotor 8 . Then, the SA fan 10 supplies the air to the room.

As described above, in the humidification mode q3 of the present embodiment, the first air flow path 12 supplies air with increased humidity to the room due to the action of the refrigerant circuit 90 and the action of the desiccant rotor 8. is possible.

[Cooling mode q4]
The cooling mode q4 is a mode in which the refrigerant circuit 90 is operated to lower the temperature of the air and supply it indoors. That is, if the outdoor air is supplied to the room at a high temperature, the load on the indoor air conditioner will increase.

The operation of the refrigerant circuit 90 is the same as in the dehumidification mode described above. That is, the first heat exchanger 5 and the second heat exchanger 7 of the first air flow path 12 function as evaporators and cool the outdoor air (OA) to lower its temperature. The third heat exchanger 4 and the fourth heat exchanger 6 of the second air flow path 13 function as condensers, and exhaust heat in the room air (RA) through the refrigerant circuit 90 . Therefore, the flow of the refrigerant in the refrigerant circuit 90 is the same as in the flowchart of FIG. 4 described above.

However, in the cooling mode, the desiccant rotor 8 is not rotated and no moisture is exchanged. That is, in the cooling mode q4, only the process of lowering the temperature in the air is performed except for dehumidification due to dew condensation in the heat exchanger functioning as an evaporator of the first air flow path 12 .

[Heating mode q5]
The heating mode q5 is an operation mode in which the refrigerant circuit 90 is operated to raise the air temperature and supply the air indoors. That is, the outdoor air is at a low temperature, and if it is supplied indoors as it is, the load on the indoor air conditioner will increase.

The operation of the refrigerant circuit 90 is the same as in the humidification mode described above. That is, the first heat exchanger 5 and the second heat exchanger 7 of the first air flow path 12 function as condensers and heat the outdoor air (OA) to raise the temperature. The third heat exchanger 4 and the fourth heat exchanger 6 of the second air flow path 13 function as evaporators, and the refrigerant circuit 90 recovers heat from the room air (RA) and exhausts the heat. Therefore, the flow of refrigerant in the refrigerant circuit 90 is the same as the flow diagram shown in FIG.
However, in the heating mode, the desiccant rotor 8 is not rotated and the moisture is not exchanged. That is, in the heating mode, only processing for raising the temperature of the air flowing through the first air flow path 12 is performed.

[Total heat exchange mode q6]
When the humidity of the outdoor air is extremely high or extremely low, the operation mode is changed to the dehumidifying mode when the refrigerant circuit 90 and the desiccant rotor 8 are combined as in the outdoor air processing device 100 according to the present embodiment. If the mode is set to q2 or the humidification mode q3, the efficiency of the refrigerant circuit 90 may decrease. Contrary to this, the total heat exchanger has the characteristic that the greater the mutual humidity difference, the greater the amount of humidity exchange. Therefore, in the case of such high humidity or low humidity, the operation mode is set to the total heat exchange mode q6.

Furthermore, when the indoor temperature and humidity reach the target values, the total heat exchange mode q6 is performed in order to improve energy saving. That is, in the total heat exchange mode q6, the refrigerant circuit 90 is stopped compared to other operation modes, so that energy consumption can be reduced (so-called energy saving).

The total heat exchange mode q6 is an operation mode in which a total heat exchanger exchanges sensible heat and latent heat between indoors and outdoors to perform ventilation. That is, the outside air processing apparatus 100 according to this embodiment does not have a total heat exchanger, but by rotating the desiccant rotor 8 at high speed, it is possible to obtain the same function as a total heat exchanger. By rotating the desiccant rotor 8 at a high speed, not only moisture is exchanged by the adsorbent, but also the desiccant rotor 8 repeats sensible heat storage and heat dissipation, enabling sensible heat exchange in the air.

That is, the main controller 31 stops the refrigerant circuit 90 in the total heat exchange mode q6. Further, the main controller 31 rotates the motor 20 of the desiccant rotor 8 at high speed.
FIG. 6 summarizes the operation of the motor 20, the operation of the compressor 1, the switching state of the four-way valve, the operation of the EA fan 9, and the operation of the SA fan 10 in each operation mode (q1 to q6) described above. .

[Description of switching control of each operation mode]
Each of the operation modes q1 to q6 described above includes detection signals (that is, the outdoor temperature To and the outdoor humidity Ho) detected by the outdoor temperature sensor 23 and the outdoor humidity sensor 24 installed in the first air flow path 12, and the 2 Determined by the detection signals (that is, the room temperature Ti and the room humidity Hi) detected by the room temperature sensor 25 and the room humidity sensor 26 installed in the air flow path 13 .

Specifically, first, a temporary operation mode (details of which will be described later) is set based on the outdoor temperature To and the outdoor humidity Ho. Next, the actual operation mode is determined based on the provisional operation mode set, the indoor temperature Ti, and the indoor humidity Hi. In addition, below, in order to distinguish between the actual operation mode and the temporary operation mode described later, the actual operation mode will be referred to as the "actual operation mode". A method for setting the temporary operation mode and a specific method for setting the actual operation mode will be described below.

[Temporary operation mode setting]
FIG. 7 is a psychrometric chart in which the horizontal axis is the outdoor temperature [° C.] and the vertical axis is the outdoor humidity (absolute humidity [kg/kg]), and shows the region in which the temporary operation mode is set.
In this embodiment, the temporary operation mode is set first, and then the actual operation mode is set by the processing described later based on the set temporary operation mode. "Temporary operation mode" is a temporary operation mode set based on the outdoor temperature (To) and the outdoor humidity (Ho), and is used to determine the actual operation mode (actually applied operation mode) described later. Set as a previous step.

The procedure for setting the temporary operation mode will be described in detail below. In the following description, all "humidity" is assumed to be "absolute humidity" unless otherwise specified.
The sensor input section 31a of the main control section 31 shown in FIG. These are stored in the storage section 31 c of the main control section 31 .

In addition, a first reference outdoor temperature t1o, a second reference outdoor temperature t2o, and a third reference outdoor temperature t3o, which serve as references for the outdoor temperature To, are set in the storage unit 31c. Furthermore, a first reference room temperature t1i, a second reference room temperature t2i, and a third reference room temperature t3i are set as references for the room temperature Ti. However, t1o<t2o<t3o and t1i<t2i<t3i.

Further, in the present embodiment, the first reference outdoor temperature t1o and the first reference indoor temperature t1i are set to the same numerical value, and indicated by "first reference temperature t1." Similarly, the second reference outdoor temperature t2o and the second reference indoor temperature t2i are expressed as the same numerical value as “second reference temperature t2”, and the third reference outdoor temperature t3o and the third reference indoor temperature t3i are indicated as the same numerical value. is shown as "third reference temperature t3". Note that the first reference outdoor temperature t1o and the first reference indoor temperature t1i may not be the same. Similarly, the second reference outdoor temperature t2o and the second reference indoor temperature t2i may not be the same, and the third reference outdoor temperature t3o and the third reference indoor temperature t3i may not be the same.

Furthermore, in the storage unit 31c, a first reference outdoor humidity h1o, a second reference outdoor humidity h2o, a third reference outdoor humidity h3o, and a fourth reference outdoor humidity h4o, which serve as references for the outdoor humidity Ho, are set. there is Further, a first reference indoor humidity h1i, a second reference indoor humidity h2i, a third reference indoor humidity h3i, and a fourth reference indoor humidity h4i are set as the reference of the indoor humidity Hi. However, h1o<h2o<h3o<h4o and h1i<h2i<h3i<h4i.

Further, in the present embodiment, the first reference outdoor humidity h1o and the first reference indoor humidity h1i are set to the same numerical value, and indicated by "first reference humidity h1." Similarly, the second reference outdoor humidity h2o and the second reference indoor humidity h2i have the same numerical value and are denoted by “second reference humidity h2”, and the third reference outdoor humidity h3o and the third reference indoor humidity h3i are the same. , and the fourth reference outdoor humidity h4o and the fourth reference indoor humidity h4i are indicated as the same numerical value as the "fourth reference humidity h4". Note that the first reference outdoor humidity h1o and the first reference indoor humidity h1i may not be the same. Similarly, the second reference outdoor humidity h2o and the second reference indoor humidity h2i may not be the same, and the third reference outdoor humidity h3o and the third reference indoor humidity h3i may not be the same. The fourth reference outdoor humidity h4o and the fourth reference indoor humidity h4i may not be the same.
Then, the main control unit 31 sets the temporary operation mode based on each reference temperature (t1 to t3) and each reference humidity (h1 to h4).

In this embodiment, as an example, t1=8.0 [° C.], t2=18.0 [° C.], and t3=27.0 [° C.]. Also, h1=0.0027 [kg/kg], h2=0.0066 [kg/kg], h3=0.0111 [kg/kg], and h4=0.0180 [kg/kg]. Note that the first reference temperature t1 is used in determining the actual operation mode (see FIG. 8, etc.), which will be described later, and is not used in FIG. Further, in this embodiment, as an example, the reference temperatures t1 to t3 and the reference humidity h1 to h3 are set as described above, and are not limited to these numerical values.

In the present embodiment, as shown in FIG. 7, temporary operation modes include temporary low humidity total heat exchange mode p1 (first temporary total heat exchange mode), temporary humidification mode p2, temporary cooling mode p3, temporary heating mode p4, One of the seven temporary operation modes of a temporary purge mode p5, a temporary dehumidification mode p6, and a temporary high humidity total heat exchange mode p7 (second temporary total heat exchange mode) is set. A detailed description will be given below.

When the outdoor humidity Ho shown on the vertical axis in FIG. 7 is less than 0.0027 [kg/kg] (h1), that is, (Ho<0.0027), the temporary operation mode is set to temporary low humidity total heat exchange Set to mode p1.

The outdoor humidity Ho is 0.0027 [kg/kg] (h1) or more and less than 0.0066 [kg/kg] (h2), and the outdoor temperature To shown on the horizontal axis in FIG. 7 is 27.0. When the temperature is less than [°C] (t3), that is, when 0.0027≤Ho<0.0066 and To<27.0, the temporary operation mode is set to the temporary humidification mode p2.

The outdoor humidity Ho is 0.0027 [kg/kg] (h1) or more and less than 0.0111 [kg/kg] (h3), and the outdoor temperature To is 27.0 [°C] (t3) or more (0.0027≦Ho<0.0111 and 27.0≦To), the provisional operation mode is set to the provisional cooling mode p3.

The outdoor humidity Ho is 0.0066 [kg/kg] (h2) or more and less than 0.0111 [kg/kg] (h3), and the outdoor temperature To is less than 18.0 [°C] (t2) (0.0066≦Ho<0.0111 and To<18.0), the provisional operation mode is set to the provisional heating mode p4.

Outdoor humidity Ho is 0.0066 [kg/kg] (h2) or more and less than 0.0111 [kg/kg] (h3), and outdoor temperature To is 18.0 [°C] (t2) or more , 27.0 [°C] (t3), i.e., (0.0066 ≤ Ho < 0.0111 and 18.0 ≤ To < 27.0), the temporary operation mode is set to temporary purge. Set to mode p5.

When the outdoor humidity Ho is 0.0111 [kg/kg] (h3) or more and less than 0.0180 [kg/kg] (h4), that is, (0.0111 ≤ Ho < 0.0180), , the temporary dehumidification mode p6 is set.

When the outdoor humidity Ho is 0.0180 [kg/kg] (h4) or more, that is, (when 0.0180≦Ho), the provisional high humidity total heat exchange mode p7 is set.

[Setting of actual operation mode]
Next, processing for setting the actual operation mode, which is the operation mode that is actually applied, based on each of the temporary operation modes (p1 to p7) described above will be described.
As described above, the outdoor air processing device 100 acquires the temperature (outdoor temperature To) and humidity (outdoor humidity Ho) of the outdoor air (OA) from the outdoor temperature sensor 23 and the outdoor humidity sensor 24, and based on these, provisional Set the driving mode. However, if the outside air treatment device 100 is operated with the provisional operation mode as the actual operation mode, the operation mode may not always be optimal depending on the indoor environment and load state, and comfort and energy efficiency may be lacking. Therefore, in the present embodiment, the temperature (indoor temperature Ti) and humidity (indoor humidity Hi) of the indoor air (RA) are obtained from the indoor temperature sensor 25 and the indoor humidity sensor 26, and based on these, the optimum The actual operation mode is finally determined, and the outside air processing device 100 is operated in the determined actual operation mode.

Specifically, the sensor input unit 31a of the main control unit 31 acquires the indoor temperature Ti from the indoor temperature sensor 25 arranged in the second air flow path 13, and further acquires the indoor humidity Hi from the indoor humidity sensor 26. Then, these data are stored in the storage section 31c of the main control section 31. FIG. Further, based on the indoor temperature Ti and the indoor humidity Hi, the indoor relative humidity Hr is calculated and stored in the storage section 31c. Furthermore, with reference to the first to third reference temperatures t1, t2, and t3, the first to fourth reference humidity h1, h2, h3, and h4, and the relative humidity Hr, based on the indoor temperature Ti and the indoor humidity Hi, Determine the actual operation mode.
The procedure for setting the actual operation mode in each of the temporary operation modes p1 to p7 described above will be described in detail below.

[When temporary low humidity total heat exchange mode p1 is set]
FIG. 8 is an explanatory diagram showing regions for setting the actual operation mode when the temporary low-humidity total heat exchange mode p1 is set as the temporary operation mode. When the outdoor humidity Ho is low (p1 in FIG. 7), the operation is basically performed in the total heat exchange mode q6 to exchange sensible heat and latent heat between indoors and outdoors. However, when the indoor temperature Ti is low, the operation is performed in the heating mode q5 to reduce the heating load of the indoor air conditioner. When the indoor humidity Hi is low, the operation is performed in the humidification mode q3 to increase the indoor humidity. When the indoor temperature Ti is high, the purge mode q1 is operated to introduce outside air into the room to lower the room temperature.

In the temporary low-humidity total heat exchange mode p1, whether to use the total heat exchange mode q6 or the humidification mode q3 is determined by the difference value between the indoor humidity Hi and the outdoor humidity Ho. That is, it is assumed that the outdoor humidity Ho is lower than the indoor humidity Hi, in which case the operation is performed in the total heat exchange mode q6, but if the indoor humidity Hi is also low, the operation is performed in the humidification mode q3. . Also, even in the humidification mode q3, if the difference between the indoor humidity Hi and the outdoor humidity Ho is equal to or greater than a specified value, the efficiency of the refrigerant circuit 90 is reduced and the humidification capacity is reduced, so operation is performed in the total heat exchange mode q6. do.

For example, the humidity hr1 (first humidity threshold), which is the threshold for switching between the total heat exchange mode q6 and the humidification mode q3, is set to "Ho-0.0039". Therefore, when the indoor humidity Hi becomes larger than the numerical value obtained by subtracting "0.0039" from the outdoor humidity Ho, the total heat exchange mode q6 is set. That is, the threshold humidity hr1 (first humidity threshold) is changed according to the outdoor humidity Ho.

Also, even if the humidification mode q3 is selected, if the humidity in the room is high, condensation may occur in the desiccant rotor 8. Switch the temperature mode q5.

The temporary low-humidity total heat exchange mode p1 is performed by selecting one of heating mode q5, humidification mode q3, total heat exchange mode q6, and purge mode q1 based on room temperature Ti and room humidity Hi. First, the indoor relative humidity Hr is calculated based on the indoor temperature Ti and the indoor humidity Hi. Further, the hr1 value (hr1=Ho−Δh1), which is a numerical value lower than the outdoor humidity Ho by 0.0039 [kg/kg] (Δh1), is calculated and stored in the storage unit 31c.

When the indoor temperature Ti is less than 8 [° C.] (t1) (Ti<t1), the heating mode q5 is selected. When the indoor temperature Ti is 8 [° C.] (t1) or more and less than 27 [° C.] (t3) (t1≦Ti<t3), the relative humidity Hr is less than 60 [%], and If the humidity Hi is less than hr1, the humidification mode q3 is selected. When the indoor temperature Ti is 8 [° C.] (t1) or more and less than 18 [° C.] (t2) (t1≦Ti<t2), and the relative humidity Hr is 60 [%] or more, or When Hi is equal to or greater than hr1 (60% RH≤Hr or hr1≤Hi), heating mode q5 is selected. When the indoor temperature Ti is 18 [° C.] (t2) or higher and lower than 27 [° C.] and the indoor humidity Hi is hr1 or higher (hr1≦Hi), the total heat exchange mode q6 is selected. When the indoor temperature Ti is 27[° C.] (t3) or more (Ti≦t3), the purge mode q1 is selected.

[When temporary humidification mode p2 is set]
FIG. 9 is an explanatory diagram showing regions for setting the actual operation mode when the temporary humidification mode p2 is set as the temporary operation mode. When the temporary humidification mode p2 is set, since the outdoor humidity Ho is low, the operation is basically performed in the humidification mode q3 to heat and humidify the room. However, when the indoor temperature is low, the operation is performed in the heating mode q5 to reduce the heating load of the indoor air conditioner. When the indoor humidity is high, the operation is performed in total heat exchange mode q6. When the room temperature is high, the purge mode q1 is operated to introduce outside air into the room to lower the room temperature.

As shown in FIG. 9, in the temporary humidification mode p2, one of the heating mode q5, the humidification mode q3, the total heat exchange mode q6, and the purge mode q1 is selected based on the room temperature Ti and the room humidity Hi. to implement. When the indoor temperature Ti is less than 8 [° C.] (t1) (Ti<t1), the heating mode q5 is selected. The indoor temperature Ti is 8 [° C.] (t1) or more and less than 27 [° C.] (t3) (t1≦Ti<t3), the relative humidity Hr is less than 60 [%], and the indoor humidity Hi is If it is less than 0.0066 [kg/kg], humidification mode q3 is selected.

This is the case where the indoor temperature Ti is 8 [° C.] (t1) or higher and lower than 27 [° C.] (t3) (t1≦Ti<t3), and the relative humidity Hr is 60 [%] or higher, or the indoor humidity Hi is 0.00. 0066 [kg/kg] or more, and when the indoor temperature Ti is less than 18 [° C.] (t2) (Ti<t2), the heating mode q5 is selected, and the indoor temperature Ti is When the temperature is 18[° C.] (t2) or more (Ti≧t2), the total heat exchange mode q6 is selected. When the indoor temperature Ti is 27[° C.] (t3) or more (Ti≦t3), the purge mode q1 is selected.

[When temporary cooling mode p3 is set]
FIG. 10 is an explanatory diagram showing regions for setting the actual operation mode when the temporary cooling mode p3 is set as the temporary operation mode. When the provisional cooling mode p3 is set, the outdoor temperature To is high, so basically the cooling mode q4 is operated to reduce the load on the indoor air conditioner. However, when the indoor temperature Ti is low, the operation is performed in the total heat exchange mode q6 to exchange sensible heat.

In the temporary cooling mode p3, either the total heat exchange mode q6 or the cooling mode q4 is selected and implemented based on the indoor temperature Ti and the indoor humidity Hi. When the indoor humidity Hi is less than 0.0111 [kg/kg] (h3) and the indoor temperature Ti is less than 27 [° C.] (t3) (Hi<h3, Ti<t3), the total heat exchange mode q6 otherwise select cooling mode q4.

[When temporary heating mode p4 is set]
FIG. 11 is an explanatory diagram showing regions for setting the actual operation mode when the temporary heating mode p4 is set as the temporary operation mode. When the provisional heating mode p4 is set, the outdoor temperature To is low, so basically the operation is performed in the heating mode q5 to reduce the load on the indoor air conditioner. When the indoor temperature is appropriate, the total heat exchange mode q6 is operated, and when the indoor temperature is high, the purge mode q1 is operated to lower the room temperature.

In the temporary heating mode p4, one of the heating mode q5, the total heat exchange mode q6, and the purge mode q1 is selected based on the room temperature. When the indoor temperature Ti is less than 18 [° C.] (t2) (Ti<t2), the heating mode q5 is selected. Total heat exchange mode q6 is selected when ≦Ti<t3), and purge mode q1 is selected when 27[° C.] (t3) or more (t3≦Ti).

[When temporary purge mode p5 is set]
FIG. 12 is an explanatory diagram showing regions for setting the actual operation mode when the temporary purge mode p5 is set as the temporary operation mode. When the temporary purge mode p5 is set, basically, the operation is performed in the purge mode q1, and when the indoor temperature Ti is high, the operation is performed in the cooling mode q4 to reduce the indoor temperature Ti.
In the provisional purge mode p5, the purge mode q1 or the cooling mode q4 is selected and implemented based on the room temperature. When the indoor temperature Ti is less than 27[°C] (t3) (Ti<t3), the purge mode q1 is selected, and when it is 27[°C] (t3) or more (t3≤Ti), the cooling mode is selected. Select q4.

[When temporary dehumidification mode p6 is set]
FIG. 13 is an explanatory diagram showing areas for setting the actual operation mode when the temporary dehumidification mode p6 is set as the temporary operation mode. When the temporary dehumidification mode p6 is set, the outdoor humidity Ho is high, so basically the dehumidification mode q2 is operated, and when the indoor temperature Ti is low, the total heat exchange mode q6 is operated.

In the temporary dehumidification mode p6, the total heat exchange mode q6 or the dehumidification mode q2 is selected based on the room temperature Ti and the room humidity Hi. When the indoor humidity Hi is less than 0.0111 [kg/kg] (h3) and the indoor temperature Ti is less than 27 [° C.] (t3) (Hi<h3, Ti<t3), total heat exchange Select mode q6, otherwise select dehumidification mode q2.

[When temporary high humidity total heat exchange mode p7 is set]
FIG. 14 is an explanatory diagram showing regions for setting the actual operation mode when the temporary high-humidity total heat exchange mode p7 is set as the temporary operation mode. When the temporary high humidity total heat exchange mode p7 is set, the dehumidification mode q2 is selected when the room temperature Ti is high or the room humidity Hi is high.

In the temporary high humidity total heat exchange mode p7, it is assumed that the outdoor humidity Ho is higher than the indoor humidity Hi. In that case, the operation is performed in the total heat exchange mode q6, but when the indoor humidity Hi is high, the operation is performed in the dehumidification mode q2. Even in the dehumidifying mode q2, if the difference in humidity between the indoor and outdoor areas exceeds a specified value, the efficiency of the refrigerant circuit 90 decreases and the dehumidification capacity decreases, so the total heat exchange mode q6 is selected.

In the temporary high-humidity total heat exchange mode p7, the total heat exchange mode q6 or the dehumidification mode q2 is selected and implemented based on the room temperature Ti and the room humidity Hi. First, hr2 (hr2=Ho-.DELTA.h2), which is lower than the outdoor humidity Ho by 0.0069 [kg/kg] (.DELTA.h2), is calculated and stored in the storage section 31c.

When the indoor humidity Hi is less than hr2 (second humidity threshold) and the indoor temperature Ti is less than 27 [° C.] (t2) (Hi<hr2 and Ti<t2), total heat exchange mode q6 otherwise select dehumidification mode q2.

Thus, the actual operation modes (q1 to q6) are set based on the provisional operation modes (p1 to p7), the indoor temperature Ti, the indoor humidity Hi, and the relative humidity Hr.

[Description of the action of the present embodiment]
Next, the operation of the outside air processing device according to this embodiment will be described with reference to the flow charts shown in FIGS. 15 to 22. FIG.
FIG. 15 is a flowchart showing the processing procedure for setting the temporary operation mode (see FIG. 7) described above, and FIGS. It is a flowchart which shows the procedure of the process which sets an actual operation mode when the cooling mode p3, the temporary heating mode p4, the temporary purge mode p5, the temporary dehumidification mode p6, and the temporary high humidity total heat exchange mode p7 are selected.

[Processing procedure for provisional operation mode setting]
A processing procedure for setting the temporary operation mode will be described with reference to the flowchart shown in FIG. 15 and FIG. 7 . This processing is executed by the main control unit 31 shown in FIG.

First, in step S11, the main controller 31 operates the EA fan 9 and the SA fan 10 shown in FIG.

In step S12, the main control section 31 acquires the outdoor temperature To detected by the outdoor temperature sensor 23 and the outdoor humidity Ho detected by the outdoor humidity sensor 24, and stores them in the storage section 31c.

In step S13, the main controller 31 determines whether the outdoor humidity Ho is less than the first reference humidity h1 (eg, 0.0027 [kg/kg]). If “Ho<h1” (S13; YES), in step S14, the main control unit 31 selects the temporary low humidity total heat exchange mode p1 (the “temporary low humidity total heat exchange mode p1” in FIG. 7 area).

If not "Ho<h1" (S13; NO), in step S15, the main control unit 31 determines that the outdoor humidity Ho is less than the second reference humidity h2 (for example, h2=0.0066) and the outdoor temperature It is determined whether or not To is lower than the third reference temperature t3 (for example, t3=27.0).

If "Ho<h2 and To<t3" (S15; YES), the main control unit 31 selects the temporary humidification mode p2 in step S16 (the "temporary humidification mode p2" in FIG. 7). area).

If not "Ho<h2 and To<t3" (S15; NO), in step S17, the main control unit 31 determines that the outdoor humidity Ho is less than the third reference humidity h3 (for example, h3=0.0111). and whether or not the outdoor temperature To is equal to or higher than the third reference temperature t3.

If “Ho<h3 and t3≦To” (S17; YES), in step S18, the main control unit 31 selects the temporary cooling mode p3 (the “temporary cooling mode p3” in FIG. area).

If not "Ho<h3 and t3≦To" (S17; NO), in step S19, the main control unit 31 determines that the outdoor humidity Ho is less than the third reference humidity h3 and the outdoor temperature To is the first 2 Determine whether or not the temperature is less than a reference temperature t2 (for example, t2=18.0).

If "Ho<h3 and To<t2" (S19; YES), the main controller 31 selects the temporary heating mode p4 in step S20 ("temporary heating mode p4 ” area).

If not "Ho<h3 and To<t2" (S19; NO), in step S21, the main controller 31 determines whether the outdoor humidity Ho is less than the third reference humidity h3.

If "Ho<h3" (S21; YES), in step S22, the main controller 31 selects the provisional purge mode p5 (see the "provisional purge mode p5" area in FIG. 7).

If not "Ho<h3" (S21; NO), in step S23, the main control unit 31 checks whether the outdoor humidity Ho is less than the fourth reference humidity h4 (for example, h4=0.0180). judge.

If "Ho<h4" (S23; YES), then in step S24, the main control section 31 selects the temporary dehumidification mode p6 (see the area of "temporary dehumidification mode p6" in FIG. 7).

If not "Ho<h4"(S23; NO), in step S25, the main control unit 31 selects the temporary high-humidity total heat exchange mode p7.
Thus, the temporary operation mode is set based on the outdoor humidity Ho and the outdoor temperature To.

Next, processing for determining the actual operation mode in each temporary operation mode set in the above processing will be described.

[Processing procedure when temporary low humidity total heat exchange mode p1 is selected; see FIG. 8]
FIG. 16 is a flow chart showing the process of determining the actual operation mode when the provisional low-humidity total heat exchange mode p1 is set.
First, in step S31, the main control unit 31 acquires the indoor temperature Ti detected by the indoor temperature sensor 25 and the indoor humidity Hi detected by the indoor humidity sensor 26, and stores them in the storage unit 31c.

In step S32, the main control section 31 calculates the relative humidity Hr from the indoor temperature Ti and the indoor humidity Hi (absolute humidity) and stores it in the storage section 31c.

In step S33, the main control unit 31 calculates the threshold humidity hr1 based on the outdoor humidity Ho using the formula "hr1=Ho+0.0039" and stores it in the storage unit 31c.

In step S34, the main controller 31 determines whether the indoor temperature Ti is lower than the first reference temperature t1 (for example, t1=8.0). If "Ti<t1" (S34; YES), in step S35, the main control unit 31 operates the outside air processing device 100 in the heating mode q5.

If not "Ti<t1" (S34; NO), in step S36, the main control unit 31 determines whether the indoor temperature Ti is equal to or higher than the first reference temperature t1 and lower than the third reference temperature t3. judge. If "t1≤Ti<t3" (S36; YES), in step S37, the main controller 31 determines that the relative humidity Hr is less than 60[%] and that the indoor humidity Hi is the threshold humidity. It is determined whether or not it is less than hr1.

If "Hr<60% and Hi<hr1" (S37; YES), the main control unit 31 operates the outside air processing device 100 in the humidification mode q3 in step S38.

If not "Hr<60% and Hi<hr1" (S37; NO), in step S39, the main control unit 31 controls the indoor temperature Ti to be lower than the second reference temperature t2 (for example, t2 is 18° C.). It is determined whether or not. When "Ti<t2" (S39; YES), in step S40, the main control unit 31 operates the outside air processing device 100 in the heating mode q5.

If not "Ti<t2" (S39; NO), in step S41, the main control unit 31 operates the outside air processing device 100 in the total heat exchange mode q6.

On the other hand, in the process of step S36, if "t1≤Ti<t3" is not satisfied (S36; NO), in step S42, the main control unit 31 operates the outside air treatment device 100 in the purge mode q1. In this way, the actual operation mode is set when the provisional low-humidity total heat exchange mode p1 is set, and the operation of the outside air processing device 100 is controlled.

[Processing procedure when temporary humidification mode p2 is selected; see FIG. 9]
FIG. 17 is a flow chart showing the process of determining the actual operation mode when the temporary humidification mode p2 is set.
First, in step S51, the main control unit 31 acquires the indoor temperature Ti detected by the indoor temperature sensor 25 and the indoor humidity Hi detected by the indoor humidity sensor 26, and stores them in the storage unit 31c.

In step S52, the main control section 31 calculates the relative humidity Hr from the room temperature Ti and the room humidity Hi (absolute humidity) and stores it in the storage section 31c.

In step S53, the main controller 31 determines whether the indoor temperature Ti is lower than the first reference temperature t1 (for example, t1=8.0). If "Ti<t1" (S53; YES), the main controller 31 operates the outside air processing device 100 in the heating mode q5 in step S54.

If not "Ti<t1" (S53; NO), in step S55, the main controller 31 determines whether the indoor temperature Ti is equal to or higher than the reference temperature t1 and lower than the reference temperature t3. If "t1≤Ti<t3" (S55; YES), in step S56, the main controller 31 determines that the relative humidity Hr is less than 60% and the indoor humidity Hi is less than the second reference humidity h2. (For example, h2=0.0066).

If "Hr<60% and Hi<h2" (S56; YES), the main controller 31 operates the outside air processing device 100 in the humidification mode q3 in step S57.

If not "Hr<60% and Hi<h2" (S56; NO), in step S58, the main control unit 31 controls the indoor temperature Ti to be less than the second reference temperature t2 (for example, t2=18.0 ). If "Ti<t2" (S58; YES), the main control unit 31 operates the outside air processing device 100 in the heating mode q5 in step S59.

If not "Ti<t2" (S58; NO), in step S60, the main control unit 31 operates the outside air processing device 100 in the total heat exchange mode q6.

On the other hand, in the process of step S55, if not "t1≤Ti<t3" (S55; NO), in step S61, the main control unit 31 operates the outside air treatment device 100 in the purge mode q1. In this way, the actual operation mode is set when the temporary humidification mode p2 is set, and the operation of the outside air processing device 100 is controlled.

[Processing procedure when temporary cooling mode p3 is selected; see FIG. 10]
FIG. 18 is a flow chart showing the process of determining the actual operation mode when the provisional cooling mode p3 is set.
First, in step S71, the main control unit 31 acquires the indoor temperature Ti detected by the indoor temperature sensor 25 and the indoor humidity Hi detected by the indoor humidity sensor 26, and stores them in the storage unit 31c.

In step S72, the main controller 31 determines whether the indoor temperature Ti is lower than the third reference temperature t3 and the indoor humidity Hi is lower than the third reference humidity h3. If "Ti<t3, Hi<h3" (S72; YES), the main control unit 31 operates the outside air processing device 100 in the total heat exchange mode q6 in step S73.

If not "Ti<t3 and Hi<h3" (S72; NO), in step S74, the main control unit 31 operates the outside air processing device 100 in the cooling mode q4. Thus, the setting of the actual operation mode when the provisional cooling mode p3 is set is performed, and the operation of the outside air processing device 100 is controlled.

[Processing procedure when temporary heating mode p4 is selected; see FIG. 11]
FIG. 19 is a flow chart showing the process of determining the actual operation mode when the temporary heating mode p4 is set.
First, in step S81, the main control section 31 acquires the room temperature Ti detected by the room temperature sensor 25 and stores it in the storage section 31c.

In step S82, the main controller 31 determines whether the room temperature Ti is lower than the second reference temperature t2 (for example, t2=18.0). When "Ti<t2" (S82; YES), in step S83, the main control unit 31 operates the outside air processing device 100 in the heating mode q5.

If not "Ti<t2" (S82; NO), in step S84, the main control unit 31 determines whether the indoor temperature Ti is equal to or higher than the second reference temperature t2 and lower than the third reference temperature t3. judge. If "t2≦Ti<t3" (S84; YES), the main control unit 31 operates the outside air processing device 100 in the total heat exchange mode q6 in step S85.

If not "t2≦Ti<t3" (S84; NO), in step S86, the main control unit 31 operates the outside air treatment device 100 in the purge mode q1. Thus, the setting of the actual operation mode when the provisional heating mode p4 is set is performed, and the operation of the outside air treatment device 100 is controlled.

[Processing procedure when temporary purge mode p5 is selected; see FIG. 12]
FIG. 20 is a flow chart showing the process of determining the actual operation mode when the temporary purge mode p5 is set.
First, in step S91, the main control unit 31 acquires the indoor temperature Ti detected by the indoor temperature sensor 25 and stores it in the storage unit 31c.

In step S92, the main controller 31 determines whether the room temperature Ti is lower than the third reference temperature t3. If "Ti<t3" (S92; YES), the main control unit 31 operates the outside air processing device 100 in the purge mode q1 in step S93.

If not "Ti<t3" (S92; NO), in step S94, the main control unit 31 operates the outside air processing device 100 in the cooling mode q4. In this way, the actual operation mode is set when the temporary purge mode p5 is set, and the operation of the outside air treatment device 100 is controlled.

[Processing procedure when temporary dehumidification mode p6 is selected; see FIG. 13]
FIG. 21 is a flow chart showing the process of determining the actual operation mode when the temporary dehumidification mode p6 is set.
First, in step S101, the main control unit 31 acquires the indoor temperature Ti detected by the indoor temperature sensor 25 and the indoor humidity Hi detected by the indoor humidity sensor 26, and stores them in the storage unit 31c.

In step S102, the main controller 31 determines whether the indoor temperature Ti is lower than the third reference temperature t3 and the indoor humidity Hi is lower than the third reference humidity h3. When "Ti<t3 and Hi<h3" (S102; YES), the main control unit 31 operates the outside air processing device 100 in the total heat exchange mode q6 in step S103.

If not "Ti<t3 and Hi<h3" (S102; NO), the main control unit 31 operates the outside air processing device 100 in the dehumidification mode q2 in step S104. Thus, the actual operation mode is set when the temporary dehumidification mode p6 is set, and the operation of the outside air processing device 100 is controlled.

[Processing procedure when temporary high humidity total heat exchange mode p7 is selected; see FIG. 14]
FIG. 22 is a flowchart showing the process of determining the actual operation mode when the temporary high-humidity total heat exchange mode p7 is set.
First, in step S111, the main control unit 31 acquires the indoor temperature Ti detected by the indoor temperature sensor 25 and the indoor humidity Hi detected by the indoor humidity sensor 26, and stores them in the storage unit 31c.

In step S112, the main control unit 31 calculates a humidity threshold hr2 (second humidity threshold) by subtracting 0.0069 from the outdoor temperature Ho, and stores it in the storage unit 31c.

In step S113, the main controller 31 determines whether the indoor temperature Ti is lower than the third reference temperature t3 and the indoor humidity Hi is lower than the humidity hr2. When "Ti<t3 and Hi<hr2" (S113; YES), in step S114, the main control unit 31 operates the outside air processing device 100 in the total heat exchange mode q6.

If not "Ti<t3 and Hi<hr2" (S113; NO), in step S115, the main control unit 31 operates the outside air processing device 100 in the dehumidification mode q2. Thus, the setting of the actual operation mode when the provisional high-humidity total heat exchange mode p7 is set is performed, and the operation of the outside air processing device 100 is controlled.

[Description of effects of the present embodiment]
Thus, the following effects are obtained in the outside air processing device 100 according to the present embodiment.
(1)
In this embodiment, temporary low humidity total heat exchange mode p1 (first temporary total heat exchange mode), temporary humidification mode p2, temporary cooling mode p3, temporary heating mode p4, temporary purge mode p5, temporary dehumidification are used as temporary operation modes. Seven temporary operation modes are set: mode p6, temporary high-humidity total heat exchange mode p7 (second temporary total heat exchange mode). Then, one of the temporary operation modes (p1 to p7) is selected based on the outdoor temperature To and the outdoor humidity Ho. Then, instead of operating the outside air processing device 100 as it is in the temporary operation mode, the actual operation mode is set based on the indoor temperature Ti, the indoor humidity Hi, and the indoor relative humidity Hr. Therefore, it becomes possible to operate the outside air processing device 100 in an appropriate actual operation mode according to the indoor environment, and it is possible to reduce energy consumption without impairing comfort.

(2)
As shown in FIG. 8, when the temporary low-humidity total heat exchange mode p1 is selected, if the operation is performed in the purge mode q1, the outside air is introduced as it is, so the indoor temperature Ti drops. That is, the room temperature Ti shifts to the left from the region q1 in FIG. Further, when the humidification mode q3 is used, the indoor humidity Hi increases. That is, the indoor humidity Hi shifts upward from the region q3 in FIG. When the engine is operated in the heating mode q5, the indoor temperature Ti rises. That is, the room temperature Ti shifts to the right from the region q5 in FIG.

Therefore, with the lapse of time, the indoor temperature Ti and the indoor humidity Hi shift to the region of the total heat exchange mode q6. In the total heat exchange mode q6, as shown in FIG. 6, although the motor 20 that drives the desiccant rotor 8 is rotated, the refrigerant circuit 90 is stopped, so energy consumption can be reduced without impairing comfort. becomes.

In addition, the temporary humidification mode p2 shown in FIG. 9 also shifts to the total heat exchange mode q6 with the passage of time, as in FIG. 8, and it is possible to reduce energy consumption without impairing comfort. becomes.

(3)
As shown in FIG. 10, when the provisional cooling mode p3 is selected and the operation is performed in the cooling mode q4, the outdoor air is cooled and then introduced into the room, so the indoor temperature Ti drops. That is, the room temperature Ti shifts to the left from the region q4 in FIG. Therefore, the indoor temperature Ti and the indoor humidity Hi shift to the total heat exchange mode q6 with the lapse of time. Therefore, energy consumption can be reduced without compromising comfort.

(4)
As shown in FIG. 11, when the provisional heating mode p4 is selected and the operation is performed in the purge mode q1, low-temperature outdoor air is introduced into the room, so the room temperature Ti drops. That is, the room temperature Ti shifts to the left from the region q1 in FIG. Further, when the operation is performed in the heating mode q5, the outdoor air is heated and introduced into the room, so the indoor temperature Ti rises. That is, the room temperature Ti shifts to the right from the region q5 in FIG. Therefore, the indoor temperature Ti shifts to the area of the total heat exchange mode q6 with the lapse of time. Therefore, energy consumption can be reduced without compromising comfort.

(5)
As shown in FIG. 12, when the provisional purge mode p5 is selected and the operation is performed in the cooling mode q4, the outdoor air is cooled and then introduced into the room, so the indoor temperature Ti drops. That is, the room temperature Ti shifts to the left from the region q4 in FIG. Therefore, the room temperature Ti shifts to the region of the purge mode q1 with the lapse of time. As shown in FIG. 6, in the purge mode q1, the motor 20 that drives the refrigerant circuit 90 and the desiccant rotor 8 is stopped, and only the EA fan 9 and the SA fan 10 are operated. Energy consumption can be reduced.

(6)
As shown in FIG. 13, when the temporary dehumidification mode p6 is selected and the operation is performed in the dehumidification mode q2, the outdoor air is dehumidified and introduced into the room, so the indoor temperature Ti drops. That is, the room temperature Ti shifts to the left from the region q2 in FIG. Therefore, the indoor temperature Ti and the indoor humidity Hi shift to the region of the total heat exchange mode q6 with the lapse of time. Therefore, energy consumption can be reduced without compromising comfort.

Also, the temporary high-humidity total heat exchange mode p7 shown in FIG. 14 will shift to the total heat exchange mode q6 as time passes, as in FIG. 13, reducing energy consumption without impairing comfort. It becomes possible to

(7)
Summarizing the contents of (2) to (6) described above, the outdoor air processing device 100 can be operated by selecting an appropriate operation mode according to the outdoor temperature To, the outdoor humidity Ho, the indoor temperature Ti, and the indoor humidity Hi. . As a result, if the capacity of the outdoor air processing device 100 and the indoor air conditioner are appropriate for the indoor load, the indoor environment approaches the target temperature and humidity. Then, the outside air processing device 100 shifts to the total heat exchange mode q6 or the purge mode q1, so it is possible to reduce energy consumption without impairing comfort.

Although embodiments of the present invention have been described above, the statements and drawings forming part of this disclosure should not be construed as limiting the present invention. Various alternative embodiments, implementations and operational techniques will become apparent to those skilled in the art from this disclosure.

1 compressor 2 accumulator 3 four-way valve 4 third heat exchanger 5 first heat exchanger 6 fourth heat exchanger 7 second heat exchanger 8 desiccant rotor 9 EA fan 10 SA fan 12 first air flow path 13 second second Air flow path 18 First expansion valve 19 Second expansion valve 20 Motor 23 Outdoor temperature sensor 24 Outdoor humidity sensor 25 Indoor temperature sensor 26 Indoor humidity sensor 31 Main control unit 31a Sensor input unit 31b Operation unit 31c Storage unit 90 Refrigerant circuit 100 Outside air Processing equipment EA Exhaust air OA Outdoor air RA Indoor air SA Supply air h1i First reference indoor humidity h1o First reference outdoor humidity h2i Second reference indoor humidity h2o Second reference outdoor humidity h3i Third reference indoor humidity h3o Third reference outdoor humidity h4i Fourth reference indoor humidity h4o Fourth reference outdoor humidity t1i First reference indoor temperature t1o First reference outdoor temperature t2i Second reference indoor temperature t2o Second reference outdoor temperature t3i 3 reference indoor temperature t3o third reference outdoor temperature Hr relative humidity hr1 first humidity threshold hr2 second humidity threshold p1 temporary low humidity total heat exchange mode (first temporary total heat exchange mode)
p2 temporary humidification mode p3 temporary cooling mode p4 temporary heating mode p5 temporary purge mode p6 temporary dehumidification mode p7 temporary high humidity total heat exchange mode (second temporary total heat exchange mode)
q1 Purge mode q2 Dehumidification mode q3 Humidification mode q4 Cooling mode q5 Heating mode q6 Total heat exchange mode

Claims (8)

a first air flow path for supplying outdoor air indoors;
a second air flow path for exhausting indoor air to the outdoors;
outdoor temperature detection means for detecting an outdoor temperature (To), which is the temperature of the air introduced into the first air flow path;
outdoor humidity detection means for detecting outdoor humidity (Ho), which is the absolute humidity of the air introduced into the first air flow path;
Room temperature detection means for detecting room temperature (Ti), which is the temperature of the air introduced into the second air flow path;
indoor humidity detection means for detecting indoor humidity (Hi), which is the absolute humidity of the air introduced into the second air flow path;
disposed across the first air flow path and the second air flow path and adsorbing moisture in air flowing through one of the first air flow path and the second air flow path; a rotary moisture adsorption means for releasing moisture into the air flowing through the other flow path;
a refrigerant circuit that heats air flowing through one of the first air flow path and the second air flow path and cools air flowing through the other;
A storage unit that stores in advance a plurality of provisional operation modes that are provisionally set based on the relationship between the outdoor temperature (To) and the outdoor humidity (Ho),
The temporary operation mode is
a first temporary total heat exchange mode (p1) set when the outdoor humidity (Ho) is lower than a predetermined first reference outdoor humidity (h1o);
A fourth reference outdoor humidity (h4o) higher than the first reference outdoor humidity (h1o) is set, and a second temporary total heat set when higher than the fourth reference outdoor humidity (h4o) exchange mode (p7);
A third reference outdoor humidity (h3o) that is higher than the first reference outdoor humidity (h1o) and lower than the fourth reference outdoor humidity (h4o) is set, and the outdoor humidity (Ho) is a temporary dehumidification mode (p6) that is set when the humidity is higher than the third reference outdoor humidity (h3o) and lower than the fourth reference outdoor humidity (h4o);
Furthermore,
When the outdoor temperature (To) and the outdoor humidity (Ho) are acquired, one temporary operation mode is set from a plurality of the temporary operation modes based on these relationships, and the one temporary operation mode and , based on the indoor temperature (Ti) and the indoor humidity (Hi) , any one of the following operation modes (A) to (F) is selected, the moisture adsorption means, and control means for controlling at least one of the refrigerant circuits;
An outside air processing device comprising:
(A) a dehumidification mode in which the moisture adsorption means is rotated and the refrigerant circuit is operated to cool the first air flow path; (B) the moisture adsorption means is rotated and the refrigerant circuit is operated and the Humidification mode (C) for heating the first air flow path Cooling mode (D) for cooling the first air flow path by stopping the moisture adsorption means and operating the refrigerant circuit (D) Stopping the moisture adsorption means and a heating mode (E) in which the refrigerant circuit is operated to heat the first air flow path, the moisture adsorption means is rotated at high speed, the refrigerant circuit is stopped, and the first air flow path is A total heat exchange mode (F) in which total heat is exchanged between the second air flow path and the second air flow path (F) A purge mode in which only ventilation is performed by stopping the moisture adsorption means and the refrigerant circuit The temporary operation mode is
When the outdoor humidity (Ho) is between the first reference outdoor humidity (h1o) and the third reference outdoor humidity (h3o), and the outdoor temperature (To) is a predetermined third reference 2. The outdoor air processing apparatus according to claim 1 , further comprising a temporary cooling mode (p3) that is set when the temperature is higher than the outdoor temperature (t3o). A second reference outdoor humidity (h2o) that is higher than the first reference outdoor humidity (h1o) and lower than the third reference outdoor humidity (h3o) is set, and the outdoor humidity (Ho) is Higher than the first reference outdoor humidity (h1o) and lower than the second reference outdoor humidity (h2o), and the outdoor temperature (To) is lower than the third reference outdoor temperature (t3o) 3. The outside air processing apparatus according to claim 2 , further comprising a temporary humidification mode (p2) that is set in a case. setting a second reference outdoor temperature (t2o) lower than the third reference outdoor temperature (t3o);
The outdoor humidity (Ho) is higher than the second reference outdoor humidity (h2o) and lower than the third reference outdoor humidity (h3o), and the outdoor temperature (To) is the second reference 4. The outside air processing apparatus according to claim 3 , further comprising a provisional purge mode (p5) that is set when the temperature is higher than the outdoor temperature (t2o) and lower than the third reference outdoor temperature (t3o). . setting a second reference outdoor temperature (t2o) lower than the third reference outdoor temperature (t3o);
The outdoor humidity (Ho) is higher than the second reference outdoor humidity (h2o) and lower than the third reference outdoor humidity (h3o), and the outdoor temperature (To) is the second reference 5. The outdoor air processing device according to claim 3 , further comprising a temporary heating mode (p4) set when the temperature is lower than the outdoor temperature (t2o). When the first temporary total heat exchange mode is set,
The control means is
The indoor temperature (Ti) is
setting the operation mode to the purge mode when it is higher than a predetermined third reference indoor temperature (t3i);
A second reference room temperature (t2i) lower than the third reference room temperature (t3i) is set, the room temperature (Ti) is higher than the second reference room temperature (t2i), and the 3, and the indoor humidity (Hi) is higher than a predetermined first humidity threshold (hr1), the operation mode is set to the total heat exchange mode. ,
The outside air processing device according to claim 1 , wherein the first humidity threshold (hr1) is changed according to the outdoor humidity (Ho). When the second temporary total heat exchange mode is set,
The control means is
When the indoor temperature (Ti) is higher than a predetermined third reference indoor temperature (t3i), or when the indoor humidity (Hi) is higher than a predetermined second humidity threshold (hr2), the operation Set the mode to the dehumidification mode,
When the indoor temperature (Ti) is lower than the third reference indoor temperature (t3i) and the indoor humidity (Hi) is lower than the second humidity threshold (hr2), the operation mode is changed to Set to the total heat exchange mode,
The outdoor air processing device according to claim 1 , wherein the second humidity threshold (hr2) is changed according to the outdoor humidity (Ho). When the temporary purge mode is set,
The control means is
setting the operating mode to the cooling mode when the indoor temperature (Ti) is higher than a predetermined third reference indoor temperature (t3i);
The outside air processing apparatus according to claim 4 , wherein the operation mode is set to the purge mode when the indoor temperature (Ti) is lower than the third reference indoor temperature (t3i).

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