JP2023047582A - Ventilation control device, ventilation control method and ventilation control system - Google Patents

Abstract

To suppress increase in indoor humidity in a room in which an air-conditioning device is installed.SOLUTION: A ventilation control device 1 controls a ventilation fan 2 for exchanging indoor air in a room in which an air conditioner 3 is installed. The ventilation control device 1 includes a first control section 111 for operating the ventilation fan 2 when first moisture amount WA1 removed by the air conditioner 3 per unit time is larger than second moisture amount WA2 per unit time included in outside air flowing into the room by operating the ventilation fan 2.SELECTED DRAWING: Figure 2

Description

The present invention relates to a ventilation control device, a ventilation control method, and a ventilation control system for controlling a ventilation device.

Various techniques are known for controlling a ventilator (see, for example, Patent Document 1).
The building ventilation system described in Patent Document 1 includes an A point sensor that measures at least the temperature at a well-ventilated measurement point A, a B point sensor that measures at least the humidity at a poorly ventilated measurement point B, and at least the temperature outdoors It has an outdoor sensor that measures, a ventilation device, and a control device that performs operation control of the ventilation device. If the temperature is higher than the temperature, the ventilation device is operated, and if the temperature at the measurement point A is lower than the outdoor temperature, the relative humidity at the measurement point B and the upper limit of the indoor relative humidity are judged to be high or low. When the relative humidity of B is higher than the indoor relative humidity upper limit value, operation control of the ventilator is executed.

JP 2019-219086 A

However, the building ventilation system described in Patent Literature 1 may not be able to properly control indoor humidity.
For example, if the temperature of the outside air is low even in summer, the air conditioner may turn off the thermostat and the dehumidification amount may decrease. In addition, the indoor humidity may increase due to the supply of outside air.
An object of the present invention is to provide a ventilation control device, a ventilation control method, and a ventilation control system capable of suppressing an increase in indoor humidity in a room in which an air conditioner is installed.

An embodiment according to the present invention is a ventilation control device for controlling a ventilation device for ventilating air in a room in which an air conditioner is arranged, wherein the air conditioner dehumidifies per unit time. Ventilation control, comprising a first control unit that operates the ventilator when a moisture content per unit time contained in outside air flowing into the room is greater than a second moisture content per unit time when the ventilator is operated. It is a device.

Further, in the above ventilation control device, the first control unit controls the flow rate of air blown out from the air conditioner, the flow rate of outside air flowing into the room by the ventilation device, the absolute humidity in the room, and the air conditioner Whether or not the first moisture content is greater than the second moisture content may be determined based on the absolute humidity of the air blown out from the device and the absolute humidity of the outside air.

Further, in the above ventilation control device, when the temperature in the room is higher than the temperature of the outside air and the absolute humidity in the room is higher than the absolute humidity in the outside air, the ventilation device is operated to A second control unit may be provided that stops the ventilation device when the temperature is higher than the temperature of the outside air and the absolute humidity in the room is equal to or lower than the absolute humidity of the outside air.

Further, the ventilation control device may include a third control unit that stops the operation of the ventilation device when the temperature of the outside air is equal to or lower than the temperature threshold.

Another embodiment of the present invention is a ventilation control method for controlling a ventilation device that ventilates air in a room in which an air conditioner is arranged, wherein the air conditioner dehumidifies per unit time. A first control step of operating the ventilator when a first moisture content is greater than a second moisture content per unit time contained in outside air flowing into the room by operating the ventilator. , is the ventilation control method.

Yet another embodiment of the present invention is a ventilation control system comprising a ventilation device for ventilating air in a room in which an air conditioner is arranged, and a ventilation control device for controlling the ventilation device. The ventilation control device determines that the first amount of moisture dehumidified by the air conditioner per unit time is the second amount of moisture per unit time contained in the outside air flowing into the room by operating the ventilation device. A ventilation control system, comprising a first control that operates the ventilator when is greater than.

ADVANTAGE OF THE INVENTION According to this invention, the indoor humidity rise can be suppressed in the room in which the air conditioning apparatus is arrange|positioned.

It is a figure showing an example of composition of a ventilation control system concerning this embodiment. It is a figure which shows an example of a structure of a ventilation fan and a ventilation control apparatus. It is a flow chart which shows an example of processing of a ventilation control device.

Embodiments will be described below with reference to the drawings.

[1. Overall configuration of ventilation control system]
First, the overall configuration of the ventilation control system 100 will be described with reference to FIG. FIG. 1 is a diagram showing an example of the configuration of a ventilation control system 100 according to this embodiment. The directions are shown in FIG. For example, the upward direction in FIG. 1 is north, and the rightward direction in FIG. 1 is east.
The ventilation control system 100 includes a ventilation control device 1, a ventilation fan 2, an indoor temperature/humidity sensor S1, an outside temperature/humidity sensor S2, an outlet temperature/humidity sensor S3, and a carbon dioxide sensor S4.
The ventilation control device 1, the indoor temperature/humidity sensor S1, the outlet temperature/humidity sensor S3, and the carbon dioxide sensor S4 are arranged inside the room RM. The ventilation fan 2 is arranged on the wall surface of the room RM.
The outside air temperature and humidity sensor S2 is arranged outside the room RM. In this embodiment, the exterior of the room RM is part of the outdoors. That is, the veranda BL is part of the outdoors.

An air conditioner 3 is arranged in the room RM. The air conditioner 3 is arranged on the wall surface on the north side of the room RM.
Specifically, the air conditioner 3 includes an indoor unit 31 and an outdoor unit 32 . The indoor unit 31 of the air conditioner 3 is arranged inside the room RM. The outdoor unit 32 is arranged on the veranda BL.

The air conditioner 3 has cooling and heating functions. In this embodiment, the case where the air conditioner 3 performs the cooling operation will be described. Note that the air conditioner 3 may be in a so-called thermo-off state during cooling operation. “Thermo off” means that the outdoor unit 32 stops when the temperature inside the room RM reaches the set temperature of the air conditioner 3 . In the "thermo-off" state, the outdoor unit 32 is stopped, so the air conditioner 3 is in a blowing operation state in which indoor air is circulated. In the thermo-off state, the indoor air is not dehumidified by the air conditioner 3, so the indoor humidity may increase due to ventilation.
The air conditioner 3 corresponds to an example of an "air conditioner".

In this embodiment, a case where the air conditioner is the air conditioner 3 will be described, but the present invention is not limited to this. The air conditioner should just have a dehumidifying function and a cooling function. For example, the air conditioner may be a dehumidifier with a cooling function.

The ventilation control device 1 controls the ventilation fan 2 .
The ventilation fan 2 is composed of a ventilation fan 21 and a ventilation fan 22 . The ventilation fan 21 and the ventilation fan 22 have substantially the same configuration. The ventilation fan 21 is arranged on the wall surface on the east side of the room RM. The ventilation fan 22 is arranged on the wall on the west side of the room RM.
The ventilation fan 2 allows outside air to flow into the room RM. The ventilation fan 2 is communicably connected to the ventilation control device 1 and turns on and off according to instructions from the ventilation control device 1 .
The ventilation fan 2 corresponds to an example of a "ventilator".

In this embodiment, the case where the ventilation device is the ventilation fan 2 will be described, but it is not limited to this. It is sufficient that the ventilator can draw outside air into the room RM. For example, a ventilation device may draw outside air into the room RM through a duct using a fan or the like.
In this embodiment, the case where the ventilating fan 2 is composed of the ventilating fan 21 and the ventilating fan 22 will be described, but the present invention is not limited to this. The ventilation fan 2 may be composed of one ventilation fan, or the ventilation fan 2 may be composed of three or more ventilation fans.

The indoor temperature/humidity sensor S1 is arranged inside the room RM and detects the temperature T1 and the humidity H1 inside the room RM.
Specifically, the indoor temperature and humidity sensor S1 includes an indoor temperature sensor S11 and an indoor humidity sensor S12. The indoor temperature sensor S11 detects the indoor temperature T1 of the room RM. The indoor humidity sensor S12 detects the indoor humidity H1 of the room RM. Humidity H1 is relative humidity.
A temperature T1 and a humidity H1 detected by the indoor temperature/humidity sensor S1 are output to the ventilation control device 1. FIG.

The outdoor air temperature and humidity sensor S2 is placed outdoors (for example, outdoors) and detects the temperature T2 and humidity H2 of the outdoor air.
Specifically, the outside air temperature and humidity sensor S2 includes an outside air temperature sensor S21 and an outside air humidity sensor S22. The outdoor air temperature sensor S21 detects the outdoor air temperature T2 of the room RM. The outdoor air humidity sensor S22 detects the humidity H2 of the outdoor air outside the room RM. Humidity H2 is relative humidity.
A temperature T2 and a humidity H2 detected by the outside air temperature and humidity sensor S2 are output to the ventilation control device 1. FIG.

The blowout temperature/humidity sensor S3 is arranged at the blowout port of the air conditioner 3, and detects the temperature T3 and the humidity H3 of the air blown out from the blowout port.
Specifically, the blowout temperature/humidity sensor S3 includes a blowout temperature sensor S31 and a blowout humidity sensor S32. The blowout temperature sensor S31 detects the temperature T3 of the air blown out from the blowout port. The blowing humidity sensor S32 detects the humidity H3 of the air blown from the blowing port. Humidity H3 is relative humidity.
A temperature T3 and a humidity H3 detected by the blowout temperature/humidity sensor S3 are output to the ventilation control device 1 .

The carbon dioxide sensor S4 is arranged inside the room RM and detects the concentration CR of carbon dioxide inside the room RM. The carbon dioxide sensor S4 detects, for example, using infrared absorption characteristics, such as a non-dispersive infrared (NDIR: Non Dispersive Infrared) detection method.
A carbon dioxide concentration CR detected by the carbon dioxide sensor S4 is output to the ventilation control device 1 .

In this embodiment, a case where the ventilation control system 100 includes the carbon dioxide sensor S4 will be described, but the present invention is not limited to this. For example, ventilation control system 100 may not include carbon dioxide sensor S4.

[2. Configuration of ventilation fan and ventilation control device]
Now refer to FIG. The configurations of the ventilation fan 2 and the ventilation control device 1 will be described. FIG. 2 is a diagram showing an example of the configuration of the ventilation fan 2 and the ventilation control device 1. As shown in FIG.
As shown in FIG. 2 , the ventilation fan 2 includes a drive control section 211 , a motor 213 and a fan 215 .

The drive control section 211 controls the operation of the motor 213 according to the instruction signal SG from the ventilation control device 1 . The drive control unit 211 turns on and off the intake operation by the fan 215 by turning on and off the motor 213 .
Motor 213 drives fan 215 according to an instruction from drive control unit 211 .
The fan 215 is driven by the motor 213 and supplies outside air to the interior of the room RM.

Next, the configuration of the ventilation control device 1 will be described with reference to FIG.
As shown in FIG. 2 , the ventilation control device 1 is configured by, for example, a personal computer, and includes a control section 11 , an operation section 12 and a display section 13 . The control section 11 controls the operation of each section of the ventilation control device 1 .

The control unit 11 has a processor 11A and a memory 11B. The processor 11A is composed of, for example, a CPU (Central Processing Unit), an MPU (Micro-Processing Unit), and the like. The memory 11B is composed of, for example, a RAM (Random Access Memory), a ROM (Read Only Memory), and the like.
The memory 11B stores data such as the control program PGM. The memory 11B may also include a storage device such as an HDD (Hard Disk Drive) or an SSD (Solid State Drive).

The processor 11A may be composed of a single processor, or may be configured such that a plurality of processors functions as the processor 11A. The processor 11A executes the control program PGM to control the operation of the ventilation fan 2. FIG.

The operation unit 12 includes, for example, keys, switches, LEDs (Light Emitting Eiodes), and the like. The operation unit 12 receives user operations and outputs operation signals corresponding to the received operations to the control unit 11 .

The display unit 13 is configured by, for example, an LCD (Liquid Crystal Display). The display unit 13 displays various images according to instructions from the control unit 11 . The display unit 13 may be composed of a touch panel. In this case, instead of or in addition to the operation unit 12 , the touch panel accepts the user's operation and outputs an operation signal corresponding to the accepted operation to the control unit 11 .

[3. Functional configuration of control device]
As shown in FIG. 2 , the controller 11 includes a first controller 111 , a second controller 112 and a third controller 113 .
Specifically, the processor 11A of the control unit 11 functions as the first control unit 111, the second control unit 112, and the third control unit 113 by executing the control program PGM.

The first control unit 111 determines that the first moisture amount WA1 dehumidified by the air conditioner 3 per unit time is the second moisture amount WA2 per unit time contained in the outside air flowing into the room RM by operating the ventilation fan 2. If it is larger than , the ventilation fan 2 is operated.
Specifically, the first control unit 111 controls the flow rate F3 of the air blown from the air conditioner 3, the flow rate F2 of the outside air flowing into the room RM, the indoor absolute humidity HA1 of the room RM, and the air blown from the air conditioner 3. It is determined whether or not the first water content WA1 is greater than the second water content WA2 based on the absolute humidity HA3 of the outside air and the absolute humidity HA2 of the outside air.
Absolute humidity HA1 is obtained from humidity H1 and temperature T1. Absolute humidity HA2 is obtained from humidity H2 and temperature T2. Absolute humidity HA3 is obtained from humidity H3 and temperature T3. Absolute humidity HA1 to absolute humidity HA3 are so-called “weight absolute humidity”. The absolute humidity HA1 to absolute humidity HA3 may be so-called "volumetric absolute humidity".

The first water content WA1 is obtained by the following formula (1) as the processing amount W1 of latent heat by the air conditioner 3.
W1=WT×D1×F3×(HA1-HA3) (1)
Here, the latent heat of vaporization WT is the amount of heat required for water to change into steam. Density D1 is the density of the air blown out from the air conditioner 3 . Density D1 is obtained, for example, from temperature T3 and humidity H3 of the air blown out from the outlet.

As the flow rate F3, for example, the design value of the flow rate during the cooling operation of the air conditioner 3 is input into the equation (1). Specifically, for example, based on the indoor temperature T1 and the temperature set value, the design value of the flow rate during the cooling operation of the air conditioner 3 is obtained. The temperature setting value may be an estimated value, or may be set based on a user's operation from the operation unit 12 .

The second moisture content WA2 is obtained by the following equation (2) as the amount W2 of latent heat acquired by ventilation of the ventilation fan 2.
W2=WT×D2×F2×(HA2-HA1) (2)
Here, the density D2 is the density of the outside air that flows in due to ventilation by the ventilation fan 2 . As the flow rate F2, for example, the flow rate set at the time of designing the ventilation fan 2 is input to Equation (2). Density D2 is obtained, for example, from outdoor temperature T2 and humidity H2.

In this embodiment, the case where the outlet temperature/humidity sensor S3 is arranged at the outlet of the air conditioner 3 will be described, but the present invention is not limited to this. For example, a preset value may be used as the absolute humidity HA3. In this case, the outlet temperature/humidity sensor S3 does not need to be arranged at the outlet of the air conditioner 3, and the configuration of the ventilation control system 100 can be simplified.

Thus, the ventilation fan 2 is operated when the first water content WA1 is greater than the second water content WA2. When the first water content WA1 is greater than the second water content WA2, for example, the indoor temperature T1 rises by letting outside air flow into the room. Therefore, for example, the air conditioner 3 can be changed from the thermo-off state to the cooling operation state, and the air conditioner 3 can dehumidify the air in the room. Therefore, it is possible to suppress an increase in the indoor humidity H1 due to the inflow of outside air into the room.

The second control unit 112 operates the ventilation fan 2 when the indoor temperature T1 is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is higher than the outdoor air absolute humidity HA2.
Further, the second control unit 112 stops the ventilation fan 2 when the indoor temperature T1 is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is equal to or lower than the outdoor air absolute humidity HA2.

Thus, when the indoor temperature T1 is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is higher than the outdoor air absolute humidity HA2, the ventilation fan 2 is operated to allow outside air to flow into the room. , the indoor temperature T1 can be lowered, and the indoor humidity H1 can be lowered.
Further, when the indoor temperature T1 is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is lower than the outdoor air absolute humidity HA2, stopping the ventilation fan 2 prevents the outdoor air from flowing into the room. can suppress an increase in the humidity H1 of the

The third control unit 113 stops the operation of the ventilation fan 2 when the outside air temperature T2 is equal to or lower than the temperature threshold SHT. The temperature threshold SHT is, for example, 23°C.

In this manner, when the outside air temperature T2 is equal to or lower than the temperature threshold SHT, the operation of the ventilation fan 2 is stopped, so that an excessive decrease in the indoor temperature T1 due to the inflow of outside air into the room can be suppressed.

[3. Processing of control unit]
Next, the processing of the control unit 11 of the ventilation control device 1 will be described with reference to FIG. FIG. 3 is a flowchart showing an example of processing of the control unit 11. As shown in FIG.
As shown in FIG. 3, first, in step S101, the control unit 11 acquires the detection value of each sensor.
Specifically, the control unit 11 acquires the detected values of the temperature T1 and the humidity H1 from the indoor temperature and humidity sensor S1. Further, the control unit 11 acquires the detected values of the temperature T2 and the humidity H2 from the outside air temperature/humidity sensor S2. Further, the control unit 11 acquires each detected value of the temperature T3 and the humidity H3 from the blowout temperature/humidity sensor S3. The control unit 11 also acquires the detected value of the carbon dioxide concentration CR from the carbon dioxide sensor S4.

Next, in step S103, the control unit 11 determines whether or not the detected value of the concentration CR of carbon dioxide is less than the concentration threshold. A concentration threshold is, for example, 1000 ppm.
When the control unit 11 determines that the detected value of the carbon dioxide concentration CR is not less than the concentration threshold value (step S103; NO), the process proceeds to step S105.
Then, in step S105, the control unit 11 operates the ventilation fan 2. FIG. After that, the process proceeds to step S129.
When the controller 11 determines that the detected value of the concentration CR of carbon dioxide is less than the concentration threshold (step S103; YES), the process proceeds to step S107.
Then, in step S107, the control unit 11 determines whether or not the humidity H1, which is the indoor relative humidity, is greater than the humidity threshold. A humidity threshold is, for example, 70%.

When the controller 11 determines that the indoor humidity H1 is not higher than the humidity threshold (step S107; YES), the process proceeds to step S109.
Then, in step S109, the control unit 11 stops the ventilation fan 2. After that, the process proceeds to step S129.
When the controller 11 determines that the indoor humidity H1 is higher than the humidity threshold (step S107; YES), the process proceeds to step S111.
Then, in step S111, the third control unit 113 determines whether or not the outside air temperature T2 is higher than the temperature threshold SHT. The temperature threshold SHT is, for example, 23°C.

When the third control unit 113 determines that the outside air temperature T2 is not higher than the temperature threshold SHT (step S111; NO), the process proceeds to step S113.
Then, in step S113, the third control unit 113 stops the ventilation fan 2. After that, the process proceeds to step S129.
When the third control unit 113 determines that the outside air temperature T2 is higher than the temperature threshold SHT (step S111; YES), the process proceeds to step S115.
Then, in step S115, the second control unit 112 determines whether the indoor temperature T1 is higher than the outdoor air temperature T2.

When the second control unit 112 determines that the indoor temperature T1 is higher than the outdoor air temperature T2 (step S115; YES), the process proceeds to step S123. When the second control unit 112 determines that the indoor temperature T1 is not higher than the outdoor air temperature T2 (step S115; NO), the process proceeds to step S117.
Then, in step S117, the first control unit 111 determines whether or not the first water content WA1 is greater than the second water content WA2. The first moisture amount WA1 is the amount of moisture that the air conditioner 3 dehumidifies per unit time. Specifically, it is the amount of moisture dehumidified per unit time when the air conditioner 3 is in cooling operation. The second water content WA2 is the water content per unit time contained in the outside air flowing into the room RM by operating the ventilation fan 2 .
When it is determined that the first water content WA1 is not greater than the second water content WA2 (step S117; NO), the process proceeds to step S119.
Then, in step S119, the first control unit 111 stops the ventilation fan 2. After that, the process proceeds to step S129.
If it is determined that the first water content WA1 is greater than the second water content WA2 (step S117; YES), the process proceeds to step S121.
Then, in step S121, the first control unit 111 operates the ventilation fan 2. FIG. After that, the process proceeds to step S129.

If YES in step S115, that is, if the second control unit 112 determines that the indoor temperature T1 is higher than the outside air temperature T2, in step S123, the second control unit 112 sets the indoor absolute humidity HA1 is greater than the absolute humidity HA2 of the outside air.
When the second control unit 112 determines that the indoor absolute humidity HA1 is not higher than the outdoor air absolute humidity HA2 (step S123; NO), the process proceeds to step S125.
Then, in step S125, the second control unit 112 stops the ventilation fan 2. After that, the process proceeds to step S129.
When the second control unit 112 determines that the indoor absolute humidity HA1 is higher than the outdoor air absolute humidity HA2 (step S123; YES), the process proceeds to step S127.
Then, in step S127, the second control unit 112 operates the ventilation fan 2. FIG.
Next, in step S129, the control unit 11 determines whether or not to end the ventilation control. “Ventilation control” is control for determining whether the ventilation fan 2 is turned on or off, which is executed in steps S101 to S127 of FIG. For example, the control unit 11 receives an operation from the user and determines whether or not to end the ventilation control according to the received operation.
When the control unit 11 determines not to end the ventilation control (step S129; NO), the process returns to step S101. When the control unit 11 determines to end the ventilation control (step S129; YES), the ventilation control is ended.

Steps S117, S119, and S121 correspond to an example of the "first control step."

As described with reference to FIG. 3, the ventilation control device 1 operates the ventilation fan 2 when the detected value of the indoor carbon dioxide concentration CR is not less than the concentration threshold. Therefore, the indoor carbon dioxide concentration CR can be reduced.

Further, when the humidity H1, which is the indoor relative humidity, is not greater than the humidity threshold, the ventilation control device 1 stops the ventilation fan 2. FIG. Note that the humidity threshold is set to a value desired by the user, for example. Therefore, if the humidity H1, which is the indoor relative humidity, is not greater than the humidity threshold, it is not necessary to lower the indoor humidity H1. Therefore, the ventilation fan 2 can be stopped when the humidity H1, which is the indoor relative humidity, is not greater than the humidity threshold.

Further, when the temperature T2 of the outside air is not higher than the temperature threshold SHT, the ventilation fan 2 is stopped. Note that the temperature threshold SHT is set to a desired value by the user. Therefore, when the outside air temperature T2 is not higher than the temperature threshold SHT, it is not necessary to operate the air conditioner 3 for cooling. Therefore, when the outside air temperature T2 is not higher than the temperature threshold SHT, stopping the ventilation fan 2 can suppress an increase in the indoor humidity H1.

[4. Effect of this embodiment]
As described above, the ventilation control device 1 according to the present embodiment is a ventilation control device 1 that controls the ventilation fan 2 that ventilates the indoor air in the room where the air conditioner 3 is arranged. A first control unit that operates the ventilation fan 2 when the first moisture content WA1 per unit time to be dehumidified is greater than the second moisture content WA2 per unit time contained in the outside air that flows into the room by operating the ventilation fan 2. 111.

That is, the first control unit 111 determines that the first moisture amount WA1 dehumidified by the air conditioner 3 per unit time is greater than the second moisture amount WA2 per unit time contained in the outside air flowing into the room by operating the ventilation fan 2. is large, the ventilation fan 2 is operated.
When the first water content WA1 is greater than the second water content WA2, the ventilation fan 2 is operated to allow outside air to flow into the room, thereby increasing the indoor temperature T1, for example. As a result, for example, the air conditioner 3 can be changed from the thermo-off state to the cooling operation state, and the air in the room can be dehumidified by the air conditioner 3 . Therefore, it is possible to suppress an increase in the indoor humidity H1 due to the inflow of outside air into the room.

In addition, the first control unit 111 controls the flow rate F3 of the air blown out from the air conditioner 3, the flow rate F2 of the outside air flowing into the room by the ventilation fan 2, the indoor absolute humidity HA1, the absolute humidity HA3 of the air blown out from the air conditioner 3, Based on the absolute humidity HA2 of the outside air, it is determined whether or not the first water content WA1 is greater than the second water content WA2.

That is, the first control unit 111 calculates, for example, the latent heat processing amount W1 by the air conditioner 3 by the above equation (1), and the latent heat acquisition amount W2 by the ventilation of the ventilation fan 2 by the above equation (2). . Then, it is determined whether or not the first water content WA1 is greater than the second water content WA2 depending on whether or not the processing amount W1 is greater than the obtained amount W2. Therefore, it can be properly determined whether or not the first water content WA1 is greater than the second water content WA2.

Further, when the indoor temperature T1 is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is higher than the outdoor air absolute humidity HA2, the ventilation control device 1 operates the ventilation fan 2 to is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is equal to or lower than the outdoor air absolute humidity HA2.

That is, the ventilation fan 2 is operated when the indoor temperature T1 is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is higher than the outdoor air absolute humidity HA2. Therefore, it is possible to allow the outside air to flow into the room, lower the indoor temperature T1, and lower the indoor humidity H1.
Further, when the indoor temperature T1 is higher than the outdoor air temperature T2 and the indoor absolute humidity HA1 is lower than the outdoor air absolute humidity HA2, the ventilation fan 2 is stopped. Therefore, it is possible to suppress an increase in the indoor humidity H1 due to the inflow of outside air into the room.

The ventilation control device 1 also includes a third control unit 113 that stops the operation of the ventilation fan 2 when the outside air temperature T2 is equal to or lower than the temperature threshold SHT.

That is, when the outside air temperature T2 is equal to or lower than the temperature threshold SHT, the operation of the ventilating fan 2 is stopped.
When the outside air temperature T2 is equal to or lower than the temperature threshold SHT, the air conditioner 3 does not need to be operated for cooling. Therefore, by stopping the operation of the ventilation fan 2, it is possible to suppress an increase in the indoor humidity H1 due to the inflow of outside air into the room.

Further, the ventilation control method according to the present embodiment is a ventilation control method for controlling the ventilation fan 2 that ventilates the indoor air in the room where the air conditioner 3 is arranged. A first control step of operating the ventilation fan 2 when the moisture content WA1 is greater than a second moisture content WA2 per unit time contained in the outside air flowing into the room by operating the ventilation fan 2 is included.
Therefore, the ventilation control method according to this embodiment has the same effect as the ventilation control device 1 according to this embodiment.

In addition, the ventilation control system 100 according to the present embodiment is a ventilation control system 100 that includes a ventilation fan 2 that ventilates the indoor air and a ventilation control device 1 that controls the ventilation fan 2 in a room where the air conditioner 3 is arranged. In the ventilation control device 1, the first moisture amount WA1 dehumidified by the air conditioner 3 per unit time is greater than the second moisture amount WA2 per unit time contained in the outside air flowing into the room by operating the ventilation fan 2. A first control unit 111 is provided to operate the ventilation fan 2 when the air pressure is large.
Therefore, the ventilation control system 100 according to this embodiment has the same effects as the ventilation control device 1 according to this embodiment.

[5. Other embodiments]
The present invention is not limited to the configurations of the above-described embodiments, and can be implemented in various aspects without departing from the spirit of the present invention.
For example, in this embodiment, a case where the ventilation control device 1 is configured by a personal computer will be described, but the present invention is not limited to this. The ventilation control device 1 may be composed of, for example, a tablet terminal, a smartphone, or the like.

At least some of the functional blocks shown in FIG. 2 may be realized by hardware, or may be realized by cooperation of hardware and software. It is not limited to a configuration in which hardware resources are arranged.
Also, the control program PGM executed by the control unit 11 may be stored in another storage unit within the memory. Also, a control program stored in an external device may be acquired via a communication unit or the like and executed.

In addition, the processing unit of the flowchart shown in FIG. 3 is divided according to the main processing content in order to facilitate understanding of the processing of the control unit 11 . The embodiment is not limited by the division method or names of the processing units shown in the flowchart shown in FIG. Further, the processing of the control unit 11 can be divided into more processing units according to the processing contents, or can be divided so that one processing unit includes more processing. Also, the processing order of the above flowchart is not limited to the illustrated example.

Further, the control method of the ventilation fan 2 can be realized by causing the processor 11A provided in the ventilation control device 1 to execute the control program PGM corresponding to the control method of the ventilation fan 2. FIG. The control program PGM can also be recorded in a computer-readable recording medium.
A magnetic or optical recording medium or a semiconductor memory device can be used as the recording medium. Specifically, flexible disks, HDDs, CD-ROMs (Compact Disk Read Only Memory), DVDs, Blu-ray (registered trademark) Discs, magneto-optical disks, flash memories, card-type recording media, and other portable or fixed recording medium of the formula. Moreover, the recording medium may be a non-volatile storage device such as RAM, ROM, HDD, etc., which is an internal storage device provided in the ventilation control device 1 .
By storing the control program PGM in a server device or the like and downloading the control program PGM from the server device to the ventilation control device 1, the control method of the ventilation fan 2 can be realized.

100 ventilation control system 1 ventilation control device 11 control unit 11A processor 11B memory 111 first control unit 112 second control unit 113 third control unit 12 operation unit 13 display unit PGM control program 2, 21, 22 ventilation fan (ventilation device)
211 drive control unit 213 motor 215 fan 3 air conditioner (air conditioner)
31 Indoor unit 32 Outdoor unit BL Veranda CR Density D1, D2 Density F2, F3 Flow rate H1, H2, H3 Humidity HA1, HA2, HA3 Absolute humidity PGM Control program RM Room S1 Indoor temperature and humidity sensor S11 Indoor temperature sensor S12 Indoor humidity sensor S2 Outside air temperature and humidity sensor S21 Outside air temperature sensor S22 Outside air humidity sensor S3 Outlet temperature and humidity sensor S31 Outlet temperature sensor S32 Outlet humidity sensor S4 Carbon dioxide sensor SG Instruction signal SHT Temperature threshold T1, T2, T3 Temperature W1 Processing amount W2 Obtained amount WA1 First Water content WA2 Second water content WT Evaporation latent heat

Claims (6)

A ventilation control device for controlling a ventilation device for ventilating air in a room in which an air conditioner is arranged,
When the first amount of moisture that the air conditioner dehumidifies per unit time is larger than the second amount of moisture per unit time contained in the outside air that flows into the room by operating the ventilation device, the ventilation A first control unit that operates the device,
Ventilation control device. The first control unit controls the flow rate of air blown out from the air conditioner, the flow rate of outside air flowing into the room by the ventilation device, the absolute humidity in the room, and the absolute humidity of the air blown out from the air conditioner. , determining whether the first moisture content is greater than the second moisture content based on the absolute humidity of the outside air;
A ventilation control device according to claim 1 . When the indoor temperature is higher than the outdoor air temperature and the indoor absolute humidity is higher than the outdoor air absolute humidity, the ventilation device is operated, and the indoor temperature is higher than the outdoor air temperature. A second control unit that stops the ventilation device when the absolute humidity in the room is higher than or equal to the absolute humidity in the outside air,
The ventilation control device according to claim 1 or 2. A third control unit that stops the operation of the ventilation device when the temperature of the outside air is equal to or lower than the temperature threshold,
The ventilation control device according to any one of claims 1 to 3. A ventilation control method for controlling a ventilation device for ventilating air in a room in which an air conditioner is arranged,
When the first amount of moisture that the air conditioner dehumidifies per unit time is larger than the second amount of moisture per unit time contained in the outside air that flows into the room by operating the ventilation device, the ventilation a first control step of operating the device;
ventilation control methods, including; A ventilation control system comprising a ventilation device for ventilating air in a room in which an air conditioner is arranged, and a ventilation control device for controlling the ventilation device,
In the ventilation control device, a first amount of moisture dehumidified by the air conditioner per unit time is larger than a second amount of moisture per unit time contained in outside air flowing into the room by operating the ventilation device. A first control unit that operates the ventilator when it is large,
Ventilation control system.

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