JP2021165625A - Ventilation blower and ventilation blower system - Google Patents

Abstract

To acquire a ventilation blower which can be used for an automatic operation by acquiring information about the state of indoor air and information about the state of outdoor air, with a simple structure.SOLUTION: A ventilation blower 101 is installed at a wall for partitioning an inside 203 and an outside 204 in a building in which a 24-hour full-time ventilation blower for performing 24-hour full-time ventilation is installed and which includes a natural air supply port. The ventilation blower 101 includes: a fan 1; an air passage 2 which communicates the inside 203 and the outside 204, and through which the air blown by the fan 1 passes; a control part 5 for performing adjustment of the rotational frequency of the fan 1; and an air state detection part arranged on the same side as the control part 5 with respect to the wall and for detecting the state of the air. The control part 5 stops the fan 1 only for a period of predetermined downtime at predetermined timing out of predetermined unit time. The air state detection part detects the state of the air of the inside 203 in the case where the fan 1 is operating, and detects the state of the air of the outside 204 in the period of the downtime.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to ventilation blowers and ventilation blower systems that ventilate the interior of a building.

Conventionally, the ventilation blowers installed in residential and non-residential buildings are generally installed in multiple places in the building such as kitchens, bathrooms, dressing rooms, toilets, closets, living rooms, and corridors. Is. It consumes a lot of energy if all the ventilation blowers in the building are always in operation. Therefore, there is a ventilation blower that automatically operates, stops, or changes the air volume according to the surrounding environment by mounting a detection unit such as a temperature detection unit and a humidity detection unit on the ventilation blower.

For example, in a ventilation blower equipped with a temperature detector, the ventilation blower is operated for the purpose of exhausting heat when the indoor temperature exceeds a predetermined operating threshold temperature, and the ventilation blower is stopped when the indoor temperature falls below the operating threshold temperature. Control is performed automatically. In such a ventilation blower, the operating threshold temperature is set to a temperature at which the user feels that the room needs to be exhausted, so that the exhaust heat is automatically exhausted only when necessary without bothering the user. be able to.

However, in summer, when the temperature of the outside air is higher than the temperature of the room, the temperature inside the room becomes higher than the operating threshold temperature, and when the ventilation blower operates, the room air is exhausted to the outside and the room becomes negative pressure. Therefore, outside air having a temperature higher than the indoor temperature equal to that of the exhausted air flows in from the air supply port of the building, and the indoor temperature further rises. For this reason, the automatic operation of the ventilation blower not only produces the opposite result for the purpose of exhausting heat, but also consumes unnecessary energy for operating the ventilation blower.

In order to suppress the occurrence of such unintended results by the user, Patent Document 1 includes an indoor temperature detecting unit that detects the indoor temperature and an outdoor temperature detecting unit that detects the temperature of the outside air. A ventilation device that detects both the temperature of the air and the temperature of the outside and controls the operation based on the detection result is described.

Japanese Unexamined Patent Publication No. 2005-114277

However, the ventilation device disclosed in Patent Document 1 is provided with two detection units, an indoor temperature detection unit and an outdoor temperature detection unit, the indoor temperature detection unit is installed indoors, and the outdoor temperature detection unit is outdoors. Since it is installed, there is a problem that the structure becomes complicated and the construction work at the time of installation becomes complicated.

The present disclosure has been made in view of the above, and an object thereof is to obtain a ventilation blower that can be used for automatic operation by acquiring information on the state of indoor air and information on the state of outdoor air with a simple structure. do.

In order to solve the above-mentioned problems and achieve the object, the ventilation blower according to the present disclosure can be used indoors and outdoors in a building in which a 24-hour continuous ventilation blower is installed to provide 24-hour continuous ventilation and a natural air supply port is provided. It is a ventilation blower that is installed on the partition wall to communicate indoors and outdoors. The ventilation blower is arranged on the same side as the control unit with respect to the wall, the air passage that communicates the fan with the indoor and outdoor areas and the air blown by the fan, the control unit that adjusts the rotation speed of the fan, and the wall. It is provided with an air condition detection unit that detects the air condition. The control unit stops the fan for a predetermined pause time period at a predetermined timing within the predetermined unit time. The air condition detection unit detects the indoor air condition when the fan is operating, and detects the outdoor air condition during the rest period.

The ventilation blower according to the present disclosure has an effect that it can be used for automatic operation by acquiring information on the state of indoor air and information on the state of outdoor air with a simple structure.

Sectional drawing which shows the ventilation blower which concerns on Embodiment 1. The figure which shows the functional configuration which concerns on the control of the operation of the ventilation blower which concerns on Embodiment 1. Top view of the building where the ventilation system according to the first embodiment is installed. FIG. 3 is a view corresponding to FIG. 3, which is a top view of the building when the ventilation blower according to the first embodiment is stopped. Operation control diagram of the ventilation blower according to the first embodiment Sectional drawing which shows the ventilation blower which concerns on Embodiment 2. The figure which shows the functional configuration which concerns on the control of the operation of the ventilation blower which concerns on Embodiment 2. Top view of the building where the ventilation system according to the second embodiment is installed. FIG. 8 is a view corresponding to FIG. 8, which is a top view of the building when the ventilation blower according to the second embodiment is stopped. Operation control diagram of the ventilation blower according to the second embodiment Sectional drawing which shows the ventilation blower which concerns on Embodiment 3. The figure which shows the functional configuration which concerns on the control of the operation of the ventilation blower which concerns on Embodiment 3. Top view of the building where the ventilation system according to the third embodiment is installed. It is the top view of the building of the structure for comparison with respect to FIG. 13, and is the top view of the building when the ventilation blower which concerns on Embodiment 1 is stopped. Operation control diagram of the ventilation blower according to the third embodiment Top view of the building where the ventilation system according to the fourth embodiment is installed. Operation control diagram of the ventilation blower according to the fourth embodiment The figure which shows an example of the hardware composition of the processing circuit in Embodiment 1 to Embodiment 4.

The ventilation blower and the ventilation blower system according to the embodiment will be described in detail below with reference to the drawings.

Japanese buildings are required by the Building Standards Law to install ventilation equipment that can replace 50% or more of the air per hour in the living room, and replace 30% or more of the air per hour outside the living room. It is obligatory to install ventilation equipment that is possible. For this reason, at least one of the plurality of ventilation blowers installed in the building is designed to be constantly ventilated for 24 hours. Hereinafter, 24-hour continuous ventilation will be referred to as 24-hour ventilation.

However, if the ventilation blower installed in the kitchen or toilet discharges odor, or if the ventilation blower installed in the bathroom, dressing room, closet, etc. discharges hot air or humidity, ventilation with a large air volume is temporarily performed. May be needed. For this reason, it is common that a ventilation blower that can be operated with a ventilation air volume larger than the air volume required for 24-hour ventilation is installed in the building. Hereinafter, ventilation with a ventilation air volume larger than the air volume required for 24-hour ventilation is referred to as rapid ventilation.

Hereinafter, the ventilation blower according to the present disclosure, which can be used for 24-hour ventilation and rapid ventilation, or can be used for rapid ventilation, will be described.

Embodiment 1.
FIG. 1 is a cross-sectional view showing a ventilation blower 101 according to the first embodiment. In addition, in FIG. 1, a part is shown in the side view. FIG. 2 is a diagram showing a functional configuration related to control of operation of the ventilation blower 101 according to the first embodiment. The ventilation blower 101 according to the first embodiment is a ventilation blower used for 24-hour ventilation and rapid ventilation. The ventilation blower 101 is installed on the indoor 203 side with respect to the building wall 200. That is, the ventilation blower 101 is fitted into the opening 201 penetrating the wall 200 of the building, which is the wall separating the indoor 203 and the outdoor in the building, and communicates the indoor 203 and the outdoor 204.

The ventilation blower 101 includes a fan 1, an air passage 2, a temperature detection unit 3, an operation threshold temperature setting unit 4, and a control unit 5. The fan 1, the air passage 2, the temperature detection unit 3, the operation threshold temperature setting unit 4, and the control unit 5 are housed inside the housing 20 of the ventilation blower 101.

The fan 1 includes an impeller 1b and an electric motor 1a for rotating the impeller 1b.

The air passage 2 is an air passage through which the air blown by the fan 1 passes while communicating the indoor 203 and the outdoor 204. The air passage 2 is provided inside the housing 20 and communicates with the room 203 through the opening 21 on the indoor 203 side formed in the housing 20, and the opening on the outdoor 204 side formed in the housing 20. It communicates with the outdoor 204 via 22 and constitutes an exhaust air passage for discharging the air in the indoor 203 to the outdoor 204 by the air blown by the fan 1.

The temperature detection unit 3 is installed on the indoor 203 side and detects the temperature of the indoor 203, that is, the temperature of the indoor air. The temperature detection unit 3 is arranged on the surface of the housing 20 exposed in the room 203. The temperature detection unit 3 is arranged on the indoor 203 side, which is the same side as the control unit 5 with respect to the wall 200 of the building. The temperature detection unit 3 is communicably connected to the control unit 5 by a signal line (not shown), and transmits a room temperature signal indicating the detected temperature of the room 203 to the control unit 5. The temperature detection unit 3 is arranged on the same side as the control unit 5 with respect to the wall 200 of the building, that is, on the indoor 203 side, and is an air condition detection unit that detects the state of air passing around the ventilation blower 101 or the air passage 2. Is.

The operation threshold temperature setting unit 4 is a volume resistor for the user to adjust and set the operation threshold temperature. The operation threshold temperature is the temperature of the indoor air that is used as a reference when the control unit 5 automatically switches between the strong operation and the weak operation of the ventilation blower 101. The strong operation is an operation with a strong air volume having a relatively large air volume, and is a rapid ventilation operation. The weak operation is an operation with a weak air volume in which the air volume is relatively small, and is a 24-hour ventilation operation. The operating threshold temperature setting unit 4 can adjust and set the operating threshold temperature by turning a volume resistance knob (not shown). The operation threshold temperature setting unit 4 is communicably connected to the control unit 5 by a signal line (not shown), and transmits an operation threshold temperature signal indicating the operation threshold temperature set by the user to the control unit 5.

The control unit 5 controls the operation of the fan 1 to control the operation of the ventilation blower 101. The control unit 5 stores the temperature detected by the temperature detection unit 3, the operation threshold temperature set in the operation threshold temperature setting unit 4, the temperature stored in the temperature storage unit 6, and the fan control data storage unit 7. The operation of the fan 1 is controlled by adjusting the rotation speed of the fan 1 based on the obtained data.

The control unit 5 can acquire the temperature of the room 203 by receiving the room temperature signal transmitted from the temperature detection unit 3. The control unit 5 can acquire the operation threshold temperature by receiving the operation threshold temperature signal transmitted from the operation threshold temperature setting unit 4.

The control unit 5 uses a fan to rapidly exhaust the hot air in the room 203 when the temperature of the room 203 detected by the temperature detection unit 3 is equal to or higher than the operation threshold temperature set in the operation threshold temperature setting unit 4. The rapid ventilation that operates 1 with a strong air volume is automatically controlled. The control unit 5 operates the fan 1 with a weak air volume for 24 hours when the temperature of the room 203 detected by the temperature detection unit 3 is lower than the operation threshold temperature set in the operation threshold temperature setting unit 4. Control is performed automatically.

The temperature storage unit 6 is built inside the control unit 5, and stores the temperature detected by the temperature detection unit 3. The temperature storage unit 6 may be provided outside the control unit 5.

The fan control data storage unit 7 is built inside the control unit 5 and stores data indicating "the relationship between the rotation speed of the motor 1a and the air volume of the fan 1" acquired in advance during the development of the ventilation blower 101. ing. The fan control data storage unit 7 may be provided outside the control unit 5.

FIG. 3 is an upper view of the building in which the ventilation system 121 according to the first embodiment is installed. The ventilation system 121 includes a ventilation blower 111 having a function of a 24-hour ventilation blower that communicates indoor 203 and outdoor 204 to perform 24-hour ventilation in a building provided with a natural air supply port 112, and an indoor 203 in the building. A ventilation blower 101, which is installed by communicating the indoor 203 and the outdoor 204 with each other, is provided on the wall 200 of the building, which is a wall partitioning the outdoor 204 from the outdoor 204. FIG. 3 shows a case where the ventilation system 121 is in operation. Further, FIG. 3 is shown assuming the second floor of a detached house. The arrows in FIG. 3 indicate the direction in which air flows. The white arrows indicate the outdoor 204 air, and the hatched arrows indicate the indoor air. The same applies to the following figures.

The ventilation blower 101 is installed on the wall 200 of the building in order to exhaust the hot air accumulated on the second floor of the house to the outside 204 and to ventilate the second floor of the house. Further, a ventilation blower 111 is installed on the wall of the toilet 211, which is a part of the wall 200 of the building, in order to ventilate the toilet 211. The ventilation blower 111 is a general ventilation device that performs 24-hour ventilation and rapid ventilation, and has a function of a 24-hour continuous ventilation blower. The wall 200 of the building is provided with two natural air supply ports 112 for naturally supplying the air of the outdoor 204 to the inside of the building.

The ventilation blower 101 and the ventilation blower 111 have both ventilation functions of 24-hour ventilation and rapid ventilation, and when used for 24-hour ventilation, they are operated with a relatively small air volume and a weak air volume. When used for rapid ventilation, operate with a strong air volume, which is a relatively large air volume.

The ventilation blower 101 and the ventilation blower 111 are ventilated for 24 hours unless the user intentionally stops the ventilation blower 101 when a peculiar situation such as the wind of the outdoor 204 blowing into the indoor 203 occurs on the day of a typhoon. I'm driving. When the temperature of the room 203 detected by the temperature detection unit 3 becomes equal to or higher than the operation threshold temperature set by the operation threshold temperature setting unit 4, the control unit 5 of the ventilation blower 101 rapidly releases the hot air accumulated on the second floor of the house. The rapid ventilation that operates the fan 1 with a strong air volume to exhaust heat is automatically controlled. Further, when the temperature of the room 203 detected by the temperature detection unit 3 becomes lower than the operation threshold temperature set in the operation threshold temperature setting unit 4, the control unit 5 operates the fan 1 with a weak air volume for 24 hours. Control is performed automatically.

When the ventilation blower 101 is operating in the configuration shown in FIG. 3, the control unit 5 operates the fan 1 with a strong air volume or a weak air volume, so that the temperatures of the air passage 2 of the ventilation blower 101 and the ventilation blower 101 An airflow 301 from the room to the outside is generated around the detection unit 3. Therefore, the temperature detection unit 3 of the ventilation blower 101 detects the temperature of the room 203, that is, the temperature of the air in the room 203.

FIG. 4 is a view corresponding to FIG. 3, and is an upper view of the building when the ventilation blower 101 according to the first embodiment is stopped. Since the ventilation blower 101 has a role as a ventilation blower that ventilates for 24 hours, basically, the fan 1 is not stopped. However, the control unit 5 stops the fan 1 at a predetermined timing during the first hour period, which is a predetermined unit time, for the second hour period, which is a predetermined stop time. .. That is, the ventilation blower 101 stops the operation only for the period of the second hour, which is the predetermined stop time, in the period of the first hour, which is the predetermined unit time. The control unit 5 stops the fan 1 only for 3 minutes, which is the second time, out of 60 minutes, which is the first time, for example.

Since the ventilation blower 101 does not have a mechanism for blocking the air passage 2, the air passage 2 is in an open state even when the fan 1 is stopped, and the air passage 2 communicates the indoor 203 and the outdoor 204 with each other. It is in a state of being. At this time, the corridor 212 has a negative pressure due to the operation of the ventilation blower 111. Therefore, an airflow 302 from the outside to the inside is generated around the air passage 2 of the ventilation blower 101 and the temperature detection unit 3 of the ventilation blower 101. Therefore, the temperature detection unit 3 of the ventilation blower 101 detects the temperature of the outdoor 204, that is, the temperature of the air in the outdoor 204. That is, the temperature detection unit 3 detects the air state of the indoor 203 when the fan 1 is operating, and detects the air state of the outdoor 204 during the rest period.

As described above, the control unit 5 of the ventilation blower 101 intermittently stops the fan 1 for a predetermined second time period. That is, the control unit 5 of the ventilation blower 101 intermittently operates the fan 1 only during the third hour period excluding the first hour to the second hour. As a result, the temperature detection unit 3 of the ventilation blower 101 can detect the temperature of the indoor 203 during the operation period of the ventilation blower 101, and can detect the temperature of the outdoor 204 during the stop period of the ventilation blower 101. can. That is, the ventilation blower 101 can acquire information on both the temperature of the indoor 203 and the temperature of the outdoor 204 by using only one temperature detection unit 3 installed on the indoor 203 side. The temperature of the indoor 203 and the temperature of the outdoor 204 are information on the state of air.

Further, the weak air volume, which is the air volume when the ventilation blower 101 ventilates for 24 hours, is a weak air volume within a range in which the ventilation volume described in the Building Standards Act can be satisfied in the case of continuous operation. Therefore, if the ventilation blower 101 is stopped for 3 minutes out of 60 minutes, there is a concern that the minimum required ventilation air volume stipulated by the Building Standards Act cannot be satisfied.

Therefore, when the control unit 5 of the ventilation blower 101 stops the fan 1 in the period of 3 minutes out of 60 minutes, when the fan 1 is weakly operated in the remaining period of 57 minutes out of 60 minutes, The fan 1 is controlled so that the output of the fan 1 in the weak operation is 1.053 times = (60 minutes / 57 minutes) times that in the case where the fan 1 is continuously operated in the weak operation for a period of 60 minutes. As a result, even if the ventilation blower 101 is stopped for 3 minutes out of 60 minutes, the minimum required ventilation air volume stipulated by the Building Standards Act can be satisfied as a whole for the period of 60 minutes.

That is, when the control unit 5 of the ventilation blower 101 stops the fan 1 only for the second hour of the first hour while ventilating for 24 hours, the first hour is excluded from the second hour. The 3-hour period is an air volume that can satisfy the minimum required ventilation air volume stipulated by the Building Standards Law as a whole during the 1-hour period. The fan 1 is controlled in a weak operation by increasing the air volume to a larger air volume than the weak air volume in the case of making the air flow. Specifically, when the control unit 5 of the ventilation blower 101 stops the fan 1 only during the second hour of the first hour while ventilating for 24 hours, the control unit 5 operates the fan 1 over the first hour. The fan 1 is controlled so that the output of the fan 1 in the weak operation is doubled (1st hour / 3rd hour) with respect to the case of continuous operation in the weak operation.

The control unit 5 of the ventilation blower 101 can obtain a required ventilation air volume based on the data stored in the fan control data storage unit 7 indicating "the relationship between the rotation speed of the motor 1a and the air volume of the fan 1". As described above, the operation of the fan 1 is controlled by adjusting the rotation speed of the motor 1a.

When the fan 1 is intermittently stopped as described above, the shorter the period during which the fan 1 is intermittently stopped, the smaller the output of the weakly operated fan 1 during the period during which the fan 1 is intermittently operated can be suppressed. For example, when the fan 1 is stopped for 1 minute out of 60 minutes, when the fan 1 operates weakly for the remaining 59 minutes, the fan 1 operates weakly for 60 minutes continuously, whereas the fan 1 operates weakly. By increasing the output of 1 to 1.017 times = (60 minutes / 59 minutes) times, the minimum required ventilation air volume stipulated by the Building Standards Act can be satisfied. As a result, when the fan 1 is intermittently stopped for 1 minute, the air volume for weak operation can be reduced as compared with the case where the fan 1 is intermittently stopped for 3 minutes, and the operating noise of the ventilation blower 101 can be reduced. Increased comfort.

FIG. 5 is an operation control diagram of the ventilation blower 101 according to the first embodiment. First, in the entire period from 0 minutes to 330 minutes, the control unit 5 of the ventilation blower 101 is the first of the 60-minute period, which is the first hour, regardless of whether the fan 1 is operating strongly or weakly. The control for stopping the fan 1 is repeated only for a period of 3 minutes, which is 2 hours. During the second hour period when the fan 1 is stopped, the corridor 212 becomes negative pressure due to the operation of the ventilation blower 111, so that the air passage 2 of the ventilation blower 101 and the temperature detection unit 3 of the ventilation blower 101 An airflow 302 from the outside to the inside is generated in the surrounding area. Therefore, the temperature detection unit 3 of the ventilation blower 101 detects the temperature of the outdoor 204.

During the remaining third hour of the 60-minute period of 57 minutes, which is the first hour, the fan 1 is operating strongly or weakly, so that the air passage 2 and the temperature detection unit 3 are surrounded by the fan 1. , An airflow 301 from the room to the outside is generated. Therefore, the temperature detection unit 3 of the ventilation blower 101 detects the temperature of the room 203.

For 3 minutes after the temperature detection of the outdoor 204 was started and for 3 minutes after the temperature detection of the indoor 203 was started, the air in the indoor 203 and the outdoor 204 were around the temperature detection unit 3 of the ventilation blower 101. There is a possibility that the temperature of the room 203 cannot be accurately detected because it is mixed with air. Therefore, the control unit 5 does not determine whether or not the temperature of the room 203 is equal to or higher than the operating threshold temperature. Therefore, the control unit 5 operates the fan 1 with the same air volume as immediately before the start of the temperature detection of the outdoor 204 for 3 minutes after the temperature detection of the indoor 203 is started.

Further, the control unit 5 stores the temperature of the outdoor 204 detected at that time in the temperature storage unit 6 three minutes after the start of the temperature detection of the outdoor 204. That is, the temperature storage unit 6 stores the temperature of the outdoor 204 that was last detected in the second time. Then, the control unit 5 determines that the temperature of the room 203 at the present time is the period from the time when the temperature of the room 203 is detected to the time when another 57 minutes elapse, that is, the period until the third time elapses. And the temperature of the outdoor 204 stored in the temperature storage unit 6 are compared.

If the result of comparing the current temperature of the indoor 203 with the temperature of the outdoor 204 stored in the temperature storage unit 6 is higher than the temperature of the outdoor 204, that is, "indoor temperature> outdoor". In the case of "temperature", the control unit 5 controls the fan 1 to be strongly operated to positively exhaust the air in the room 203. As a result, the same amount of outside air as the air exhausted by the ventilation blower 101 and the ventilation blower 111, which is lower than the temperature of the room 203, flows into the inside of the building from the natural air supply port 112, so that a high heat exhaust effect can be obtained. can get.

The control for strongly operating the fan 1 is based on the premise that the temperature of the room 203 on the second floor is equal to or higher than the operation threshold temperature. Therefore, in the control for strongly operating the fan 1 during the period from the time when the temperature detection of the room 203 is started to the time when the third time elapses, the temperature of the room 203 on the second floor is equal to or higher than the operation threshold temperature. And "indoor temperature> outdoor temperature".

On the other hand, if the result of comparing the current temperature of the indoor 203 with the temperature of the outdoor 204 stored in the temperature storage unit 6 is lower than the temperature of the outdoor 204, that is, "indoor temperature". In the case of <outdoor temperature", the control unit 5 operates the fan 1 weakly to suppress the ventilation air volume to the minimum necessary ventilation air volume for 24-hour ventilation. As a result, the ventilation blower 101 reduces the amount of outside air, which is equal to the amount of air exhausted by the ventilation blower 101 and the ventilation blower 111 and is higher than the temperature of the room 203, flowing into the inside of the building from the natural air supply port 112. It is possible to prevent the temperature of the room 203 from rising further.

The control other than the control for stopping the fan 1 in order to detect the temperature of the outdoor 204 in the operation control diagram of the ventilation blower 101 shown in FIG. 5 will be described.

The period from 0 minutes to 80 minutes is the temperature detection unit except for the period of 3 minutes after the temperature detection of the outdoor 204 is started and the period of 3 minutes after the temperature detection of the indoor 203 is started. The temperature of the room 203 detected in No. 3 is less than the operating threshold temperature. Therefore, the control unit 5 controls the fan 1 to operate weakly.

In the period of 160 minutes after the lapse of 80 minutes, since the temperature of the room 203 is equal to or higher than the operation threshold temperature and “indoor temperature> outdoor temperature”, the control unit 5 controls the fan 1 to be strongly operated. As a result, the hot air on the second floor of the building can be positively discharged to the outdoor 204.

In the period of 280 minutes after the lapse of 160 minutes, the temperature of the room 203 is equal to or higher than the operation threshold temperature, but since "indoor temperature <outdoor temperature", the control unit 5 controls the fan 1 to operate weakly. .. As a result, the ventilation air volume of the entire second floor of the building can be reduced, so that the ventilation air volume required for 24-hour ventilation can be secured, and the outside air having a high temperature higher than the temperature of the indoor 203 is naturally supplied. It is possible to suppress the inflow from the mouth 112 into the inside of the building and prevent the temperature of the room 203 from further rising.

In the period of 330 minutes after the lapse of 280 minutes, since the temperature of the room 203 is equal to or higher than the operation threshold temperature and “indoor temperature> outdoor temperature”, the control unit 5 controls the fan 1 to be strongly operated. As a result, the hot air on the second floor of the building can be positively discharged to the outdoor 204.

After 330 minutes have passed, the temperature of the room 203 detected by the temperature detection unit 3 is less than the operating threshold temperature. Therefore, the control unit 5 of the ventilation blower 101 controls the fan 1 to operate weakly.

By controlling the operation of the fan 1 by the control unit 5 described above, the ventilation blower 101 can exhaust the hot air on the second floor of the building, which is the purpose of the user, without impairing the function as 24-hour ventilation. It is effectively feasible.

As described above, the ventilation blower 101 according to the first embodiment includes a fan 1, an air passage 2, a temperature detection unit 3, and a control unit 5. Then, the control unit 5 stops the fan for a predetermined pause time period at a predetermined timing in the predetermined unit time, and the temperature detection unit 3 stops the fan when the fan 1 is operating. The temperature of the indoor 203 is detected, and the temperature of the outdoor 204 is detected during the rest period. In this case, when the fan 1 is rotated, the temperature detection unit 3 detects the temperature of the indoor air, which is the air in the space on the upstream side in the direction in which the airflow generated in the air passage 2 flows. Further, the temperature detection unit 3 detects the temperature of the outdoor air, which is the air in the space on the upstream side in the direction in which the airflow generated in the air passage 2 flows, during the rest period.

The ventilation blower 101 configured in this way acquires information on both the temperature of the indoor 203 and the temperature of the outdoor 204 by using only one temperature detection unit 3 installed on the indoor 203 side. , Can be used to control the fan 1 by the control unit 5. As a result, the structure is not complicated, and information on both the temperature of the indoor 203 and the temperature of the outdoor 204 can be obtained with a simple structure, and the cost of the ventilation blower 101 can be reduced.

Further, since the control unit 5 and the temperature detection unit 3 are both installed on the indoor 203 side of the ventilation blower 101, the outdoor 204 side opposite to the indoor 203 side to the indoor 203 side across the wall 200 of the building. It is not necessary to wire the communication line of the temperature detection unit 3. That is, it is not necessary to wire the communication line between the control unit 5 and the temperature detection unit 3 between the indoor 203 side and the outdoor 204 side with the wall 200 of the building interposed therebetween. As a result, the time and cost of constructing the communication line of the temperature detection unit 3 can be suppressed.

Further, according to the configuration of the ventilation blower 101, the ventilation blower 101 installed on the indoor 203 side and the temperature detection unit 3 installed on the outdoor 204 side opposite to the indoor 203 side across the wall 200 of the building. Since a communication device for wireless communication is not required and the cost of the communication device is unnecessary, the cost of the ventilation blower 101 can be reduced.

In the above description, the temperature detection unit 3 is taken as an example of the air condition detection unit, but the air condition detection unit includes a humidity detection unit that detects humidity, an air pollution detection unit that detects air pollution, and an air pollution detection unit. It may be a carbon dioxide concentration detection unit that detects the carbon dioxide concentration in the air, and is not limited to a specific detection unit. That is, in the ventilation blower 101, an air condition detection unit that detects the air condition can be used. An example using the humidity detection unit will be described in the second embodiment described later.

Further, in the above description, the ventilation blower 101 is installed on the indoor 203 side of the building wall 200, but the ventilation blower 101 may be installed on the outdoor 204 side of the building wall 200. In this case, the temperature of the indoor 203 is detected when the ventilation blower 101 is operated, and the temperature of the outdoor 204 is detected when the ventilation blower 101 is stopped, so that both the temperature of the indoor 203 and the temperature of the outdoor 204 are used for controlling the ventilation blower 101. be able to. Also in this case, since the temperature detection unit 3 is arranged on the outdoor 204 side, which is the same side as the control unit 5 with respect to the building wall 200, the communication line is sandwiched between the building wall 200 and the indoor 203 side and the outdoor 204. There is no need to wire to the side. Further, a communication device for wireless communication between the temperature detection unit 3 and the control unit 5 across the wall 200 of the building is not required.

Further, in the above description, the case where the ventilation target space of the ventilation blower 101 is the second floor of the house is taken as an example, but heat may be accumulated regardless of whether the space is residential, non-resident, or the number of floors of the building. If the ventilation blower 111 having the role of 24-hour ventilation, the natural air supply port 112, and the ventilation blower 101 according to the first embodiment are installed in the building, the same effect as described above can be obtained.

Further, in the above description, the time for the control unit 5 to stop the fan 1 in order for the temperature detection unit 3 to detect the temperature of the outdoor 204, that is, the second time, which is the stop time, is set to 3 minutes. A switch may be provided in 5 so that the second time can be selected depending on the setting state of the switch. The switch is set by the user. As a result, the temperature detection unit 3 needs to detect the temperature of the outdoor 204 in the second time for stopping the fan 1 in accordance with the conditions such as the installation environment of the ventilation blower 101 and the air volume of the ventilation blower 111. It can be the time of. That is, the amount of weak air during the weak operation during the third hour period can be reduced as much as possible, and the operating noise of the ventilation blower 101 can be reduced, so that the comfort of the user is improved.

Further, in the above description, after the temperature detection of the outdoor 204 is completed, the air of the indoor 203 and the air of the outdoor 204 are around the temperature detection unit 3 for 3 minutes after the temperature detection of the indoor 203 is started. Because there is a possibility that the temperature of the room 203 cannot be accurately detected, the control unit 5 does not determine whether the temperature of the room 203 is equal to or higher than the operating threshold temperature. The period during which it is not determined whether the temperature of the indoor 203 is equal to or higher than the operating threshold temperature is automatically changed so that it is the same time as the time for stopping the fan 1 to detect the temperature of the outdoor 204. You may.

Further, during the period during which it is not determined whether or not the temperature of the room 203 is equal to or higher than the operation threshold temperature, a switch may be provided in the control unit 5 so that the switch can be selected depending on the setting state of the switch. As a result, the period during which it is not determined whether or not the temperature of the room 203 is equal to or higher than the operating threshold temperature is set to the minimum necessary period according to the conditions such as the installation environment of the ventilation blower 101 and the air volume of the ventilation blower 111. can do. The minimum required period is a situation in which the air in the indoor 203 and the air in the outdoor 204 are mixed around the temperature detection unit 3 due to the start of operation of the fan 1 after the temperature detection of the outdoor 204 is completed. This is the time required for the air around the temperature detection unit 3 to be eliminated and the air around the temperature detection unit 3 to be only the air in the room 203.

As a result, in the ventilation blower 101, the period during which the temperature of the room 203 is not determined to be equal to or higher than the operating threshold temperature can be set to a time shorter than the 3 minutes described in the above description. That is, since the ventilation blower 101 can start the control of the fan 1 by comparing the temperature of the indoor 203 with the temperature of the outdoor 204 earlier than the above description, the comfort of the user is improved.

As described above, according to the first embodiment, it is possible to acquire information on the state of indoor air and information on the state of outdoor air and use it for automatic operation with a simple structure, and automatically realize the purpose of the user. Ventilation blower can be obtained.

Embodiment 2.
In the second embodiment, the items not particularly described are the same as those in the first embodiment. Further, for the same configuration as that of the first embodiment, detailed description will be omitted by using the same reference numerals.

FIG. 6 is a cross-sectional view showing the ventilation blower 102 according to the second embodiment. In addition, in FIG. 6, a part is shown in the side view. FIG. 7 is a diagram showing a functional configuration related to control of the operation of the ventilation blower 102 according to the second embodiment. The ventilation blower 102 according to the second embodiment is a ventilation blower used for rapid ventilation, which is ventilation having a larger air volume than 24-hour ventilation. The ventilation blower 102 is installed on the indoor 203 side with respect to the building wall 200. That is, the ventilation blower 102 is fitted into the opening 201 penetrating the wall 200 of the building to communicate the indoor 203 and the outdoor 204.

The ventilation blower 101 according to the first embodiment further includes a humidity detection unit 11, an operation threshold humidity setting unit 12, a shutter 13, and a control unit 51 instead of the control unit 5. Different from. The humidity detection unit 11, the operation threshold humidity setting unit 12, the shutter 13, and the humidity storage unit 14 are housed inside the housing 20 of the ventilation blower 102. In FIG. 6, the temperature detection unit 3 and the operation threshold temperature setting unit 4 are not shown.

The humidity detection unit 11 is installed on the indoor 203 side to detect the humidity of the indoor 203, that is, the humidity of the indoor air. The humidity detection unit 11 is arranged on the surface of the housing 20 exposed in the room 203. The humidity detection unit 11 is arranged on the indoor 203 side, which is the same side as the control unit 51 with respect to the wall 200 of the building. The humidity detection unit 11 is communicably connected to the control unit 51 by a signal line (not shown), and transmits an indoor humidity signal indicating the detected humidity of the room 203 to the control unit 51. The humidity detection unit 11 is arranged on the same side as the control unit 51 with respect to the wall 200 of the building, that is, on the indoor 203 side, and is an air condition detection unit that detects the state of air passing around the ventilation blower 102 or the air passage 2. Is.

The operation threshold humidity setting unit 12 is a volume resistor for the user to adjust and set the operation threshold humidity. The operation threshold humidity is the humidity of the indoor air that is used as a reference when the control unit 51 automatically switches between the strong operation and the weak operation of the ventilation blower 102. The operating threshold humidity setting unit 12 can adjust and set the operating threshold humidity by turning a volume resistance knob (not shown). The operation threshold humidity setting unit 12 is communicably connected to the control unit 51 by a signal line (not shown), and transmits an operation threshold humidity signal indicating the operation threshold humidity set by the user to the control unit 51.

The shutter 13 is a shutter capable of opening and closing the air passage 2. Specifically, the shutter 13 is a shutter capable of opening or closing the air passage 2 by opening or closing the opening 21 on the indoor 203 side provided in the housing 20.

The humidity storage unit 14 is built inside the control unit 51, and stores the humidity detected by the humidity detection unit 11. The humidity storage unit 14 may be provided outside the control unit 51.

The control unit 51 stores the humidity detected by the humidity detection unit 11, the operation threshold humidity set in the operation threshold humidity setting unit 12, the humidity stored in the humidity storage unit 14, and the fan control data storage unit 7. The operation of the fan 1 and the shutter 13 is controlled based on the obtained data. The control unit 51 has the function of the control unit 5 described above.

The control unit 51 can acquire the humidity of the room 203 by receiving the room humidity signal transmitted from the humidity detection unit 11. The control unit 51 can acquire the operation threshold humidity by receiving the operation threshold humidity signal transmitted from the operation threshold humidity setting unit 12.

The control unit 51 uses a fan to rapidly drain the humidity in the room 203 when the humidity in the room 203 detected by the humidity detection unit 11 is equal to or higher than the operation threshold humidity set in the operation threshold humidity setting unit 12. The rapid ventilation that operates 1 with a strong air volume is automatically controlled. The control unit 51 operates the fan 1 with a weak air volume for 24 hours when the humidity of the room 203 detected by the humidity detection unit 11 is less than the operation threshold humidity set in the operation threshold humidity setting unit 12. Control is performed automatically.

The control unit 51 controls the opening / closing operation of the shutter 13 by transmitting an opening / closing signal instructing the opening / closing of the shutter 13 to the shutter 13. That is, the control unit 51 controls the opening / closing operation of the shutter 13 by transmitting an opening signal instructing the opening of the shutter 13 or a closing signal instructing the closing of the shutter 13 to the shutter 13. ..

FIG. 8 is an upper view of the building in which the ventilation system 122 according to the second embodiment is installed. The ventilation system 122 includes a ventilation blower 111 having a function of a 24-hour ventilation blower that communicates indoor 203 and outdoor 204 to perform 24-hour ventilation in a building provided with a natural air supply port 112, and an indoor 203 in the building. A ventilation blower 102, which is installed by communicating the indoor 203 and the outdoor 204 with each other, is provided on the wall 200 of the building, which is a wall partitioning the outdoor 204 from the outdoor 204. FIG. 8 shows the case where the ventilation system 122 is in operation. FIG. 8 is shown assuming the first floor of a detached house.

The ventilation blower 102 is installed for the purpose of discharging the humidity in the room 203 to the outside 204. For example, when the door between the bathroom 213 and the washroom 214 is opened and the humidity of the bathroom 213 flows into the washroom 214 and the humidity of the room 203 on the second floor becomes equal to or higher than the operating threshold humidity, the ventilation blower 102 exhausts the humidity. The control to operate the fan 1 for the purpose is automatically performed. Further, the ventilation blower 102 operates the fan 1 for the purpose of exhausting moisture, and when the humidity of the indoor 203 on the first floor becomes less than the operating threshold humidity, for example, when the humidity of the washroom 214 is exhausted to the outdoor 204, the fan 1 Is automatically controlled to stop. That is, the ventilation blower 102 is a ventilation blower used for the purpose of rapid ventilation.

On the other hand, the ventilation blower 111 has both 24-hour ventilation and rapid ventilation functions, is installed in the toilet 211 to ventilate the toilet 211, and is installed in the toilet 211 to ventilate the bathroom 213. It is installed in.

When the ventilation blower 102 is operating in the configuration shown in FIG. 8, the control unit 51 of the ventilation blower 102 controls to operate the fan 1 with the shutter 13 open. Therefore, an airflow 301 from the room to the outside is generated around the air passage 2 of the ventilation blower 102 and the humidity detection unit 11 of the ventilation blower 102. Therefore, the humidity detection unit 11 of the ventilation blower 102 detects the humidity of the room 203, that is, the humidity of the air in the room 203.

FIG. 9 is a view corresponding to FIG. 8, and is an upper view of the building when the ventilation blower 102 according to the second embodiment is stopped. The arrows in FIG. 9 indicate the direction in which air flows. When the fan 1 is operated because the humidity of the room 203 on the first floor is equal to or higher than the operation threshold humidity, the control unit 51 stops in a predetermined time during the first hour, which is a predetermined unit time. The fan 1 is stopped with the shutter 13 open only during the second hour, which is the time. The state in which the shutter 13 is opened is a state in which the air passage 2 is open. That is, the ventilation blower 102 stops the operation with the shutter 13 open only for the second hour period, which is the predetermined stop time, in the first hour period, which is the predetermined unit time. .. For example, the control unit 51 stops the fan 1 with the shutter 13 open only for 3 minutes, which is the second time, out of 60 minutes, which is the first time.

At this time, the toilet 211, the bathroom 213, and the washroom 214 have negative pressure due to the operation of the ventilation blower 111. Therefore, an air flow 302 from the outside to the inside is generated around the air passage 2 of the ventilation blower 102 and the humidity detection unit 11 of the ventilation blower 102. Therefore, the humidity detection unit 11 detects the humidity of the outdoor 204, that is, the humidity of the air of the outdoor 204. That is, the humidity detection unit 11 detects the air condition of the indoor 203 when the fan 1 is operating, and detects the air condition of the outdoor 204 during the rest period.

As described above, the control unit 51 opens the shutter 13 for a predetermined second time period when the fan 1 is operated because the humidity of the room 203 on the first floor is equal to or higher than the operation threshold humidity. In this state, the fan 1 is periodically stopped. That is, the control unit 51 of the ventilation blower 102 intermittently operates the fan 1 with the shutter 13 open for a period of the third hour excluding the first hour to the second hour. As a result, the humidity detection unit 11 can detect the humidity of the indoor 203 during the operation period of the ventilation blower 102, and can detect the humidity of the outdoor 204 during the stop period of the ventilation blower 102. That is, the ventilation blower 102 can acquire information on both the humidity of the indoor 203 and the humidity of the outdoor 204 by using only one humidity detection unit 11 installed on the indoor 203 side. The humidity of the indoor 203 and the humidity of the outdoor 204 are information on the state of air.

Further, when the humidity of the room 203 detected by the humidity detection unit 11 is less than the operation threshold humidity set in the operation threshold humidity setting unit 12, the control unit 51 is in a state where the shutter 13 is closed, that is, the wind. The fan 1 is stopped when the road 2 is closed. In this state, since the humidity detection unit 11 is installed on the indoor 203 side of the wall 200 of the building, it detects the humidity in the indoor 203. The control unit 51 of the ventilation blower 102 can also acquire the humidity of the outdoor 204 by opening the shutter 13 periodically, for example, by opening only 3 minutes out of a unit time of 60 minutes.

The second time, which is the time for stopping the fan 1 with the shutter 13 open, can be freely set as long as it is longer than the time for the air in the outdoor 204 to reach the humidity detection unit 11 after the fan 1 is stopped. can do. However, if the second time is set as short as possible, the time for interrupting the drainage of the indoor 203 on the first floor will be shorter, so that the comfort for the user will be improved.

FIG. 10 is an operation control diagram of the ventilation blower 102 according to the second embodiment. First, during the entire period from 0 minutes to 330 minutes, the control unit 51 of the ventilation blower 102 opened the shutter 13 only for a period of 3 minutes, which is the period of the second hour, out of the period of 60 minutes, which is the first hour. In this state, the control for stopping the fan 1 is repeated. During the second hour period in which the fan 1 is stopped with the shutter 13 open, the toilet 211, the bathroom 213, and the washroom 214 are in negative pressure due to the operation of the ventilation blower 111, so that the ventilation blower 102 Around the air passage 2 and the humidity detection unit 11, an air flow 302 from the outside to the inside is generated. Therefore, the humidity detection unit 11 detects the humidity of the outdoor 204.

Since the fan 1 is operating with the shutter 13 open during the remaining third hour of the first hour of 60 minutes, which is 57 minutes, the air passage 2 of the ventilation blower 102 and the ventilation blower 102 Since the airflow 301 from the room to the outside is generated around the humidity detection unit 11, the humidity detection unit 11 detects the humidity in the room 203. Alternatively, since the fan 1 is stopped with the shutter 13 closed for 57 minutes, which is the remaining third time of the 60 minutes, the humidity detection unit 11 detects the humidity in the room 203.

Immediately before the humidity detection of the indoor 203 is started, the control unit 51 of the ventilation blower 102 stores the humidity of the outdoor 204 detected at that time in the humidity storage unit 14. Then, the control unit 51 of the ventilation blower 102 sets the period from the time when the humidity of the outdoor 204 starts to be detected to the time when another 57 minutes elapses, that is, the period until the third time elapses. The current humidity of the indoor 203 detected in the above is compared with the humidity of the outdoor 204 stored in the humidity storage unit 14.

If the result of comparing the humidity of the indoor 203 at the present time with the humidity of the outdoor 204 stored in the humidity storage unit 14 is higher than the humidity of the outdoor 204, that is, "indoor humidity> outdoor". In the case of "humidity", the fan 1 is operated with the shutter 13 open to control the exhaust. As a result, the outside air, which has a humidity lower than the humidity of the room 203, which is the same amount as the air exhausted by the ventilation blower 102 and the ventilation blower 111, flows into the inside of the building from the natural air supply port 112, so that a high humidity exhaust effect is obtained. can get.

The control for operating the fan 1 with the shutter 13 open to exhaust the air is premised on the humidity of the room 203 on the first floor being equal to or higher than the operating threshold humidity. Therefore, the control for operating the fan 1 with the shutter 13 open during the period from the time when the humidity detection of the outdoor 204 is started to the time when the third time elapses is the indoor 203 on the first floor. Humidity is equal to or higher than the operating threshold humidity, and "indoor humidity> outdoor humidity".

On the other hand, if the result of comparing the humidity of the indoor 203 at the present time with the humidity of the outdoor 204 stored in the humidity storage unit 14 is lower than the humidity of the outdoor 204, that is, "indoor humidity". In the case of <outdoor humidity", the fan 1 is stopped with the shutter 13 closed. As a result, the ventilation blower 102 prevents outside air, which has the same amount of air as the air exhausted by the ventilation blower 102 and the ventilation blower 111 and is higher in humidity than the humidity of the room 203, from flowing into the inside of the building from the natural air supply port 112. , It is possible to prevent the humidity of the room 203 from rising further.

In the operation control diagram of the ventilation blower 102 shown in FIG. 10, a control other than the control of stopping the fan 1 with the shutter 13 opened in order to detect the humidity of the outdoor 204 will be described.

The humidity detection unit 11 detected the period from 0 to 80 minutes, excluding the period of 3 minutes from the start of the detection of the humidity of the outdoor 204 and the period of 3 minutes from the start of detecting the temperature of the indoor 203. The humidity in the room 203 is less than the operating threshold humidity. Therefore, the control unit 51 of the ventilation blower 102 controls to stop the fan 1 and close the shutter 13.

In the period of 160 minutes after the lapse of 80 minutes, the humidity of the indoor 203 is equal to or higher than the operating threshold humidity and “humidity of the indoor 203> humidity of the outdoor 204”. It is possible to control the operation of 1 and discharge the humidity inside the washroom 214 and the building to the outdoors 204.

In the period of 280 minutes after 160 minutes have passed, the humidity in the room 203 is equal to or higher than the operating threshold humidity, but since "indoor humidity <outdoor humidity", the control unit 51 stops the fan 1 and releases the shutter 13. Performs close control. As a result, the ventilation air volume of the entire building can be reduced, so that high humidity outside air, which is higher in humidity than the humidity of the room 203, can be prevented from flowing into the inside of the building from the natural air supply port 112, and the humidity of the room 203 can be reduced. Further rise can be suppressed.

In the period of 330 minutes after the lapse of 280 minutes, the humidity of the indoor 203 is equal to or higher than the operating threshold humidity, and “humidity of the indoor 203> humidity of the outdoor 204”, so that the control unit 51 of the ventilation blower 102 opens the shutter 13. In this state, the fan 1 is controlled to be operated. As a result, the humidity on the first floor of the building can be positively discharged to the outdoor 204.

After 330 minutes, the humidity in the room 203 is less than the operating threshold humidity. Therefore, the control unit 51 of the ventilation blower 102 controls to stop the fan 1 and close the shutter 13.

By controlling the fan 1 and the shutter 13 described above, the ventilation blower 102 can effectively exhaust the moisture on the first floor of the building, which is the purpose of the user.

As described above, the ventilation blower 102 according to the second embodiment includes a fan 1, an air passage 2, a control unit 51, a shutter 13, and a humidity detection unit 11. Then, the control unit 51 stops the fan 1 in a state where the shutter 13 is opened for a predetermined pause time period at a predetermined timing in the predetermined unit time. The humidity detection unit 11 detects the humidity of the air in the room 203 when the fan 1 is operating, and detects the temperature of the air in the outdoor 204 during the rest period. In this case, when the fan 1 is rotated, the humidity detection unit 11 detects the humidity of the indoor air, which is the air in the space on the upstream side in the direction in which the airflow generated in the air passage 2 flows. Further, the humidity detection unit 11 detects the humidity of the outdoor air, which is the air in the space on the upstream side in the direction in which the airflow generated in the air passage 2 flows, during the rest period.

The ventilation blower 102 configured in this way acquires information on both the humidity of the indoor 203 and the humidity of the outdoor 204 by using only one humidity detection unit 11 installed on the indoor 203 side. , Can be used to control the fan 1 and the shutter 13 by the control unit 51. As a result, the structure is not complicated, and information on both the humidity of the indoor 203 and the humidity of the outdoor 204 can be obtained with a simple structure, and the cost of the ventilation blower 102 can be reduced.

Further, since the control unit 51 and the humidity detection unit 11 are both installed on the indoor 203 side of the ventilation blower 102, the outdoor 204 side opposite to the indoor 203 side to the indoor 203 side across the wall 200 of the building. It is not necessary to wire the communication line of the humidity detection unit 11. That is, it is not necessary to wire the communication line between the control unit 51 and the humidity detection unit 11 between the indoor 203 side and the outdoor 204 side with the wall 200 of the building interposed therebetween. As a result, the time and cost of constructing the communication line of the humidity detection unit 11 can be suppressed.

Further, according to the configuration of the ventilation blower 102, the ventilation blower 102 installed on the indoor 203 side and the humidity detection unit 11 installed on the outdoor 204 side opposite to the indoor 203 side across the wall 200 of the building. Since the communication device for wireless communication is not required and the cost of the communication device is not required, the cost of the ventilation blower 102 can be reduced.

In the above description, the case where the ventilation blower 102 for exhaust and the ventilation blower 111 for exhaust are used as an example has been described, but the ventilation blower for air supply that supplies the air of the outdoor 204 to the indoor 203. The contents of the second embodiment can be applied even when is installed. Here, a ventilation blower 102 for air supply and a ventilation blower 111 for air supply are used. In this case, since the room 203 has a positive pressure due to the operation of the air supply ventilation blower having the function of 24-hour ventilation, the ventilation blower 102 according to the second embodiment stops the fan 1 and shutters. By opening 13, an airflow 301 from the room to the outside is generated in the air passage 2, and the humidity detection unit 11 can detect the humidity in the room 203.

On the other hand, in the ventilation blower 102 according to the second embodiment, the fan 1 is operated and the shutter 13 is opened to generate an air flow 302 from the outside to the room in the air passage 2, and the humidity detection unit 11 is the humidity of the outdoor 204. Can be detected. That is, since the ventilation blower 102 can acquire information on both the humidity of the indoor 203 and the humidity of the outdoor 204 only by one humidity detection unit 11 installed on the indoor 203 side, the above description of the first embodiment and the above description. A similar effect can be obtained.

As described above, the ventilation blower 102 according to the second embodiment uses only one humidity detection unit 11 installed on the indoor 203 side, and has both the humidity of the indoor 203 and the humidity of the outdoor 204. The information can be acquired and used for controlling the fan 1 and the shutter 13 by the control unit 51. That is, according to the second embodiment, a ventilation blower capable of automatically realizing the purpose of the user by acquiring information on the state of indoor air and information on the state of outdoor air and using it for automatic operation with a simple structure. Is obtained.

Embodiment 3.
In the third embodiment, the items not particularly described are the same as those in the first embodiment. Further, for the same configuration as that of the first embodiment, detailed description will be omitted by using the same reference numerals.

FIG. 11 is a cross-sectional view showing the ventilation blower 103 according to the third embodiment. In addition, in FIG. 11, a part is shown in the side view. FIG. 12 is a diagram showing a functional configuration related to control of the operation of the ventilation blower 103 according to the third embodiment. The ventilation blower 103 according to the third embodiment is a ventilation blower used for 24-hour ventilation and rapid ventilation. The ventilation blower 103 is installed on the indoor 203 side with respect to the building wall 200. That is, the ventilation blower 103 is fitted into the opening 201 penetrating the wall 200 of the building to communicate the indoor 203 and the outdoor 204.

The ventilation blower 103 is different from the ventilation blower 101 according to the first embodiment described above in that the timing for stopping the fan 1 can be set in order to detect the temperature of the outdoor 204. That is, the ventilation blower 103 has the same configuration and function as the ventilation blower 101. The ventilation blower 103 is different from the ventilation blower 101 in that the control unit 52 is provided instead of the control unit 5 so that the timing for stopping the fan 1 can be set in order to detect the temperature of the outdoor 204. That is, the ventilation blower 103 has the same configuration and function as the ventilation blower 101.

The control unit 52 further includes a timing setting unit 15 in addition to the temperature storage unit 6 and the fan control data storage unit 7. The control unit 52 stores the temperature detected by the temperature detection unit 3, the operation threshold temperature set in the operation threshold temperature setting unit 4, the temperature stored in the temperature storage unit 6, and the fan control data storage unit 7. The operation of the fan 1 is controlled based on the data and the address where the timing setting information is set in the timing setting unit 15.

The timing setting unit 15 is built inside the control unit 52, and the timing for stopping the fan 1 is set in order to detect the temperature of the outdoor 204. By setting the timing setting information to different addresses of the timing setting unit 15, the control unit 52 has a fan to detect the temperature of the outdoor 204 based on the address where the timing setting information is set in the timing setting unit 15. Control is performed by determining the timing at which 1 is stopped. The timing setting information is information set to specify the timing for stopping the fan 1 in order to detect the temperature of the outdoor 204.

FIG. 13 is an upper view of the building in which the ventilation system 123 according to the third embodiment is installed. The ventilation system 123 includes a ventilation blower 111 having a function of a 24-hour ventilation blower that is installed by communicating the indoor 203 and the outdoor 204 in a building provided with a natural air supply port 112 and performs 24-hour ventilation, and an indoor 203 in the building. A plurality of ventilation blowers 103 installed by communicating the indoor 203 and the outdoor 204 with the wall 200 of the building, which is a wall partitioning the outdoor 204, are provided. FIG. 13 shows a case where the ventilation blower 103 according to the third embodiment is operating. FIG. 13 is shown assuming the second floor of a detached house as in FIG. In the configuration shown in FIG. 13, the ventilation blower 101 arranged on the wall 200 of the building facing the balcony 216 in FIG. 3 is changed to the first ventilation blower 103a which is the ventilation blower 103, and in FIG. 3, next to the stairs 215 in FIG. It is different from FIG. 3 that the natural air supply port 112 installed on the wall 200 of the building is changed to the second ventilation blower 103b which is the ventilation blower 103.

The first ventilation blower 103a is a ventilation blower 103 in which timing setting information is set at the address 1 of the timing setting unit 15. The second ventilation blower 103b is a ventilation blower 103 in which timing setting information is set at the address 2 of the timing setting unit 15. Since the first ventilation blower 103a and the second ventilation blower 103b have timing setting information set at different addresses in the timing setting unit 15, the timing of stopping the fan 1 to detect the temperature of the outdoor 204 is different. In FIG. 13, only the first ventilation blower 103a in which the timing setting information is set at the address 1 of the timing setting unit 15 is stopped, and the second ventilation in which the timing setting information is set at the address 2 of the timing setting unit 15 is stopped. The blower 103b is in operation.

FIG. 14 is an upper view of the building having a configuration for comparison with respect to FIG. 13, and is an upper view of the building when the ventilation blower 101 according to the first embodiment is stopped. FIG. 14 is different from FIG. 4 in that the natural air supply port 112 installed on the wall 200 of the building next to the stairs 215 in FIG. 4 is changed to the ventilation blower 101 according to the first embodiment. That is, in FIG. 14, the ventilation blowers 101 according to the first embodiment are arranged at two locations, the wall 200 of the building facing the balcony 216 and the wall 200 of the building next to the stairs 215, for a total of two units. Ventilation blower 101 is installed on the second floor of the house. In FIG. 14, since the two ventilation blowers 101 are not set to the address for setting the timing to stop the fan 1 in order to detect the temperature of the outdoor 204, the two ventilation blowers 101 have the same timing. It shows the case where the fan 1 of 101 is stopped.

In FIG. 14, of the ventilation blower 111 installed on the second floor of the house and the two ventilation blowers 101, the only ventilation blower in operation is the ventilation blower 111. Therefore, the same amount of outdoor 204 air as the air exhausted by the ventilation blower 111 is dispersed inside the building from a total of three locations, the air passage 2 of the two ventilation blowers 101 and the natural air supply port 112. Inflow. Therefore, assuming that the air pressure loss in the air inflow paths of the three outdoor 204s is the same, the air volume flowing through the air passage 2 of the ventilation blower 101 is 0.33 times the exhaust air volume of the ventilation blower 111, that is, the ventilation blower 111. It is one-third of the exhaust air volume of the above, which is the same as in the case of FIG.

Therefore, in the configuration shown in FIG. 14, when the fan 1 is stopped only during the second hour of the first hour period, the time for stopping the fan 1 of the ventilation blower 101 in order to detect the temperature of the outdoor 204 is set. , The same time as in the case of the first embodiment is required. That is, in the configuration shown in FIG. 14, the time for stopping the fan 1 of the ventilation blower 101 in order to detect the temperature of the outdoor 204 is required for only 3 minutes in the same case as the example in the case of FIG.

On the other hand, in the configuration shown in FIG. 13, the ventilation blower 111 installed on the second floor of the house and the first ventilation blower 103a and the second ventilation blower 103b, which are two ventilation blowers 103, are in operation. There are two ventilation blowers, a ventilation blower 111 and a second ventilation blower 103b in which timing setting information is set at the address 2 of the timing setting unit 15. Therefore, the timing setting information is set at the address 1 of the timing setting unit 15 for the amount of outdoor 204 air equivalent to the total of the exhaust air volumes of the two ventilation blowers of the ventilation blower 111 and the second ventilation blower 103b. It is dispersed from a total of two locations, the air passage 2 of the first ventilation blower 103a and the natural air supply port 112, and flows into the inside of the building.

Here, it is assumed that the air pressure loss in the air inflow paths of the two outdoor 204s is the same, and the exhaust air volume of the ventilation blower 111 and the ventilation blower 103 is the same. Since there are two ventilation blowers exhausting, the ventilation blower 111 and the second ventilation blower 103b, the exhaust air volume is twice that in the case of FIG. Further, since there are two air inflow points in the outdoor 204, the air inflow points in the outdoor 204 are two-thirds times as large as in the case of FIG. 14 = (2 places / 3 places). Therefore, in the configuration shown in FIG. 13, the air volume of the first ventilation blower 103a set at the address 1 is 2 times ÷ (2/3) times = 3 times the air volume in the case of FIG. It flows on the road 2.

As a result, after the control unit 52 of the first ventilation blower 103a stops the fan 1, the time for the air in the outdoor 204 to reach the temperature detection unit 3 is three times faster, so that the temperature of the outdoor 204 can be detected. The time for stopping the fan 1 can be shortened to one-third of the time. That is, in the first embodiment, the fan 1 was stopped for 3 minutes out of 60 minutes, but in the third embodiment, each ventilation blower 103 stopped the fan 1 for 1 minute = (3 minutes ÷ 3 times). Then, the temperature of the outdoor 204 can be detected.

That is, the control unit 52 changes the pause time based on the total exhaust air volume of the ventilation blower 111, which is a 24-hour continuous ventilation blower, and the exhaust air volume of the other ventilation blowers 103 in the ventilation system 123. Can be done. Here, the number of ventilation blowers 103 in the ventilation system 123 may be three or more. Then, among the plurality of ventilation blowers 103 in the ventilation system 123, the timing of stopping the fan 1 to detect the temperature of the outside air is different from the timing of the other ventilation blowers 103 of the plurality of ventilation blowers 103. The blower 103 is a ventilation blower with a different timing. The control unit 52 of the different timing ventilation blower can perform control to shorten the pause time as the total exhaust air volume with the exhaust air volume of the other ventilation blower 103 increases.

FIG. 15 is an operation control diagram of the ventilation blower 103 according to the third embodiment. The first ventilation blower 103a in which the timing setting information is set at the address 1 of the timing setting unit 15 and the second ventilation blower 103b in which the timing setting information is set at the address 2 of the timing setting unit 15 are divided into 0 minutes. At the same time, the commercial power supply is turned on and the operation is started.

The control unit 52 of the ventilation blower 103 stops the fan 1 for a period of 1 minute out of 60 minutes, for example. However, when the timing setting information is set at the address 1, the control unit 52 stops the fan 1 in the period from 59 minutes to 60 minutes from the start of energization of the commercial power supply. That is, the first ventilation blower 103a in which the timing setting information is set at the address 1 stops the fan 1 in the period from 59 minutes to 60 minutes from the start of energization of the commercial power source.

Further, when the timing setting information is set at the address 2, the control unit 52 stops the fan 1 in a period of 29 to 30 minutes from the start of energization of the commercial power source. That is, the second ventilation blower 103b in which the timing setting information is set at the address 2 stops the fan 1 in the period from the start of energization of the commercial power source to 29 minutes to 30 minutes.

As described above, in the third embodiment, the timing setting information is set at different addresses of the timing setting unit 15 for the first ventilation blower 103a and the second ventilation blower 103b, which are the two ventilation blowers 103, so that the outdoors The timing of stopping the fan 1 is different in order to detect the temperature of 204.

Therefore, in the third embodiment, the fan 1 is stopped for a period of 2 minutes = (1 minute x 2 units) out of 60 minutes in total of the two ventilation blowers 103, which is compared with the first embodiment. The time for stopping the fan 1 of the ventilation blower 103 can be shortened by 1 minute = (3 minutes-2 minutes).

As described above, in the first embodiment, in order to stop the fan 1 in the period of 3 minutes out of 60 minutes, the weak operation of the fan 1 in the remaining period of 57 minutes out of 60 minutes is determined by the Building Standards Act. In order to satisfy the minimum required ventilation air volume, the output of the weakly operated fan 1 is increased 1.053 times = (60 minutes ÷ 57 minutes) compared to the case where the fan 1 is continuously operated for 60 minutes. I had to keep it.

On the other hand, in the third embodiment, since the fan 1 is stopped in the period of 2 minutes out of 60 minutes, it is necessary that the fan 1 is operated weakly in the remaining 58 minutes of 60 minutes by the Building Standards Act. It suffices to satisfy the minimum ventilation air volume. That is, it is only necessary to increase the output of the weakly operated fan 1 for a period of 58 minutes to 1.034 times = (60 minutes ÷ 58 minutes) as compared with the case where the fan 1 is continuously operated for 60 minutes. Therefore, in the third embodiment, the output of the fan 1 in the weak operation carried out in the period of the third hour can be further reduced as compared with the first embodiment, and the operating noise of the ventilation blower 103, which increases in direct proportion to the air volume, can be reduced. Therefore, the comfort of the user is improved.

As described above, the ventilation blower 103 according to the third embodiment includes the timing setting unit 15, and the control unit 52 determines the temperature of the outdoor 204 based on the address where the timing setting information is set in the timing setting unit 15. The timing for stopping the fan 1 is determined and controlled in order to detect the above. Then, in the ventilation system 123 including the ventilation blower 111 and the plurality of ventilation blowers 103 installed in the building, the plurality of ventilation blowers 103 are set with timing setting information at different addresses in the respective timing setting units 15. NS. Therefore, the plurality of ventilation blowers 103 have different timings for stopping the fan 1 in order to detect the temperature of the outdoor 204.

In the ventilation system 123 configured as described above, the output of the fan 1 in the weak operation performed by the ventilation blower 103 during the period of the third hour is weakened by the ventilation blower 101 in the first embodiment during the period of the third hour. Since the output can be made smaller than the output of the operating fan 1 and the operating noise of the ventilation blower 103, which increases in direct proportion to the air volume, can be reduced, the comfort of the user is improved.

Further, in FIG. 13, two ventilation blowers 103 are installed, but three or more ventilation blowers 103 may be installed. Even in this case, it is better to stop the fan 1 in order to detect the temperature of the outdoor 204 at different timings than when all the ventilation blowers stop the fans 1 at the same timing as in the case of FIG. However, since the time for stopping the fan 1 can be shortened, the same effect can be obtained.

For example, it is assumed that one more ventilation blower 103 is installed with respect to the configuration of FIG. 13, and a total of three ventilation blowers 103 and a ventilation blower 111 are installed on the second floor of the house. When the three ventilation blowers 103 stop the fan 1 in order to detect the temperature of the outdoor 204 at different timings, the ventilation blowers that exhaust the air, including the two ventilation blowers 103 and the ventilation blower 111, are used. There are three. Therefore, the amount of air in the outdoor 204, which is equivalent to the total exhaust air volume of the three ventilation blowers of the ventilation blower 111 and the two ventilation blowers 103, is naturally supplied to the air passage 2 of the ventilation blower 103 that stops the fan 1. It disperses from a total of two locations, including the air vent 112, and flows into the interior of the building.

Here, it is assumed that the air pressure loss in the air inflow paths of the two outdoor 204s is the same, and the exhaust air volume of the ventilation blower 111 and the ventilation blower 103 is the same. Since there are three ventilation blowers exhausting, the ventilation blower 111 and the two ventilation blowers 103, the exhaust air volume is three times that in the case of FIG. Further, since there are two air inflow points in the outdoor 204, the air inflow points in the outdoor 204 are two-thirds times as large as in FIG. 14 = (2 places / 3 places). Therefore, in the configuration in which a total of three ventilation blowers 103 are installed, the air volume of 3 times ÷ (2/3) times = 4.5 times that of the configuration in the case of FIG. 14 increases the temperature of the outdoor 204. It flows into the air passage of the ventilation blower 103 in which the fan 1 is stopped for detection.

As a result, after the control unit 52 of one ventilation blower 103 stops the fan 1 to detect the temperature of the outdoor 204, the time for the air of the outdoor 204 to reach the temperature detection unit 3 is 4.5 times faster. Therefore, the time for stopping the fan 1 to detect the temperature of the outdoor 204 can be shortened to 1/4.5. That is, in the first embodiment, the fan 1 was stopped for 3 minutes out of 60 minutes, but in the configuration in which a total of 3 ventilation blowers 103 are installed, each ventilation blower 103 has 0.66 minutes = (3). If the fan 1 is stopped by (minutes ÷ 4.5 times), the temperature of the outdoor 204 can be detected.

That is, the more ventilation blowers 103 that stop the fan 1 to detect the temperature of the outdoor 204 at different timings, the shorter the time for each ventilation blower 103 to stop the fan 1 to detect the temperature of the outdoor 204. Therefore, the weak air volume can be reduced, the operating noise of the ventilation blower, which increases in direct proportion to the air volume, can be reduced, and the comfort of the user is improved.

When a plurality of ventilation blowers 103 are installed, information on how many ventilation blowers 103 are installed to stop the fan 1 in order to detect the temperature of the outdoor 204 at different timings is provided in each ventilation blower 103. The method of grasping by the control unit 52 may be such that the information of the address where the timing setting information is set in each ventilation blower 103 can be shared among the ventilation blowers 103. For example, it is possible to communicate between the ventilation blowers 103 by wire communication or wireless communication, and to exchange information of the address set in each ventilation blower 103 between the ventilation blowers 103 by communication. .. The method of sharing the information of the address in which the timing setting information is set in each ventilation blower 103 is not limited to a specific method.

For example, when each ventilation blower 103 grasps information on how many ventilation blowers 103 are installed to stop the fan 1 in order to detect the temperature of the outdoor 204 at different timings by the set address, If there are three ventilation blowers 103 installed, for example, the address 31, the address 32, and the address 33 in the timing setting unit 15 may be used. Further, if there are four ventilation blowers 103 installed, the address 41, the address 42, the address 43, and the address 44 in the timing setting unit 15 may be used.

Further, in FIG. 15, the cycle in which the two ventilation blowers 103 stop the fan 1 in order to detect the temperature of the outdoor 204 is set to a 60-minute cycle for both the two ventilation blowers 103, but the timing setting information is different. By setting to, the cycle for stopping the fan 1 may be different for each ventilation blower 103. For example, the cycle of stopping the fan 1 in the ventilation blower 103 whose timing setting information is set to the address 1 is a 60-minute cycle, and the cycle of stopping the fan 1 in the ventilation blower 103 whose timing setting information is set to the address 2 is set. It is assumed that the cycle is 55 minutes. Then, the two ventilation blowers 103 are simultaneously energized with the commercial power source at the timing of 0 minutes. In this case, the ventilation blower 103 whose timing setting information is set to the address 1 stops the fan 1 in a period of 59 minutes to 60 minutes. Further, the ventilation blower 103 whose timing setting information is set to the address 2 stops the fan 1 in a period of 54 minutes to 55 minutes. As a result, the two ventilation blowers 103 can stop the fan 1 at different timings, so that the same effect as described above can be obtained.

As described above, in the ventilation blower 103 according to the third embodiment, the control unit 52 detects the temperature of the outdoor 204 based on the address where the timing setting information is set in the timing setting unit 15, and the fan 1 The timing to stop is determined and control is performed. As a result, in the ventilation system 123, the output of the weakly operated fan 1 carried out by the ventilation blower 103 during the third hour period is output from the weakly operated fan 1 carried out by the ventilation blower 101 according to the first embodiment during the third hour period. Since the operating noise of the ventilation blower 103, which can be made smaller than the output of 1 and increases in direct proportion to the air volume, can be reduced, the comfort of the user is improved.

Embodiment 4.
In the fourth embodiment, the items not particularly described are the same as those in the third embodiment. Further, for the same configuration as that of the third embodiment, detailed description thereof will be omitted by using the same reference numerals.

FIG. 16 is an upper view of the building in which the ventilation system 124 according to the fourth embodiment is installed. In the ventilation system 124, the first ventilation blower 103a is changed to the third ventilation blower 103c, and the second ventilation blower 103b is changed to the fourth ventilation blower 103d. Different from system 123. In the third ventilation blower 103c, timing setting information is set at the address 3 of the timing setting unit 15. In the fourth ventilation blower 103d, timing setting information is set at the address 4 of the timing setting unit 15. When the ventilation system 124 according to the fourth embodiment is used for 24-hour ventilation due to the difference in the setting of the address, the control method of the fan 1 by the control unit 52 is the ventilation system 123 of the third embodiment. Different from the case.

FIG. 17 is an operation control diagram of the ventilation blower 103 according to the fourth embodiment. In the operation control diagram shown in FIG. 17, the temperature of the room 203 detected by the temperature detection unit 3 of the ventilation blower 103 is lower than the operation threshold temperature set by the operation threshold temperature setting unit 4, or the temperature of the ventilation blower 103 is detected. When the temperature of the room 203 detected in the unit 3 is equal to or higher than the operating threshold temperature, but "the temperature of the room 203 <the temperature of the outdoor 204", the control unit 52 controls the fan 1 as 24-hour ventilation. Shown.

The control unit 52 of the third ventilation blower 103c in which the timing setting information is set at the address 3 of the timing setting unit 15 is the fan 1 during the period from 0 minutes to 29 minutes after the commercial power supply is started to be energized in 0 minutes. Is weakly operated, fan 1 is strongly operated from 29 minutes to 30 minutes, fan 1 is weakly operated from 30 minutes to 59 minutes, and 59 minutes to 60 minutes. During the period of, the fan 1 is stopped, and this control is repeated in a cycle of 60 minutes.

Further, during the period from 29 minutes to 30 minutes, the control unit 52 of the fourth ventilation blower 103d in which the timing setting information is set at the address 4 of the timing setting unit 15 is required to detect the temperature of the outside air. This is the period during which the fan 1 is stopped. By strongly operating the third ventilation blower 103c during the period from 29 minutes to 30 minutes, which is the third time, the exhaust air volume can be increased as compared with the weak operation. Therefore, the wind of the fourth ventilation blower 103d From road 2, more outdoor 204 air flows into the building.

On the other hand, the control unit 52 of the fourth ventilation blower 103d uses the fan 1 for a period from 0 minutes to 59 minutes after the energization of the commercial power source is started in 0 minutes, and then the control unit 52 of the second ventilation blower 103b of the third embodiment. The control is the same as that of 52, but the fan 1 is strongly operated during the period from 59 minutes to 60 minutes. The period from 59 minutes to 60 is the period in which the third ventilation blower 103c stops the fan 1 in order to detect the temperature of the outside air. Since the control unit 52 of the fourth ventilation blower 103d is strongly operated during the period from 59 minutes to 60, which is the third time, the exhaust air volume can be increased as compared with the weak operation. Therefore, the third ventilation blower From the air passage 2 of 103c, more air of 204 outdoors flows into the inside of the building.

As described above, in the fourth embodiment, with respect to the third ventilation blower 103c and the fourth ventilation blower 103d, which are two ventilation blowers 103, one of the ventilation blowers 103 uses the fan 1 to detect the temperature of the outdoor 204. When the other ventilation blower 103 strongly operates the fan 1 when the ventilation blower 103 is stopped, the time for the air of the outdoor 204 to reach the temperature detection unit 3 of the stopped ventilation blower 103 can be shortened.

The number of ventilation blowers 103 in the ventilation system 124 may be three or more. Here, among the plurality of ventilation blowers 103 in the ventilation system 124, the timing at which the fan 1 is stopped in order to detect the temperature of the outside air is different from the timing in the other ventilation blowers 103 among the plurality of ventilation blowers 103. The ventilation blower 103 is used as a ventilation blower with a different timing.

In the ventilation system 124, when the fan 1 of the timing-difference ventilation blower is stopped during the pause period, the control unit 52 of at least one of the plurality of other ventilation blowers 103 is the fan 1. The exhaust air volume is increased by controlling to increase the number of revolutions of.

Further, when the fan 1 of at least one of the other ventilation blowers 103 in the ventilation system 124 is stopped during the pause period, the control unit 52 of the timing difference ventilation blower sets the fan. The exhaust air volume is increased by controlling to increase the number of revolutions of 1.

For example, in FIGS. 16 and 17, it is assumed that the strong air volume is twice the weak air volume. Compared to the case where both the fourth ventilation blower 103d and the ventilation blower 111 are operating at a weak air volume, when the fourth ventilation blower 103d is operating at a strong air volume and the ventilation blower 111 is operating at a weak air volume, The displacement of the entire building will be 1.5 times. Therefore, in the air passage 2 of the fourth ventilation blower 103d in which the fan 1 is stopped in order to detect the temperature of the outside air, both the fourth ventilation blower 103d and the ventilation blower 111 are operating with a weak air volume. Since the air of the outdoor 204 flows 1.5 times as much as the case, the time for the fourth ventilation blower 103d to stop for detecting the temperature of the outdoor 204 should be shortened by 1.5 times as compared with the third embodiment. Can be done.

That is, in the third embodiment, the fan 1 is stopped for a period of 2 minutes = (1 minute x 2 units) out of 60 minutes in total of the two ventilation blowers 103, but in the fourth embodiment, the fan 1 is stopped. The fan 1 may be stopped for a total period of 1.33 minutes = (2 minutes ÷ 1.5 times) of the two ventilation blowers 103. As a result, by stopping the fan 1 of any one of the two ventilation blowers 103, the time during which the ventilation of the building becomes uneven can be reduced, so that the comfort of the user is improved.

Further, when two ventilation blowers 103 are used for 24-hour ventilation, even if one ventilation blower 103 stops, the other ventilation blower 103 exhausts twice, so that the two ventilation blowers Both 103 can obtain the same exhaust air volume as when operating at a weak air volume.

Therefore, the weak air volume of the weak operation carried out during the third hour period of the ventilation blower 103 in the fourth embodiment can be the same as that in the case of continuous operation for 60 minutes, and therefore, the third is more than the third embodiment. The amount of weak air in the weak operation performed during the period of time can be set to be small, and the operating noise of the ventilation blower, which increases in direct proportion to the air volume, can be reduced, so that the comfort of the user is improved.

As described above, in the ventilation system 124 according to the fourth embodiment, the control unit 52 has a pause time for the fan 1 of at least one of the plurality of ventilation blowers 103 to detect the temperature of the outside air. When stopped during the period, another ventilation blower 103 controls to increase the rotation speed of the fan 1. As a result, the ventilation blower 103 in the ventilation system 124 can set the weak air volume of the weak operation in the third hour lower than the ventilation blower 103 in the ventilation system 123 according to the third embodiment, and the ventilation increases in direct proportion to the air volume. Since the operating noise of the blower 103 can be reduced, the comfort of the user can be improved.

The above-described first to fourth embodiments can be appropriately combined as long as the effects of the respective embodiments are not impaired. Further, in the above-described first to fourth embodiments, the outside air temperature is higher than the indoor temperature in summer or the like, or the outside air humidity is higher than the indoor humidity in the rainy season or the like. It is suitable for such cases.

The control unit 5, the control unit 51, and the control unit 52 of the above-described first to fourth embodiments are realized as a processing circuit having a hardware configuration shown in FIG. FIG. 18 is a diagram showing an example of the hardware configuration of the processing circuit according to the first to fourth embodiments. When each of the above control units is realized by the processing circuit shown in FIG. 18, each of the above control units is realized by executing a program stored in the memory 502 by the processor 501. Further, a plurality of processors and a plurality of memories may cooperate to realize the functions of the above-mentioned control units. Further, a part of the functions of the above control units may be implemented as an electronic circuit, and the other part may be realized by using the processor 501 and the memory 502.

The configuration shown in the above embodiments is an example, and can be combined with another known technique, can be combined with each other, and does not deviate from the gist. It is also possible to omit or change a part of the configuration.

1 fan, 1a electric motor, 1b impeller, 2 air passage, 3 temperature detection unit, 4 operation threshold temperature setting unit, 5,51,52 control unit, 6 temperature storage unit, 7 fan control data storage unit, 11 humidity detection unit , 12 Operating threshold humidity setting unit, 13 shutter, 14 humidity storage unit, 15 timing setting unit, 20 housings, 21 and 22 openings, 101, 102, 103, 111 ventilation blower, 103a first ventilation blower, 103b second Ventilation Blower, 103c 3rd Ventilation Blower, 103d 4th Ventilation Blower, 112 Natural Air Supply Port, 121, 122, 123, 124 Ventilation System, 200 Walls, 201 Openings, 203 Indoors, 204 Outdoors, 211 Toilet, 212 Corridors, 213 Bathroom, 214 washroom, 215 stairs, 216 veranda, 301 indoor to outdoor airflow, 302 outdoor to indoor airflow, 501 processor, 502 memory.

Claims (11)

A ventilation blower that communicates the indoor and outdoor areas on a wall that separates the indoor and outdoor areas in a building that is equipped with a natural air supply port and is equipped with a 24-hour continuous ventilation blower that provides 24-hour continuous ventilation. ,
With fans
An air passage through which the air blown by the fan passes while communicating the indoor and outdoor areas with each other.
A control unit that adjusts the rotation speed of the fan,
An air condition detection unit, which is arranged on the same side as the control unit with respect to the wall and detects the air condition,
With
The control unit stops the fan for a predetermined pause time period at a predetermined timing among the predetermined unit times.
The air condition detection unit detects the air condition in the room when the fan is operating, and detects the outdoor air condition during the rest period.
Ventilation blower featuring. A shutter for opening or closing the air passage is provided.
The control unit stops the fan with the shutter open during the pause period.
The ventilation blower according to claim 1. The timing can be changed,
The ventilation blower according to claim 1 or 2. The pause time can be changed,
The ventilation blower according to any one of claims 1 to 3, wherein the ventilation blower is characterized. A 24-hour continuous ventilation blower that communicates indoors and outdoors in a building equipped with a natural air supply port to provide 24-hour continuous ventilation, and a wall that separates the indoor and outdoor parts of the building from the indoor and outdoor areas. It is a ventilation blower system equipped with a plurality of ventilation blowers installed in communication with each other.
The ventilation blower is
With fans
An air passage through which the air blown by the fan passes while communicating the indoor and outdoor areas with each other.
A control unit that adjusts the rotation speed of the fan,
An air condition detection unit, which is arranged on the same side as the control unit with respect to the wall and detects the air condition,
With
The control unit stops the fan for a predetermined pause time period at a predetermined timing among the predetermined unit times.
The air condition detection unit detects the air condition in the room when the fan is operating, and detects the outdoor air condition during the rest period.
Ventilation blower system featuring. The ventilation blower comprises a shutter for opening or closing the air passage.
The control unit stops the fan with the shutter open during the pause period.
The ventilation blower system according to claim 5. The timing can be changed,
At least one of the plurality of the ventilation blowers is a ventilation blower whose timing is different from that of the other ventilation blowers of the plurality of ventilation blowers.
The ventilation blower system according to claim 5 or 6. The control unit of the timing difference ventilation blower changes the pause time based on the total exhaust air volume of the exhaust air volume of the 24-hour continuous ventilation blower and the exhaust air volume of the other ventilation blower.
7. The ventilation blower system according to claim 7. The control unit of the timing difference ventilation blower controls to shorten the pause time as the total exhaust air volume increases.
The ventilation blower system according to claim 8. When the fan of the timing difference ventilation blower is stopped during the pause period, the control unit of at least one of the plurality of other ventilation blowers is the rotation speed of the fan. To control to increase
The ventilation blower system according to any one of claims 7 to 9. When the fan of at least one other ventilation blower among the plurality of other ventilation blowers is stopped during the period of the pause time, the control unit of the timing difference ventilation blower performs the rotation speed of the fan. To control to increase
The ventilation blower system according to any one of claims 7 to 10.

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