JP2004177085A - Ventilating structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ventilating structure for a building having a plurality of living spaces, reducing thermal energy loss during cooling or heating operation. <P>SOLUTION: The ventilating structure for ventilating the living spaces R21-R24 of the building B2 comprises a feed route (a main feed duct 21 and a branch feed duct 23) for supplying outside air from the side face of the building B2 into the living spaces R21-R24, an exhaust route (an exhaust chamber 22 and a branch feed duct 24) for exhausting air from the living spaces R21-R24 to the side face of the building B2, and a heat exchanger T2 provided in an area where the feed route and the exhaust route are each connected to the living spaces R21-R24. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a ventilation structure for a building having a plurality of living room spaces.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, for example, an invention described in Patent Document 1 has been devised as a ventilation structure in a building having a living room space such as an apartment house.
As shown in FIG. 5, in the ventilation structure 5 of the invention, the main air supply duct 51 and the main air exhaust duct 52 are provided so as to penetrate the building B5 in the horizontal direction, and the air supply of the main air supply duct 51 is performed. The ports 51a and 52b and the exhaust ports 52a and 52b of the main exhaust duct 52 are provided so as to open on two opposing outer walls of the building B5.
Further, a branch supply duct 53 branched from the main supply duct 51 and a branch exhaust duct 54 branched from the main exhaust duct 52 are provided so as to communicate with the living room spaces R51 to R54.
[0003]
Then, outside air flows into the main air supply duct 51 from the air supply port 51 a or 51 b according to the direction of the wind, and the outside air is supplied into the living room space 111 through the branch air supply duct 53. When there is no wind, the sensor 56 detects this and activates the fan 58 to allow the outside air to flow from the duct 57 into the main air supply duct 51.
Next, the air in the living room spaces R51 to R54 is pushed out by the branch exhaust duct 54, flows into the main exhaust duct 52, and is discharged outside through the exhaust port 52b or 52a.
In this manner, the ventilation in the living room spaces R51 to R54 is performed using the natural wind.
[0004]
However, in the ventilation structure 5, since the side for introducing outside air and the side for discharging indoor air are opposite to each other, when cooling or heating each of the room spaces R51 to R54 shown in FIG. It has been difficult to exchange heat between the outside air to be discharged and the room air to be discharged.
[0005]
As shown in FIG. 6, in the normal ventilation structure 6 that does not use natural wind, outside air is supplied to each of the room spaces R61 to R64 through the main air supply duct 61 and the branch air supply duct 63, and R61 to R61. The air in the room of R64 is discharged outside through the branch exhaust duct 64 and the main exhaust duct 62.
Here, when cooling or heating each of the living room spaces R61 to R64 shown in FIG. 3, heat exchange between the outside air to be introduced and the room air to be discharged is performed by the air supply port 61a of the main air supply duct 61 and the main exhaust duct. It is customary to provide a heat exchanger T6 near the exhaust port 62a of 62 and perform the heat exchange of the air in each of the living room spaces R61 to R64 collectively.
[0006]
[Patent Document 1]
Japanese Patent No. 2897873 (FIG. 1)
[0007]
[Problems to be solved by the invention]
However, in the above ventilation structure 5, since heat exchange is not performed between the air exhausted from the living room spaces R51 to R54 and the outside air introduced into the living room spaces R51 to R54, cooling is performed in each of the living room spaces R51 to R54. When heating or heating, heat energy consumption is wasted.
In the ventilation structure 6, when cooling or heating is performed in a part of each of the room spaces R61 to R64, heat exchange of the air in each of the room spaces R61 to R64 is performed collectively. There was waste in consumption. For example, even if air that has been cooled or heated is mixed with air that has not been heated, and then heat is exchanged with the outside air, the outside air is not so cooled or heated.
[0008]
It is an object of the present invention to provide a ventilation structure having a small amount of heat energy loss during cooling or heating in a building having a plurality of living room spaces.
[0009]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the invention according to claim 1 is for performing ventilation in the living room spaces R11 to R14 and R21 to R24 of the buildings B1 and B2, for example, as shown in FIGS. Ventilation structure,
An air supply route (main air supply ducts 11 and 21 and branch air supply ducts 13 and 23) for supplying outside air from the side surfaces of the buildings B1 and B2 into the living room spaces R11 to R14 and R21 to R24;
An exhaust route (main exhaust duct 12, exhaust chamber 22, branch air supply ducts 14, 24) for exhausting air from inside each of the living room spaces R11 to R14, R21 to R24 to the side surfaces of the buildings B1, B2;
The heat exchangers T1 and T2 are provided at portions where the air supply route and the exhaust route are connected to the respective living room spaces R11 to R14 and R21 to R24.
Here, the living room space may be composed of one room, or may be composed of two or more rooms that can ventilate each other.
The living room space is not limited to a room that is continuously used by a resident, but refers to any room in a building.
[0010]
According to the first aspect of the present invention, since a heat exchanger is provided at a portion where the air supply route and the exhaust route are connected to each room space, the outside air supplied to each room space is provided. The heat exchange between the room air discharged from the room and the room air can be individually performed for each room.
Therefore, in a building having a plurality of living room spaces, even if cooling or heating is performed only in a part of the living room spaces, a ventilation structure with a small heat energy loss amount is obtained.
[0011]
The invention according to claim 2 is, for example, as shown in FIG. 2, in the ventilation structure 2 according to claim 1,
The main air supply route is arranged so as to penetrate from the air supply port 21a provided on one side S1 facing the building B2 to the air supply port 21b provided on the other side S2. An air duct 21; and a branch air supply duct 23 that communicates the main air supply duct 21 with each of the living room spaces R21 to R24.
The exhaust route includes an exhaust duct 24 connected to each of the living room spaces R21 to R24 and connected to the branch supply duct 23 by a heat exchanger T2, and the one side S1 and the other side S2 of the building B2. And exhaust chambers 22 communicating the exhaust duct 24 and the exhaust ports 22a and 22b.
The air supply ports 21a and 21b are provided with a backflow prevention damper (backflow prevention / air volume adjustment damper) 25 for preventing the air in the main air supply duct 21 from flowing outside.
The exhaust ports 22a and 22b are provided with a backflow prevention damper 26 for preventing air from flowing back into the exhaust chamber 22 from outside.
[0012]
According to the invention described in claim 2, the air supply port on the leeward side and the exhaust port on the leeward side are closed according to the wind direction around the building, and the main air supply duct and the branch air supply are provided from the air supply port on the leeward side. Outside air flows into the room through the duct. At this time, the outside air taken into the living room space exchanges heat with air discharged from the living room space to the branch exhaust duct.
Then, the air in the living room space exhausted from the branch exhaust duct is exhausted from the exhaust port on the leeward side through the exhaust chamber.
In this way, in a building having a plurality of living room spaces, even when cooling or heating is performed only in a part of the living room spaces, a ventilation structure with a small heat energy loss amount can be realized using natural wind.
[0013]
According to a third aspect of the present invention, as shown in FIG. 2, for example, in the ventilation structure 2 according to the second aspect,
The air supply port 21a is provided with an air volume adjustment damper (backflow prevention / air volume adjustment damper) 25 for stabilizing the air volume of the airflow flowing into the main air supply duct 21 from outside.
[0014]
According to the third aspect of the present invention, since the air supply opening is provided with the air volume adjustment damper for stabilizing the air volume of the airflow flowing from outside into the main air supply duct, the natural air volume changes. In addition, it is possible to stably ventilate the living room space.
[0015]
According to a fourth aspect of the present invention, as shown in, for example, FIGS. 1 and 2, in the ventilation structure 2 according to the second or third aspect, an airflow provided in the main air supply duct 21 and passing therethrough A sensor 27 for detecting the air volume of
An exhaust fan 28 is provided for exhausting air from the exhaust chamber 22 to the side of the building when the airflow detected by the sensor 27 is smaller than a predetermined value.
[0016]
According to the fourth aspect of the present invention, when the sensor detects that the airflow of the airflow passing through the main air supply duct is smaller than a predetermined value, that is, the natural air having sufficient strength to ventilate the living room space. When the wind is not blowing, the exhaust fan operates and the air in the living room space is exhausted to the outside of the building through the branch exhaust duct and exhaust chamber, and the building air is exhausted through the main air supply duct and the branch air supply duct. Outside air is drawn into the living room space from the outside.
Therefore, even when the natural wind is weak or when there is no wind, the room space can be properly ventilated.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, preferred embodiments of the present invention will be specifically described with reference to the drawings.
[0018]
Hereinafter, as shown in FIG. 1, the ventilation structures 1 and 2 of the first and second embodiments ventilate the living rooms R11 to R14 and R21 to R24 of the buildings B1 and B2. It was installed behind the ceiling of the dwelling unit.
Here, the living room spaces R11 to R14 and R21 to R24 are partitioned by walls, doors, and the like, and can be individually cooled and heated.
[0019]
[First Embodiment]
As shown in FIG. 1, the ventilation structure 1 according to the present embodiment has an air supply route (main air supply ducts 11 and 21, branch air supply) for supplying outside air from the side of the building B <b> 1 into each of the living room spaces R <b> 11 to R <b> 14. Ducts 13 and 23) and an exhaust route (main exhaust duct 12, branch exhaust duct 14) for exhausting air from inside each of the living room spaces R11 to R14 to the side surface of the building B1.
The outside air is supplied into the main supply duct 11 by the supply fan 15, and the air in the main exhaust duct 12 is discharged outside by the exhaust fan 16.
[0020]
A heat exchanger T1 is provided at a portion where the branch air supply duct 13 and the branch exhaust duct 14 are connected to each of the room spaces R11 to R14. Thereby, the heat exchange between the outside air supplied to each of the room spaces R11 to R14 and the room air exhausted from the room spaces R11 to R14 can be individually performed for each of the room spaces R11 to R14. I have.
[0021]
[Second embodiment]
As shown in FIG. 2, the ventilation structure 2 according to the present embodiment is configured such that the air inlet 21 a provided on one of the side surfaces (for example, the north outer wall surface) S <b> 1 of the building B <b> 2 faces the other side surface (for example, the south side). Main air supply duct 21 arranged to penetrate into an air supply port 21b provided in S2, and a branch air supply duct connecting the main air supply duct 21 and each of the living room spaces R21 to R24. 23.
Further, each of the living room spaces R21 to R24 is provided with an exhaust duct 24 connected to a branch air supply duct 23 and a heat exchanger T2, and the exhaust duct 24 is provided in an exhaust chamber 22 which is located above the ceiling of the building B2. Through the air outlets 22a and 22b provided on the side surfaces S1 and S2 of the building B2.
[0022]
The air supply ports 21a and 21b prevent backflow of air in the main air supply duct 21 and stabilize the air flow of the outside air flowing into the main air supply duct 21 from outside. An adjustment damper (backflow prevention damper, air volume adjustment damper) 25 is provided.
Also, at the exhaust ports 22a and 22b, a backflow prevention / air volume adjustment damper 26 configured similarly to the backflow prevention / air volume adjustment damper 25 to prevent air from flowing back into the exhaust chamber 22 from outside is provided. Provided.
[0023]
Further, a sensor 27 for detecting an air flow rate of an airflow passing through the inside of the main air supply duct 21 is provided.
The exhaust chamber 22 is provided with an exhaust fan 28 for discharging air from the exhaust chamber 22 to the side of the building when the airflow detected by the sensor 27 is smaller than a predetermined value.
[0024]
Here, the backflow prevention / air volume adjustment damper 25 (26) will be described with reference to FIGS.
As shown in FIG. 3, the backflow prevention / air volume adjustment damper 25 (26) includes a cylindrical frame member 251, a main blade 252 formed in a disk shape corresponding to the inner diameter of the frame member 251, and a frame member 251. Are provided with auxiliary blades 254 formed in a semi-disc shape corresponding to the inner diameter of.
[0025]
The main blade 252 is attached to the inside of the frame member 251 via a main blade rotation shaft 253 orthogonal to the axial direction of the frame member 251, and can be smoothly rotated about the main blade rotation shaft 253. ing.
A main blade stopper 257 is provided on the upper inner surface of the frame member 251, and just before the main blade 252 closes the internal space of the frame member 251, the main blade 252 rotates clockwise in FIGS. 3 and 4. It is becoming regulated.
[0026]
The leeward side of the wind direction in the steady state from the main blade rotation shaft 253 of the main blade 252 is defined as an upper operating portion 252a, and the leeward side is defined as a lower operating portion 252b (see FIGS. 3 and 4). The main blade rotation shaft 253 is set at a position slightly shifted from the center of gravity of the main blade 252 so as to be slightly heavier than the portion 252b side.
Therefore, in a state of no wind and a small air volume where the main blade 252 receives almost no wind resistance, the main blade 252 tries to rotate counterclockwise, but this rotation is performed at a position where the main blade 252 is substantially horizontal. In order to restrict the movement, a stopper 259 is provided on the inner surface of the frame member 251 at the time of a small air flow such as a screw.
[0027]
The auxiliary blade 254 is attached to the inside of the frame member 251 via an auxiliary blade rotation shaft 255 substantially coinciding with the main blade rotation shaft 253, and can be smoothly rotated around the auxiliary blade rotation shaft 255. ing.
An auxiliary blade stopper 258 is provided on the lower inner surface of the frame member 251, and the auxiliary blade 254 closes a portion of the internal space of the frame member 251 below the auxiliary blade rotation shaft 255, and the auxiliary blade stopper 258 shown in FIGS. The counterclockwise rotation of the blade 254 is regulated. Therefore, the auxiliary blade 254 can smoothly rotate in a region on the left side of the auxiliary blade stopper 258.
The auxiliary blade 254 hangs down from the auxiliary blade rotation shaft 255 until it receives a wind pressure of a certain value or more from the right side. Further, even if wind pressure is received from the left side in FIGS. 3 and 4, the rotation is restricted by the auxiliary blade stopper 258.
[0028]
As described above, the upper operation section 252a of the main blade 252 is set slightly heavier than the lower operation section 252b so that the upper operation section 252a is lowered in the state of no wind and at the time of the small air volume. This may be realized by slightly shifting the position of the main blade rotation shaft 253 with respect to the main blade 252 from the center of the main blade 252, or by providing a weight (not shown) on the upper operation unit 252a. Is also good.
[0029]
The operation of the thus configured backflow prevention / air volume adjustment damper 25 (26) will be described with reference to FIG. Here, the wind from the leeward side (the right side in FIG. 4) of the normal wind direction is called a forward airflow, and the wind from the leeward side (the left side in FIG. 4) is called a reverse airflow. Further, the description of the magnitude of the air volume is based on the forward airflow.
[0030]
When the air volume inside the backflow prevention / air volume adjustment damper 25 (26) is no wind or small air volume, the upper operating portion 252a side of the main blade 252 is heavier than the lower operating portion 252b side, so the main blade 252 rotates counterclockwise. However, as shown in FIG. 4A, this rotation is restricted by the small air volume stopper 259, and the main blade 252 is substantially horizontal. In addition, the auxiliary blade 254 has not reached a critical air flow rate at which the auxiliary blade 254 is separated from the auxiliary blade stopper 258, and the auxiliary blade 254 remains in a state of hanging downward. Thus, the wind blows through the upper space of the main blade 252.
[0031]
When the inside of the backflow prevention / air volume adjusting damper 25 (26) has a small air volume to a medium air volume, the auxiliary blade 254 receives a wind pressure of a certain value or more from the right side. Then, when the auxiliary blade 254 reaches a critical airflow at which the auxiliary blade 254 separates from the auxiliary blade stopper 258, as shown in FIG. 4B, the auxiliary blade 254 rotates clockwise about the auxiliary blade rotation shaft 255, and A gap is generated between the auxiliary blade 254 and the lower inner surface of the frame member 251. Thus, the wind blows through the upper space of the main blade 252 and the lower space of the auxiliary blade 5.
Further, as shown in FIG. 4C, the main blade 252 is rotated clockwise by the air-receiving portion 256 formed on the lower surface of the main blade 252 being pushed up by the auxiliary blade 254.
[0032]
When the upper operating part 252a of the main blade 252 rotates clockwise by slightly rotating the main blade 252, as shown in FIG. 4C, the upper space of the main blade 252 inside the frame member 251 moves to the right. To the left. As a result, the flow velocity of the wind passing through the upper space gradually increases from the right side to the left side, and a larger lift acts on the upper operation part 252a than the lift acting on the lower operation part 252b.
As described above, the amount of air flowing inside the backflow prevention / air volume adjusting damper 25 (26) increases, and the lift reaches the critical air flow rate for rotating the main blade 252, and then the main blade 252 rotates clockwise. . At the stage of transition from the medium air flow rate to the atmospheric flow rate, the main blade 252 rotates in a direction (clockwise) to close the frame member 251.
[0033]
When the amount of air flowing inside the backflow prevention / air volume adjustment damper 25 (26) further increases, as shown in FIG. 4D, the main blades 252 rotate clockwise and are likely to hit the main blade stopper 257. The air flow passing above and below the main blade 252 is significantly reduced. Then, the lift acting on the upper operating section 252a and the lower operating section 252b is reduced and the lift difference is also reduced, so that the main blade 252 rotates slightly to the opposite side and the air flow passing above and below the main blade 252 is slightly reduced. To increase. Then, the upper operating portion 252a receives the lift again, and the main blade 252 slightly rotates in the direction to close the frame member 251, so that the air flow passing above and below the main blade 252 decreases. Thereafter, these operations are repeated while gradually attenuating, and the air flow is stabilized.
[0034]
At the time of the reverse airflow, as shown in FIG. 4 (e), an air pocket occurs in the lower space of the upper operation unit 252a, and the lower surface of the upper operation unit 252a receives the wind pressure and rises upward. As shown in (f), the main blade 252 rotates clockwise until it comes into contact with the main blade stopper 257, and the frame member 251 is closed by the main blade 252 and the auxiliary blade 254. Therefore, the airflow passing through the backflow prevention / air volume adjustment damper 25 (26) becomes substantially zero, and the backflow is prevented.
[0035]
As described above, according to the ventilation structures 1 and 2 described in the first and second embodiments, the portions where the air supply route and the exhaust route are connected to the respective living room spaces R11 to R14 and R21 to R24 are respectively provided. Since the heat exchangers T1 and T2 are provided, the heat exchange between the outside air supplied to each of the living room spaces R11 to R14 and R21 to R24 and the indoor air exhausted from the living room space is performed by each of the living room spaces. This can be performed individually for each of R11 to R14 and R21 to R24.
Therefore, in the buildings B1 and B2 having the plurality of living room spaces R11 to R14 and R21 to R24, a ventilation structure having a small heat energy loss during cooling or heating is provided.
[0036]
Further, according to the ventilation structure 2 described in the second embodiment, the air supply port 21b (21a) on the leeward side and the exhaust port 22a (22b) on the leeward side are closed according to the wind direction around the building B2. Outside air flows from the air supply ports 21a (21b) on the windward side into the living room spaces R21 to R24 through the main air supply duct 21 and the branch air supply duct 23. At this time, the outside air taken into the living room spaces R21 to R24 exchanges heat with the air discharged from the living room spaces R21 to R24 to the branch exhaust duct 24.
Then, the air in the living room spaces R21 to R24 discharged from the branch exhaust duct 24 passes through the exhaust chamber 22 and is exhausted from the exhaust port 22b (22a) on the leeward side.
In this manner, in the building B2 having the plurality of living room spaces R21 to R24, even when cooling or heating is performed only in some of the living room spaces R21 to R24, the ventilation structure with a small amount of heat energy loss can reduce the natural wind. It can be realized by using.
[0037]
Further, since the airflow openings 21a and 21b are provided with the backflow prevention / airflow amount adjustment dampers 25 for stabilizing the airflow of the airflow flowing into the main air supply duct 21 from the outside, even if the natural airflow volume changes. The ventilation of the room spaces R21 to R24 can be stably performed.
[0038]
Further, when the sensor 27 detects that the airflow of the airflow passing through the main air supply duct 21 is smaller than a predetermined value, that is, a natural wind having a sufficient strength to ventilate the living room spaces R21 to R24 is blowing. When not present, the exhaust fan 28 is operated, and the air in the living room spaces R21 to R24 is discharged to the outside of the building B2 through the branch exhaust duct 24 and the exhaust chamber 22, and the main air supply duct 21, the branch air supply duct 23 , Outside air is drawn from the outside of the building B2 to the living room spaces R21 to R24.
Therefore, even when the natural wind is weak or when there is no wind, the ventilation of the living room spaces R21 to R24 can be appropriately performed.
[0039]
It should be noted that the present invention is not limited to the above embodiment, and various improvements and design changes may be made without departing from the spirit of the present invention.
For example, in the second embodiment, the exhaust ports 22a and 22b are provided with the backflow prevention / air volume adjustment damper 26 having both the backflow prevention function and the air volume adjustment function. However, a damper having only the backflow prevention function is provided. Is also good.
In addition, it is needless to say that specific detailed structures and the like can be appropriately changed.
[0040]
【The invention's effect】
According to the first aspect of the present invention, since a heat exchanger is provided at a portion where the air supply route and the exhaust route are connected to each room space, the outside air supplied to each room space is provided. The heat exchange between the room air discharged from the room and the room air can be individually performed for each room.
Therefore, in a building having a plurality of living room spaces, a ventilation structure having a small heat energy loss during cooling or heating is provided.
[0041]
According to the invention described in claim 2, the air supply port on the leeward side and the exhaust port on the leeward side are closed according to the wind direction around the building, and the main air supply duct and the branch air supply are provided from the air supply port on the leeward side. Outside air flows into the room through the duct. At this time, the outside air taken into the living room space exchanges heat with air discharged from the living room space to the branch exhaust duct.
Then, the air in the living room space exhausted from the branch exhaust duct is exhausted from the exhaust port on the leeward side through the exhaust chamber.
Therefore, in a building having a plurality of living room spaces, in addition to the effects obtained by the invention according to claim 1, even when cooling or heating is performed only in a part of the room spaces, a ventilation structure with a small heat energy loss is provided. It can be realized using natural wind.
[0042]
According to the third aspect of the invention, since the air supply port is provided with the air volume adjustment damper for stabilizing the air volume of the airflow flowing into the main air supply duct from the outside, the invention according to the second aspect is provided. In addition to the obtained effects, there is an advantage that the ventilation of the living room can be stably performed even if the amount of natural wind changes.
[0043]
According to the fourth aspect of the present invention, when the sensor detects that the airflow of the airflow passing through the main air supply duct is smaller than a predetermined value, that is, the natural air having sufficient strength to ventilate the living room space. When the wind is not blowing, the exhaust fan operates and the air in the living room space is exhausted to the outside of the building through the branch exhaust duct and exhaust chamber, and the building air is exhausted through the main air supply duct and the branch air supply duct. Outside air is drawn into the living room space from the outside.
Therefore, in addition to the effects obtained by the invention of claim 2 or 3, there is obtained an advantage that the ventilation of the living room space can be appropriately performed even when the natural wind is weak or when there is no wind.
[Brief description of the drawings]
FIG. 1 is a plan view showing an example of a ventilation structure according to the present invention.
FIG. 2 is a sectional view showing another example of the ventilation structure according to the present invention.
FIG. 3 is a perspective view showing an example of a backflow prevention damper and an air volume adjustment damper used in the ventilation structure according to the present invention.
FIG. 4 is a cross-sectional view showing the operation of an example of a backflow prevention damper and an air volume adjustment damper used in the ventilation structure according to the present invention.
FIG. 5 is a sectional view showing an example of a conventional ventilation structure.
FIG. 6 is a plan view showing another example of the conventional ventilation structure.
[Explanation of symbols]
1, 2 Ventilation structure 11, 21 Main air supply duct 12 Main exhaust duct 13, 23 Branch air supply duct 14, 24 Branch exhaust duct 22 Exhaust chamber 25, 26 Backflow prevention / air volume adjustment damper (backflow prevention damper, air volume adjustment damper)
27 Sensor 28 Exhaust fan B1, B2 Buildings R11 to R14, R21 to R24 Living room space S1 One side S2 (of the building) The other side T1, T2 (of the building) Heat exchanger

Claims (4)

A ventilation structure for ventilating the interior space of the building,
An air supply route for supplying outside air from the side of the building to each of the living room spaces,
An exhaust route for discharging air from each living room space to the side of the building;
A ventilation structure, comprising: a heat exchanger provided at a portion where the air supply route and the exhaust route are respectively connected to the living room spaces. The main air supply duct is arranged so that the air supply route penetrates from an air supply port provided on one side of the building facing each other to an air supply port provided on the other side of the building. A main air supply duct and a branch air supply duct that communicates with each of the living room spaces;
The exhaust route, an exhaust duct connected to each living room space and connected to the branch air supply duct and a heat exchanger, and an exhaust port provided on the one side and the other side of the building, An exhaust chamber communicating the exhaust duct and the exhaust port,
The air supply port is provided with a backflow prevention damper that prevents air in the main air supply duct from flowing out to the outside,
The ventilation structure according to claim 1, wherein the exhaust port is provided with a backflow prevention damper that prevents air from flowing back into the exhaust chamber from outside. The ventilation structure according to claim 2, wherein the air supply port is provided with an air volume adjustment damper that stabilizes an air volume of an airflow that flows into the main air supply duct from outside. A sensor provided in the main air supply duct, for detecting a flow rate of an airflow passing through the inside;
4. An exhaust fan according to claim 2, further comprising: an exhaust fan configured to exhaust air from the exhaust chamber to the side of the building when an air volume detected by the sensor is smaller than a predetermined value. Ventilation structure.

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