JP6284733B2 - Building with natural ventilation - Google Patents

Description

  The present invention relates to a building having a natural ventilation system on multiple floors.

29 , 30 and 31 show conventional examples. Opening 1a on one side of the outer wall surface 1 of the building A as shown in FIG. 29, has a 1b, other outer wall surface 2 on the opposite side of one of the outer wall surface 1 and the building A, the opening except the top in the wall surface without the first floor of the chamber R1,2 floor of the chamber R2 is opening facing the blow 4 along the other of the outer wall surface 2 1ra, it has 1 RB. A ventilation chamber 6 having a roof 5 is provided in the upper part of the atrium 4. An opening 6 i is provided in the wall of the ventilation chamber 6 near the one outer wall surface 1, and an opening 6 o is provided above the other outer wall surface 2 at the same height as the opening 6 i. The openings 6i and 6o have protruding shojis 7i and 7o.
The building A shown in FIG. 30 is the same as the building A shown in FIG. 29 except that the openings 6i and 6o are provided with check valves 7a and 7b.
The check valve 7a is open when the wind force is small , but closes the opening 6i when the wind speed is about 1 m / s or more, for example.

In the building having the configuration as shown in FIG. 30, when the wind speed is about 1 m / s or more, the check valve 7a is closed as shown in FIG. Therefore wind w is an arrow b, blow to blow fourth opening 1a, a 1b through the chamber R1, R2 becomes airflow such as B, arrow C, air flow rising medium atrium 4 as two are ventilated Entering the chamber 6 is directed to the opening 6o as indicated by an arrow e, and is discharged to the outside from the opening 6o as indicated by an arrow.

Patent Document 1 Japanese Patent Application Laid-Open No. 2000-213184 Patent Document 2 Japanese Patent Application Laid-Open No. 2003-083575 Patent Document 3 Japanese Patent Application Laid-Open No. 2009-133526

None

In building shown in FIG. 29, the air Nagareto flowing from the opening 6i windward side to the ventilation chamber 6 is thus exhausted from the leeward side of the opening 6o rampant ventilation chamber 6 (short-circuit). The velocity of the wind flowing in from the windward opening 6 i is reduced in the ventilation chamber 6, and part of the velocity energy of the incoming air is converted into pressure energy in the ventilation chamber 6. As a result, the air that has risen up the blow-through 4 mainly causes a backflow hike at the upper portion of the blow-through 4. The air flow in the direction of the arrow b blown from the openings 1a and 1b due to the wind w goes right in the rooms R1 and R2, but the flow velocity is small, so the air flowing into the room R1 on the first floor is warmed and rises after leaving the opening 1ra As shown by the arrow, the second floor room R2 is exhausted from the opening 1b toward the opening 1b on the one outer wall 1 side as indicated by the arrow. As a result, the room R1 on the first floor becomes fresh air, but the air in the room R2 on the second floor is air that is no longer fresh on the first floor.

In the invention described in Patent Documents 1 and 3, it comprises a vent on one of the outer wall surface, is less open or not there is the window on the other outer wall surface. It is a proposal to measure ventilation in such a case . In the invention according to Patent Document 1 includes a duct called ecological shaft. The invention according to Patent Document 3 includes a ventilation tower. That is, the invention according to Patent Documents 1 and 3 performs natural ventilation by a so-called chimney effect in a building that does not have an opening that can be sufficiently ventilated on the back side (the other outer wall surface), and has excellent ventilation capability.
In Patent Document 2, air supply is provided with backflow prevention dampers on opposite sides in the house, and an exhaust duct that opens to the ceiling and produces a chimney effect is provided.

In the building having the natural ventilation device shown in FIG. 29 as described above, indoor ventilation is effective as shown in FIG. 29 even if air supply openings and exhaust openings with check valves are provided on the windward and leeward sides. Not done.
Figure 29 As described above, in a building shown in FIG. 30, when the opening for the exhaust to the outer wall surface side of the leeward side is not provided, there is a problem that should be on how the ventilation of the building.
That is, the window may not be provided depending on the state of the surrounding building, topography, facilities, and the like.

FIG. 31 shows a conventional example. This building A is the building A shown in FIG. 30, in which the second floor is three floors and the opening 6o on the leeward side of the ventilation chamber 6 is eliminated. The check valve 7a provided in the opening 6i facing the windward is closed at a wind speed of the wind w of about 1 m / s, for example. The air flowing from the opening 1a on the first floor of the chamber R1, one of the outer wall surface as the willing warmed by upward flow of arrow Li, j and turned to the third floor of the chamber R3 arrow Le as arrow b The air is exhausted from the opening 1c facing the opening 1c on the one side. As a result, the room R1 on the first floor becomes fresh air, but the air in the room R3 on the third floor is air that is no longer fresh on the first floor.
Although the provision of the exhaust duct as in Patent Documents 1 and 3 is one solution, not a little if the provision of the high exhaust duct is excluded.

  As a ventilation passage, for example, there is an opening on each floor on one outer wall surface side, the other outer wall surface is a wall surface that does not have an opening, the other outer wall surface has an atrium open to each floor, and a roof is formed on the upper portion of the atrium. An object of the present invention is to provide a building having a natural ventilation device in which ventilation on each floor is effectively performed in a building having a natural ventilation device having a ventilation room.

Each of the inventions of the present application has one outer wall surface having an opening, the other outer wall surface not having an opening that allows ventilation on the opposite side to the one outer wall surface, and one outer wall surface provided at the top of the building. A multi-story natural ventilation device having an exhaust opening that opens in the same direction as the provided opening and having a space serving as a ventilation passage from the opening provided on one outer wall surface to the exhaust opening Relates to a building having

Each of the inventions of the present application has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface, and the upper surface of the windproof member. A natural airflow exhaust louver is provided in the opening of the exhaust, which exhausts the air inside the building to the outside but closes when the airflow in the same direction as the wind blown to one outer wall surface becomes large. It is a building with a ventilation device.

In the present invention, the exhaust backflow prevention louvers may be flat shape in the horizontal direction.

In the invention according to claim 1, exhaust backflow prevention louvers that are disposed at substantially the same height as the top of the roof of the building.

In the invention which concerns on Claim 2, it has a ventilation room above the rooftop of the top floor, and the opening facing the direction of the wind which blows on one outer wall surface for exhaust_gas | exhaustion is provided in the ventilation room.

In the invention which concerns on Claim 3, the backflow prevention louver for exhaust has the blade | wing supported rotatably with the support shaft installed transversely with respect to the wind direction, and by the strength of the wind which blows toward a wind-proof member wings closed or that have been established position relative to the blade of the support shaft so as to open.

In the invention according to claim 4, that have a rotary control device of the blade taking the open or closed position and force the position for opening and closing blades by wind.

The invention according to claims 5 and 6 has a chamber facing an opening provided on one outer wall surface side, and takes in outside air into this opening, but is closed by an air flow from the indoor side to the outside side. obtain Bei care for backflow prevention louver.

The invention according to claim 6 further includes a windproof member constituting a space communicating with the opening outside the opening of the chamber provided on the one outer wall surface, the windproof member on the lower surface side and the outside air in the chamber. While flowing Ru windbreak member der having closed space having an opening having a suppressing air supply backflow prevention louver backflow indoor air to the outside from the chamber.

In the invention which concerns on Claim 7, a building is provided with the room which has an opening in one outer wall surface, is an opening in the building on the opposite side to this opening of the room which has an opening in one outer wall surface, and is exhausted There is an opening / closing member at the opening in the building that communicates with the backflow prevention louver, and the opening on one outer wall surface ventilates the entire building when the opening / closing member is opened, and the opening of the room when the opening / closing member is closed. that having a device that performs the air supply or air supply and exhaust carry out the ventilation.

In the invention which concerns on Claim 8, the backflow prevention louver for ventilation which suppresses the inflow of the external air to room | chamber interior by the magnitude | size of a wind force on the upper surface at the opening of one outer wall surface side, or discharges indoor air, and a lower surface that Yusuke and air supply louver performing air supply, and windbreak member that closes the space between the ventilation backflow prevention louver and air supply louver respect building outside.

In the invention according to claim 9, that have a air duct member extending chamber between the ventilation backflow prevention louver and air supply louver beyond the opening of the partition one outer wall surface side down in the windbreak member.

In the invention which concerns on Claim 10, it is the opening in the building on the opposite side to this opening of the room which has an opening in one outer wall surface side, Comprising: The opening in the building connected with the backflow prevention louver for exhaust_gas | exhaustion The opening on the one outer wall surface side is provided separately on the ceiling side and the floor side of the room, and the opening on the ceiling side is operated for ventilation by outside air and closes when the wind force is large A backflow prevention louver and an upper damper that closes when performing overall ventilation of the building and opens when the individual ventilation of the room is provided are stacked, and when the outside air flows into the opening on the floor side, it opens and the indoor air When the air is about to flow out, the air supply backflow preventing louver and the upper damper are closed together with the lower damper that is closed when the general ventilation and the individual ventilation are not performed.

In the invention which concerns on Claim 11, the opening of one outer wall surface is divided up and down, and the partition material which comprises an upper opening lower opening and the lower opening can supply external air, but it is outside the building of indoor air A backflow prevention louver for air supply that suppresses the outflow of air, a windproof member that is provided on the outer side of the upper opening and has an upper surface that opens and communicates with the upper opening through the space, and an opening on the upper surface of the windbreak member. A backflow prevention louver for individual ventilation that discharges air outside the building but closes when the wind force of the outside air becomes large, and a position where it is pivotally attached to the partition material and the upper opening is closed and opened inward. And a damper that conducts wind at a position in the horizontal direction.

In the invention according to claim 12, backflow preventing louver air supply is that is parallel to upright and one of the outer wall surface.

In the invention which concerns on Claim 13, the member which supplies or exhausts air is a front plate parallel to one outer wall surface, a side plate perpendicular to one outer wall surface, and one outer wall surface. A lower air supply backflow prevention louver that is perpendicular to the horizontal direction and a flat airflow backflow prevention louver and an upper ventilation backflow prevention louver that form a hollow six-cube in the assembled state, Each of the backflow prevention louver for ventilation and the backflow prevention louver for ventilation is pivotally attached to the edge of the opening provided on one outer wall surface so as to have a position parallel to and perpendicular to the one outer wall surface. apart from location and one of the outer wall surface side along the outer wall surface that is coupled with a parallel motion device on one of the outer wall surface to take a position parallel to one of the outer wall surface.

In the invention which concerns on Claim 14, it replaces with the backflow prevention louver for ventilation, and it is set as the board | plate material.
In the invention which concerns on Claim 15, it changes into the backflow prevention louver for supply air, and is set as the board | plate material.
In the invention which concerns on Claim 16, it was set as the multilayer floor which has one opening provided in the one outer wall surface side, and the other opening provided with the opening-and-closing member which looked into the space in a building to Yes and the chamber, and a the space leading to the opening of the exhaust at the top along with leading the other opening of said each chamber.

Present in each invention, it is possible to perform effective natural ventilation in one outer wall surface side has an opening other without building an opening on the outer wall surface side.
Further, if the air backflow prevention louver is formed into a flat shape in the horizontal direction, ventilation is assisted by the airflow flowing over the exhaust backflow prevention louver, and blowing in the building when wind power increases is prevented.

According to the invention which concerns on Claim 1, since the exhaust means of a building is substantially the same as the height of a building, a high chimney-like exhaust pipe is provided, and a landscape is not damaged and a problem is not produced in safety. .
According to the invention which concerns on Claim 2, it only provides the ventilation room which has the opening which opposes a wind power on a roof, and does not affect the external appearance of a building.

According to the third aspect of the present invention, the exhaust backflow prevention louver is open at low wind speeds where natural ventilation is possible due to the fluctuation of wind power, and is maintained at natural ventilation, and is closed automatically at high winds, so wind blowing is possible. There is no need to monitor and open and close the exhaust side of the building.

According to the invention according to claim 4, since the blades can be kept open or closed according to the wind force, and can be forcibly closed or opened, the ventilation state of the exhaust backflow prevention louver is left only to the wind force. It is possible to make a selection that can be artificially made into a desired form.
According to the invention which concerns on Claim 5, it can prevent that the air which is not fresh in the room flows backward.
According to the invention which concerns on Claim 6, it is suppressed by a wind-proof member that a wind blows directly into opening of a chamber. And it is suppressed by the backflow prevention louver for supply air that indoor air flows backward.
According to the invention which concerns on Claim 7, the natural ventilation of the whole building and the individual ventilation of a room can be selectively performed.
According to the invention which concerns on Claim 8, when a wind force becomes large, it can suppress that a wind blows into a room | chamber and individual natural ventilation of a room | chamber can be performed.
According to the invention which concerns on Claim 9, inflow and outflow of the air to a chamber can be performed reliably.

According to the invention which concerns on Claim 10, since the floor side opening and the ceiling side opening are separated up and down, the efficiency of individual ventilation is good. And it is possible to switch to general ventilation just by closing the upper damper . By closing the upper and lower dampers, the building can be closed, and it can respond to disturbances such as storms.

According to the invention of claim 11, since the air entering the room from the backflow prevention louver for air supply is not directed directly to the upper opening by the horizontal damper during individual ventilation, the ventilation effect of the room is improved. The entire building can be ventilated simply by closing the upper opening with a damper.
According to the invention which concerns on Claim 12, the height of a wind-proof member can be made small and the function of air supply is maintained.
According to the invention which concerns on Claim 13, when individual ventilation is unnecessary, it can accommodate.
According to the invention which concerns on Claim 14, the backflow prevention louver for supply can be accommodated small.
According to the invention which concerns on Claim 15, the backflow prevention louver for exhaust can be accommodated small.

It is a longitudinal cross-sectional view of the building of Example 1. It is a longitudinal cross-sectional view of the backflow prevention louver for exhaust. It is a longitudinal cross-sectional view of the backflow prevention louver for exhaust. It is a longitudinal cross-sectional view of the backflow prevention louver for exhaust. It is a longitudinal cross-sectional view of the building of Example 2. It is a longitudinal cross-sectional view of an air supply / exhaust box. It is a perspective view of an air supply / exhaust box. It is a related figure of an air supply / exhaust box and sunshine. It is a chart related to supply and exhaust of the supply and exhaust box. (A), (A), (A), (A) and (B) are longitudinal sectional views showing the operation of the air supply / exhaust box. It is a longitudinal cross-sectional view of an air supply / exhaust box. It is a longitudinal cross-sectional view which shows the individual ventilation of the chamber | room which provided the air supply / exhaust box. (A), (b), and (c) are longitudinal sectional views of Example 4, respectively. It is a longitudinal cross-sectional view of the building of Example 5. It is a longitudinal cross-sectional view of the air supply / exhaust device of Example 5. It is a longitudinal cross-sectional view of the air supply / exhaust device of Example 5. It is a longitudinal cross-sectional view of the backflow prevention louver for air supply. It is a longitudinal cross-sectional view of the backflow prevention louver for air supply. It is a longitudinal cross-sectional view of the backflow prevention louver for air supply. It is a longitudinal cross-sectional view of the windbreak board of Example 6, and the backflow prevention louver for exhaust. It is a horizontal sectional view of the windproof plate of Example 6 and the backflow prevention louver for exhaust. It is a perspective view of the side facing the windward side of a building. It is a side view of the air supply / exhaust box which can be accommodated of Example 7. It is a horizontal sectional view of the air supply / exhaust box which can be stored in Example 7. It is sectional drawing which shows attachment to the existing frames, such as an air supply / exhaust box of Example 8. FIG. It is a longitudinal section which shows the effect | action of a windbreak board. It is a longitudinal cross-sectional view which shows the effect | action of an air supply box. It is a longitudinal cross-sectional view which shows the effect | action of an air supply box. It is a longitudinal cross-sectional view which shows a prior art example. It is a longitudinal cross-sectional view which shows a prior art example. It is a longitudinal cross-sectional view which shows a prior art example. (B2), (B3), (C) and (D1) are longitudinal sectional views showing the operation of the air supply / exhaust box. (D2) (E1), (E2) and (F) are longitudinal sectional views showing the operation of the air supply / exhaust box. (G), (H1), (H2), and (R) are longitudinal sectional views showing the operation of the air supply / exhaust box.

Hereinafter, a description will be given to an embodiment of the present invention with reference to the drawings.
Example 1

FIG. 1 is a schematic side sectional view of a building A. Building A is a multi-story, one outer wall surface opening 1a provided as air inlets of 1, 1b, ventilation passages to the space communicating to the opening 6i provided as uppermost portion of the exhaust port consists of 1c.

The outer wall surface 1 one of a front of a building A, with each floor of the chamber R1, R2, R3 of the opening 1a, 1b, and 1c. In this example, the openings 1a, 1b, and 1c are located near the ceilings of the rooms R1, R2, and R3. The other outer wall surface 2 does not have an opening. Here, having no opening includes the case where even if there is an opening, the building A hardly contributes to ventilation. Further, the side wall surface of the building A parallel to the paper surface of the figure has an opening that hardly contributes to ventilation of the entire building A or no opening. The inside of the other outer wall surface 2, a floor of the chamber R1, R2, R3 in the opening 1ra, 1 RB, a blow-4 which is opened as leads in 1RC. Here, the blow-out means from the floor surface FL to the ventilation chamber 6. The atrium 4 may be a facility space. That is, you may equip some steps, escalators, etc.

  A ventilation chamber 6 having a roof 5 is provided at the top of the atrium 4. An opening 6 i is provided in the wall on the side close to the outer wall surface 1 on the one windward side of the ventilation chamber 6. The other outer wall of the ventilation chamber 6 is flush with the outer wall surface 2.

  A box-shaped windproof plate 8 and an exhaust backflow prevention louver (hereinafter sometimes referred to as a louver, or a backflow prevention louver or an exhaust louver) 9 are surrounded as a windproof member that forms a space outside the opening 6i. The position of the backflow prevention louver 9 in the vertical direction is substantially the same as that of the roof 5 above the blow-through 4. The roof 5 is the roof of the ventilation chamber 6.

  The windbreak plate 8 is provided outside the opening 6i so as to form a space 8a, and the space 8a is rectangular in this example. One of the spaces 8a communicates with the ventilation chamber 6 through an opening 6i. The upper part of the space 8 a is partitioned by a louver 9. The windbreak plate 8 excluding the louver 9 and the opening 6i is a non-breathable plate material. The louver 9 is an exhaust backflow prevention louver. The windbreak plate 8 is made of glass when daylighting is necessary, but may be made of aluminum.

  2, 3, and 4 are side sectional views schematically showing the backflow prevention louver 9. The blades 9a of the backflow prevention louver 9 have a strip shape that is long in a direction perpendicular to the drawing sheet. The blade 9a is supported by the four-side frame 9c so as to be swingable by a support shaft 9b having a center in a direction perpendicular to the paper surface of the drawing. Here, the support shaft 9b is provided horizontally with respect to the wind direction. In the various louvers that will be described below, the support shafts are also set transverse to the wind direction. Here, horizontal installation is limited to the case of facing in the horizontal direction. The support shaft 9b is in the middle of the width direction of the blade 9a (the direction of finding in FIG. 2). The blade 9a is urged in a standing direction with respect to the support shaft 9b in a free state. That is, the louver 9 opens naturally as long as the louver 9 does not receive the force of the air flow. The urging of the blade 9a is based on the balance of the primary moment based on the gravity of the blades on both sides of the support shaft 9b, the attachment of a torsion coil spring (not shown), a weight (not shown) provided on the support shaft 9b, and the like. The blade 9a is prevented from rotating counterclockwise by a stopper 11 provided on the four-sided frame 9c (see FIG. 3).

In this example, the blade 9a is divided into a lower portion 9a1 and an upper portion 9a2 with a support shaft 9b as a boundary. The width of the upper part 9a2 is larger than the width of the lower part 9a1. First moment based on the gravity around the support shaft 9b is lower portion 9a1, the cross-sectional shape of the upper portion 9a2 defined as the lower portion 9a1 becomes lower than the support shaft 9b. Here, the blade 9a is aluminum. The cross section of the blade 9a is a flat plate or an airfoil.

According to the above configuration, in FIG. 3, when the wind force of the wind blown from the left side to the right side exceeds a certain value, for example, about 1 m / s or more , the blade 9a rotates clockwise around the support shaft 9b. When further increased, the blades 9a are further rotated and overlapped, and the backflow prevention louver 9 is closed. Conversely, when the wind force is reduced , the blade 9a rotates counterclockwise about the support shaft 9b, and the backflow prevention louver 9 opens.

2, 3, the backflow prevention louvers 9 shown in FIG. 4, the opening and closing device 12 force the opening or closing of the blades as a rotation control device for blade are annexed. The opening / closing device 12 has pieces 12a, 12a, 12a interlocking in the left-right direction in the drawing just above the support shaft 9b of each blade 9a. The interval between the pieces 12a is the same as the interval between the support shafts 9b. The pieces 12a, 12a, and 12a are supported by the four-sided frame 9c so as to be movable parallel to the paper surface in the drawing. There are two support shafts 9b and three pieces 12a. The piece 9a is disposed at a position where it does not interfere with the stopper 11, for example, on the opposite side in the longitudinal direction of the blade 9a.

As shown in FIG. 3 , the backflow prevention louver 9 opens and closes the vane 9a by the change in the wind force as described above at the position where the left and center pieces 12a are on the left side of the stopper 11 and do not act on the vane 9a. When the opening / closing device 12 is moved rightward from the position for preventing backflow by wind force in FIG. 3 in the backflow prevention louver 9, the piece 12a slides and pushes the upper portion 9a2 of the blade 9a toward the right above the support shaft 9b, The blade 9a is rotated clockwise around the support shaft 9b to close the backflow prevention louver 9 (see FIG. 4). When the piece 12a is moved leftward from the position shown in FIG. 4 , the blade 9a rotates counterclockwise around the support shaft 9b, and the blade 9a follows the piece 12a. When the piece 12 a passes through the stopper 11 , the blade 9 a is stopped from rotating by the stopper 11. In the position of FIG. 3 beyond the stopper 11 , the louver 9 is closed at a certain wind speed or higher, and is in a position for performing a backflow prevention function to prevent the blowing from the outside to the inside.

When the backflow prevention louver 9 is in the position shown in FIG. 3, when the switch 12 is moved to the left , the central piece 12a reaches the left blade 9a and the right piece 12a reaches the right blade 9a. Thereafter, since the vicinity of the root of the upper portion 9a2 of the blade 9a is in contact with the stopper 11, the blade 9a is forcibly kept open.
Since the piece 12a is usually at a high place, remote control is performed via a link device, a winding transmission device and the like. Further, the position of the piece 12a may be controlled by electric drive, fluid pressure drive, or the like.

In FIG. 1, on the one outer wall surface 1 side of the building A, a backflow prevention louver (airflow backflow prevention louver) 13 and a box-shaped windbreak plate 14 as a windbreak member are provided in each of the rooms R1, R2, and R3. Are provided outside the openings 1a, 1b and 1c for supplying air. Each of the openings 1a, 1b, the just outside of 1c, windbreak plate 14 with six cubic space 14a for supply air in the supply air backflow prevention louver 13 as windbreak member is formed. The backflow preventing louver 13 for supplying air prevents the air in the chambers R1, R2 and R3 from flowing back to the outside through the openings 1a, 1b and 1c. The windbreak plate 14 is made of glass when daylighting is required, but may be made of aluminum.

  The air supply backflow prevention louver 13 (hereinafter sometimes referred to as a louver or backflow prevention louver or air supply louver) will be described with reference to FIG. In the first embodiment, a plate material is used instead of the backflow prevention louver 18 for ventilation. A backflow prevention louver 13 is shown on the lower side of the figure. A backflow prevention louver 13 is provided at the lower opening of the windbreak plate 14. The blades 13a of the louver 13 extend long in the direction orthogonal to the drawing sheet. The blade 13a is supported by the support shaft 15 in a swingable manner in the middle of its width direction (finding direction). The blade 13a is divided into a lower part 13a1 and an upper part 13a2 with the support shaft 15 as a boundary. The width of the upper part 13a2 is larger than the width of the lower part 13a1. The cross-sectional shape and weight of the lower side portion 13a1 and the upper side portion 13a2 are determined so that the lower side portion 13a1 is larger than the upper side portion 13a2 with respect to the primary moment about the support shaft 15. In this example, a weight (not shown) is attached to the lower side 13a1.

The configuration of such blades is the same as described above for the louver 9 on the exhaust side. Although not shown in FIG. 6, FIG. 2, FIG. 3, have likewise stopper is provided with a stopper 11 shown in FIG. 4, and rotates clockwise by the upper portion 13a2 of the blade 13a is upward, the blade 13a Is inclined upward to the left, and the stopper stops rotation in the clockwise direction around the support shaft 15. Accordingly, when the room air tries to flow backward from the chamber R1 through the openings 1a, 1b, 1c, the space 14a, and the louver 13, the air flow causes the blades 13a to rotate counterclockwise about the support shaft 15 and become almost horizontal. The louver 13 is designed to close. Although not shown, a piece similar to the piece 12a shown in FIGS. 2, 3, and 4 may be provided so that the louver 13 is forcibly opened or closed .

Consider the case where the louver 9 is in the backflow prevention state in FIG. 1 as shown in FIG. When the wind w is blowing, an air flow w1 indicated by an arrow is generated on the roof 10 of the building A.
When the wind w blows toward the building A, when the wind w hits one outer wall surface 1 on the left side in FIG. 1 of the building A, most of the air rises along the outer wall surface 1 and rises to the top of the roof 10. The air thus obtained becomes an air flow w1 that flows in the right direction along the roof 10 of the building A.

When the air flow w1 to be directed to the opening 6i is blocked by the front plate of the windbreak plate 8, the wind rises without blowing into the building A through the opening 6i and passes over the louver 9 to the leeward side. The air flow w1-1 (see FIG. 26) that diverges downward against the windbreak plate 8 is a vortex.

  At this time, the air flow w1 passes over the blade 9a and flows rightward. A relative negative pressure is generated on the louver 9 on the side close to the louver 9 below the air flow w1. When the flow velocity of the air flow w1 is small due to this flow, the air pressure in the space above the blade 9a becomes negative with respect to the indoor air pressure of the building A. Further, in FIG. 3, when an air flow strikes the front side of the blade 9a (the left surface in FIG. 3), a negative pressure space is generated on the back side (the right surface in FIG. 3) of the blade 9a.

  When the wind speed of the air flow w1 exceeds a certain level, the air flow w1 blows directly on the blades 9a. Then, the blade 9 rotates clockwise around the support shaft 9b by the air flow w1 applied to the upper portion 9a2 of the blade 9a, and the opening degree of the louver 9 is reduced. When the wind speed further increases, the blades 9a rotate clockwise and overlap each other, and the louver 9 closes. This prevents a strong wind from being blown into the building A. When the wind speed decreases, the blade 9a rotates around the support shaft 9b and the louver 9 opens, contrary to the above.

  Unless the strong wind or the wind direction is unstable and the wind flies, the air flow w1 blowing toward the front surface of the windbreak plate 8 flows downward on the louver 9 and immediately above the louver 9 and the blades 9a. Negative pressure is generated in the space on the back side.

As long as the air pressure in the building A is not lower than the negative pressure in the ventilation chamber 6, the air in the ventilation chamber 6 is discharged outside the building through the opening 6i, the space 8a, and the backflow prevention louver 9, as indicated by the air flow w2 in the arrow. Discharged.

On the other hand, the wind w blows on the front surface of the building A (the outer wall surface 1 facing the left wind in FIG. 1). Each of the chambers R1, R2, and R3 has air supply openings 1a, 1b, and 1c. However , since the wind w is provided with the windbreak plate 14, the chambers R1, R2, and R3 are directly provided through the openings 1a, 1b, and 1c. There is no insufflation. Air around the windbreak plate 14 due to the wind w enters the space 14a through the open louver 13 (see FIG. 28) and flows into the chambers R1, R2, R3 from the air supply openings 1a, 1b, 1c (air flow indicated by arrows). w3). In each of the chambers R1, R2, and R3, air flows from left to right in FIG. 1, and this air enters the vent 4 through the openings 1ra, 1rb, and 1rc between the chambers R1, R2, and R3 and the vent 4, and the ascending air flow It becomes w4 and w5, enters the ventilation chamber 6, and is discharged through the opening 6i, the space 8a, and the backflow prevention louver 9 like the air flow w6. This becomes the air flow w2.

In the above, the air in each room R1, R2, R3 and the blow-off 4 and the ventilation room 6 has the wind w entering the building A through the louver 13 and has a positive pressure in the building A. Therefore, air does not blow into the building A through the opening 6i of the ventilation chamber 6.

If the wind direction is varied by strong wind or wind as already mentioned dancing, the magnitude of the air flow w1 on louvers 9, depending orientation outside air through the louvers 9 when you Fukikomo into the building A. Then, the blade 9a shown in FIG. 3 is rotated around the support shaft 9b by the wind pressure, and the louver 9 is closed. This prevents inflow of outside air from the exhaust side of the building.

In a state that the louver 9 strong winds or the like is closed, air is blown from if the first floor of the chamber R1, figure chamber R3 upstairs the heating air in the chamber R1 rises blow 4 extruded into blow 4 1, the louver 13 on the air supply side of the chamber R3 closes (see FIG. 27), so that dirty air generated on the lower floor side is prevented from flowing into the chamber R3 from the opening 1rc side. Is done.

When coming down the wind speed in after becoming a strong wind, air pressure in the building A and the louvers 13 of the air supply side Before that is open outside air enters the building A is going to rise. Since the air pressure inside and outside the louver 9 on the exhaust side becomes equal , the louver 9 eventually opens its blade 9a by rotating counterclockwise around the support shaft 9b as shown in FIG.

When the louver 9 on the exhaust side is closed , the louver 9 opens and the exhaust starts when the wind speed of the wind w suddenly decreases uniformly from the ground to above the building A, but the air pressure in the building A starts. because suddenly the trivial from the capacity of air space a, the air pressure in the building a is greater than one outer wind pressure of the outer wall surface 1 of a building a. At that time, air flows from the blowout 4 side to the respective openings 1a, 1b, 1c through the openings 1ra, 1rb, 1rc and the chambers R1, R2, R3. At this time, the blades 13a of the backflow prevention louver 13 rotate counterclockwise in FIG. Thereby, the dirty air in the blow-through 4 is suppressed from flowing into the chambers R1, R2, and R3.
As described above, natural ventilation is performed when the wind speed is low. In addition, backflow can be prevented under conditions where backflow occurs in the chamber. Outside air does not flow back from the exhaust port during strong winds.
(Example 2)

  In Example 1, the air supply side is a simple opening as a building ventilator. FIG. 5 is a longitudinal sectional view of the building of the second embodiment. 5 will be described with respect to the configuration and action different from FIG.

One of the outer wall surface 1 side of the opening 1a of the building A, 1b, 1c, is similar to the one outer wall surface 1 side opening of a building A shown in FIG. 1, the chamber R1, R2, provided respectively on the ceiling side of R3. The upper sides of the openings 1a, 1b, and 1c are covered with a ridge 1d. The heel 1d may be a protruding shoji.
Opening 1a, 1b, the 1c, backflow prevention louver supply air to prevent the outflow towards the room air to the outside is not provided.

In this embodiment, when the wind w is a normal wind speed at a low speed , the exhaust-side backflow prevention louver 9 is open, so that ventilation is performed in the same manner as in the first embodiment. That is, unlike the conventional example, the backflow of the air flow does not occur in the upper floor room R3.

  Thus, even if there is no ventilation opening on the other outer wall surface 2 in the ventilation chamber 6, the provision of the windbreak plate 8 and the louver 9 in the exhaust side opening 6 i is effective for the ventilation condition as in the first embodiment. Can contribute.

However, when the wind is strong, the air flow w7 flowing to the left through the chamber R1 as indicated by the arrow w7 becomes an upward flow as indicated by the arrows w8 and w9 when the air flow w7 flows through the opening 1ra to the blow-through 4. Since the louver 9 is closed, the air flow w10 entering the room R3 from the opening 1rc of the upper floor room R3 is discharged through the opening 1c. This embodiment is effective for ventilation of the entire building A when the wind speed of the wind w is low. If the louver 9 continues to be closed, the heat accumulation H is generated, but it stays at the upper part of the blow-through 4 and does not descend to the lower part. Therefore, when the wind speed of the wind w is reduced and the louver 9 is opened, the heat pool H is exhausted.
Compared to the conventional example shown in FIG.
(Example 3)

In each embodiment, a corridor 16 shown in FIG. 1 is provided just outside the openings 1rb and 1rc between the respective chambers R2 and R3 and the blow-through 4. The floor of the room R1 on the first floor and the floor surface FL of the atrium 4 are continuous through both sides of the opening 1ra. These openings 1ra, 1rb, and 1rc are usually provided with doors that can be opened and closed as opening and closing members. The opening / closing member is provided with a window that can be opened and closed together with the door.

  When the openings 1ra, 1rb, and 1rc are closed in such a configuration, the closed chamber is not ventilated because the exhaust from the exhaust louver 9 cannot be made through the blow-through 4. Means capable of individual ventilation of the chambers R1, R2, and R3 in such a state will be described.

The overall structure of the building A is the same as that shown in FIG. Each room R1, R2, R3 of the opening 1a, 1b, the outer 1c is provided with a supply and exhaust box shown FIG. 6, the whole in Figure 7 by reference numeral 17. 6 is a side sectional view, and FIG. 7 is a perspective view.

The upper louver 18 has the same configuration as the louver 9 described with reference to FIG. The front plate 14 b of the box-shaped windproof plate 14 provided as a windproof member is a plate material parallel to one outer wall surface 1 which is the front of the building A. Side plates 14c of plate material are provided at right angles to both ends of the plate material of the front plate 14b of the windbreak plate 14. This air supply / exhaust box 17 has a hollow hexagonal shape with a front plate 14b on the front side, openings 1a, 1b, and 1c on the back side, a backflow prevention louver 13 for air supply on the lower surface, a backflow prevention louver 18 for ventilation on the upper surface, and a side plate 14c. .

As described in the first embodiment, the backflow preventing louver 13 for supplying air suppresses the discharge of indoor air while taking in outside air in the backflow preventing state. The ventilating backflow prevention louver 18 discharges room air in the backflow prevention state, but prevents the outside air from being blown into the room when the wind speed increases. Then, the backflow prevention louver 13 for supply air and the backflow louver 18 for ventilation are opened and closed freely according to the magnitude of the wind force by the piece 12a (not shown in FIGS. 6 and 7) and are fully opened and fully closed. it can.
Such a supply / exhaust box 17 is provided on the outer side of each opening 1a, 1b, 1c near the ceiling of each chamber R1, R2, R3.
(Operation of the supply / exhaust box 17 when the openings 1ra, 1rb, and 1rc facing the vents 4 of the chambers R1, R2, and R3 are closed (except in the case of FIG. 34 (H2))

  FIG. 9 shows the state of the backflow prevention louver for ventilation (abbreviated as ventilation louver 18) 18 of the air supply / exhaust box 17 from the top to the bottom (abbreviated as open), backflow prevention (abbreviated as constant), forced closure (abbreviated as closed). ) Is the heading in the left column, and three states are described in the first column. And the state of the backflow prevention louver (abbreviated as air supply louver 13) 13 of the box 17 is forcibly opened from left to right (abbreviated as open), backwind prevention (abbreviated as constant), and forced closed (abbreviated as closed). Three states are described in the first line with the heading in the upper column.

There are nine combinations of the supply air louver 13 and the ventilation louver 18 as shown in FIG. 10, 32, 33, and 34, the respective cases shown in (a) to (i) are designated as the drawing numbers, and (i) to (i) are added to FIGS. Indicates the state. In each louver state, a case where the wind speed of the wind w is low and a case where the wind speed is high will be described.

As shown in FIG. 10A, the case of A in FIG. 9 in which both the air supply louver 13 and the ventilation louver 18 are forcibly opened will be described. When the wind speed of the wind w is low, the outside air that has passed through the air supply louver 13 enters the room R1 through the lower side of the opening 1a (which is described on the first floor of the building but the same applies to the higher floor) as indicated by an arrow a. In the room R1, the supply air goes to the back of the room R1. The air heated by a heat source such as office equipment, lighting, human body, etc., sequentially rises to the back side of the room R1 and then reverses at the back side of the room R1 to the opening 1a. And it is discharged | emitted outside through the ventilation louver 18 above the opening 1a as shown by the arrow b. Note that a part of the air flows outside through the ventilation louver 18 by rising from the supply louver 13 into the space 14a of the supply / exhaust box 17 (not shown).

In the case of b in FIG. 9, when the wind speed of the wind w is high, the wind w is blocked by the windbreak plate 14 of the air supply / exhaust box 17 and is not directly blown into the opening 1a. The function of not blowing the wind w of the air supply / exhaust box 17 directly into the opening 1 a is common to all the modes of the air supply louver 13 and the ventilation louver 18. Therefore, this description is omitted below. As shown in FIG. 10 (b 2) the wind speed becomes larger depending on the wind of the prevalence of wind w, air supply louver 13, air flow c blown from the ventilation louver 18 to the chamber R1, d occurs. The air pressure in the chamber R1 is pressurized by the blown air flows c and d and rises. Pressurized room air when the wind speed of the wind w decreases, outside as the air flow indicated by arrows e, f through the air supply louver 13, the ventilation louver 18 from 10 within the chamber R1 as shown in (a 3) Spill to Thereafter, after the air pressure in the chamber R1 is lowered, the state returns to the state shown in FIG.

As shown in FIG. 10B, when the air supply louver 13 is in the backflow preventing state and the ventilation louver 18 is open in FIG. 9B, when the wind speed of the wind w is low, the air supply louver 13 is opened and the ventilation louver is opened. The air flows a and b are the same as those in FIG. When the wind speed is increased in response to the prevalence when the wind speed of the wind w is greater in the case of B of FIG. 9, the air blown FIG. 32 (b 2) As shown in the air supply louver 13, the ventilation louver 18 to the chamber R1 Streams c and d are generated. The air pressure in the chamber R1 is increased by being pressurized by the blowing flows c and d. When the wind speed of the wind w decreases, the air supply louver 13 from 32 within the chamber R1 as shown in (b 3), flows out to the outside as the air flow indicated by arrows g, h through the ventilation louver 18. At this time, the air supply louver 13 has a direction in which the opening is reduced by the passing air flow, so that more indoor air is discharged from the ventilation louver 18 than the louver 13. Thereafter, after the air pressure in the chamber R1 decreases, the state returns to the state of FIG.

In strong winds the fate of the wind velocity, FIG. 32 (b 2), only up to 32 (b 3) shows inflow and outflow indoor side near the opening 1a of the one outer wall surface 1 side of the air into the chamber R1, the chamber The air pressure of the room air varies only slightly up to the back side opening 1ra where R1 is closed.
As shown in FIG. 32C, the case of FIG. 9C in which the air supply louver 13 is forcibly closed and the ventilation louver 18 is forcibly opened will be described.

Regardless of the wind speed of the wind w, outside air does not flow into and out of the air supply / exhaust box 17 through the air supply louver 13. When the wind speed of the wind w is low, the supply and exhaust of the room R1 from the ventilation louver 18 is hardly performed. In the process of increasing the wind speed of the wind w, the air to be introduced from the ventilation louver 18 is guided to the front plate 14b side of the space 14a by the blades 18a, so that it stays in the vicinity of the opening 1a and the wind speed decreases. The air in the vicinity of the opening 1a moves in the returning direction through the ventilation louver 18. Therefore, an effective ventilation effect cannot be expected. Only the air pressure in the chamber R1 varies.

As shown in FIG. 32 (D1), the case where the air supply louver 13 is forcibly opened and the ventilation louver 18 is in the backflow prevention state (fixed in FIG. 9) will be described. When the wind speed of the wind w is low, the ventilation louver 18 remains open. Through the air supply louver 13 that is forcibly opened, the outside air enters the room R1 through the lower side of the opening 1a as indicated by an arrow a. In the room R1, the air heated by a heat source such as office equipment, lighting, or human body rises below the ceiling on the back side of the room R1 and goes to the opening 1a. And as shown by the arrow b, it discharges | emits outside through the ventilation louver 18 above the opening 1a. A part of the air flows outside through the ventilation louver 18 by rising from the supply louver 13 into the space 14a of the supply / discharge box 17 (not shown). As described above, the air flow mode of FIG. 32 (D 1) is the case of A shown in FIG. 9 in which the air supply louver 13 and the ventilation louver 18 are forcibly opened when the wind speed of the wind w is low (FIG. 10 (A 1). )), And the case shown in FIG. 9 (FIG. 10 (B-1)) in which the air supply louver 13 is fixed in the backflow prevention state and the ventilation louver 18 is forcibly opened.

  FIG. 33 (d 2) shows a case where the wind speed of the wind w has increased in the case of d in FIG. 9 where the supply louver 13 is forcibly opened and the ventilation louver 18 is in the backflow prevention state (constant of FIG. 9). .

When the wind speed of the wind w increases, the ventilation louver 18 is closed by the air flow outside the ventilation louver 18. From the air supply louver 13, outside air enters the space 14 a of the air supply / exhaust box 17 as indicated by an arrow i. Here, although air pressure is applied to the inside and outside of the ventilation louver 18, the ventilation louver 18 is closed because the positive pressure generated on the outside of the ventilation louver 18 is larger than the positive pressure generated on the inside. On the other hand the air flow arrow i flowing into the supply and exhaust box 17 through the air supply louver 13 thereof with energy as it passes through the air supply louver 13 is depleted. The air flow indicated by the arrow i is diffused in the supply / exhaust box 17 and a part of the air flow indicated by the arrow i blowing on the ventilation louver 18 changes to a positive pressure and acts on the ventilation louver 18 in the direction of opening the ventilation louver 18. Since the positive pressure due to the air flow applied to the outside of 18 is greater than the positive pressure based on the air flow indicated by the arrow i applied to the inside of the ventilation louver 18 , the ventilation louver 18 remains closed. Thus, in the state where the ventilation louver 18 is closed and the air supply louver 13 is open, the chamber R1 is hardly ventilated. In this case , since the ventilation louver 18 is closed in the process of increasing the wind speed of the wind w, strong wind does not blow into the room R1. Further, the strong wind blown into the room through the air supply louver 13 is also attenuated by the direction of the blades 13a. The air pressure in the chamber R1 increases slightly. Such a phenomenon is limited.

  As shown in FIG. 33 (e), the case where the air supply louver 13 and the ventilation louver 18 are in the backflow prevention state (constant in FIG. 9) will be described. When the wind speed of the wind w is low, the air supply louver 13 and the ventilation louver 18 are kept open. Therefore, in this case, for example, in the case of A shown in FIG. 9, that is, the air flow louver 13 and the ventilation louver 18 are both forcedly opened, and ventilation is performed in the same flow of arrows a and b as in FIG. Is done.

In FIG. 33 (E1), when the wind speed of the wind w increases, as already shown in FIG. 33 (E2) , the air flow is forced open by the supply louver 13 and the ventilation louver 18 is closed. This is the same state as FIG. The air flow indicated by the arrow i is shown in FIG. 33 (E2). The explanation of FIG. 33 (E2) uses the explanation of FIG. 33 (D2).

As shown in FIG. 33 (f), the fixed case of FIG. 9 in which the air supply louver 13 is forcibly closed and the ventilation louver 18 is in the backflow prevention state will be described. Regardless of the wind speed of the wind w, the outside air does not flow into and out of the air supply / exhaust box 17 through the air supply louver 13. When the wind speed of the wind w is low, the supply and exhaust of the room R1 from the ventilation louver 18 is hardly performed. In the process of increasing the wind speed of the wind w, the opening degree of the ventilation louver 18 decreases, and closes when the wind speed exceeds a certain wind speed. As the wind speed of the wind w decreases, the ventilation louver 18 opens and the opening degree increases. Therefore, inflow and outflow of outside air into the room R1 is not allowed.
Figure 33 supply and exhaust box 17 in the state of (f) may be substituted for windbreak plate 8 and the exhaust backflow prevention louvers 9 for use in the exhaust of the overall ventilation of the building A.

As shown in FIG. 34G, the case of FIG. 9G in which the air supply louver 13 is forcibly opened and the ventilation louver 18 is forcibly closed will be described. Since the ventilation louver 18 is closed when the wind speed is low, the air flow in and out of the room passing through the air supply louver 13 is small both in and out, and the air pressure in the room R1 changes only slightly due to the fluctuation of the wind speed of the wind w. In a strong wind, the state is the same as in FIGS. 33 (E2) and (D2).

As shown in FIG. 34 (H1), the case where the air supply louver 13 is in the backflow prevention state (fixed in FIG. 9) and the ventilation louver 18 is forcibly closed (H in FIG. 9) will be described. In this case , it is the same as in the first embodiment. When the wind speed of the wind w is low, the ventilation louver 18 is closed, so that there is no air flow inside and outside the room that passes through the ventilation louver 18. Therefore , the air flowing into and out of the chamber R1 through the air supply louver 13 and the space 14a of the air supply / exhaust box 17 has a small amount and small kinetic energy, so the air supply louver 13 does not operate. When the wind speed of the wind w is high, the air pressure in the chamber R1 rises due to the air flow indicated by the arrow i trying to blow into the space 14a and the chamber R1 through the air supply louver 13. When the wind speed of the wind w in a state where the air pressure chamber R1 is rising is lowered, the air supply louver 13 by flow air from the inside through the air supply louver 13 there is a difference in the inside and outside air pressure of the air supply louver 13 to the outer side The opening becomes smaller. Therefore, the fluctuation of the air pressure in the chamber R1 is reduced. In this case, the entire building A can be ventilated by opening the opening 1ra. When the ventilation louver 18 is replaced with a plate material in FIG. 34 (H1), the windbreak plate 14 and the air supply louver 13 of the first embodiment are obtained.

As shown in FIG. 34 (h2), when the openings 1ra, 1rb, and 1rc are open, the opening 1rc, the room R3, the opening 1c, the space 14a of the air supply / exhaust box 17 and the air supply louver 13 are passed through the higher floor room R3. Then, the air supply louver 13 is closed by the air flow that is going to flow backward.

Figure 34 supply as shown in (i) the louver 13, in the case of re-9 ventilation louvers 18 are forced closed together, individually ventilated chambers R1 is not performed. In this case, the wind w is remarkably high, or corresponds to the end of work.
The description of FIG. 10, FIG. 32, FIG. 33, and FIG. 34 is mainly for the chamber R1, but the same applies to the chambers R2 and R3.
(Overall ventilation of the building when a windproof plate and a backflow prevention louver for exhaust are provided at the top of the building and a supply / exhaust box is provided at the supply side opening of each room)

  When the openings 1ra, 1rb, and 1rc between the rooms R1, R2, and R3 and the ventilator 4 are opened for individual ventilation as described above (excluding FIG. 34 (H2)), the floors R1, R2, and R3 are opened. The ventilation of the entire building A when the supply / exhaust box 17 is provided in the openings 1a, 1b, and 1c on the supply side of R3 will be described.

In FIG. 1, the openings 1 a, 1 b, 1 c communicating with the rooms R 1, R 2, R 3 on the front surface of the building A are covered with a windproof plate 14 and an air supply louver 13. An air supply / exhaust box 17 is provided instead of the air supply structure in which the windbreak plate 14 and the air supply louver 13 are combined.

Assuming that the air supply louver 13 shown in FIGS. 6 and 7 is in the backflow prevention state, it is possible to prevent backflow when the air is normally supplied with respect to the air supply / exhaust box 17 in the chamber R3 and flows backward in the direction opposite to the air supply direction. And且逆flow ceases can return to the air supply state is when, as already mentioned is air supply louver 13 in FIG. 9 (a constant), the ventilation louver 18 is closed (h).

The exhaust louver 9 in the best locations of the building A is closed for high winds based on wind w when being opened in a reverse flow preventing condition shown in FIG. 3 in the building A, the supply side air supply louver 13 streets chamber The airflow flowing to the blow-through 4 via R1 and R2 increases the air pressure in the blow-through 4. Since air flows from the blow-through 4 into the chamber R3 through the opening 1rc , the air flow closes the air supply louver 13 as shown in FIG. Therefore, the dirty air generated in the first and second floor rooms R1, R2, and R3 is prevented from continuing to flow into the third floor room R3.
11 and 12 show a configuration for ensuring the inflow and outflow of the air flow into the chamber in the air supply / exhaust box 17.

  The configuration of the air supply / exhaust box 17 is the same as described above. The space in the air supply / exhaust box is divided into an upper space 14a1 and a lower space 14a2 by an upper and lower dividing board 21 provided as an isolating member that divides the space vertically and an air guide member that guides the air flow.

The upper and lower dividing board 21 has a horizontal flat plate shape, and the upper space 14 a 1 and the lower space 14 a 2 are not communicated in the air supply / exhaust box 17. The upper and lower dividing boards 21 are extended into the chambers R1, R2, and R3. The extending length is limited to the indoor side from the openings 1a, 1b, and 1c of the chambers R1, R2, and R3. In this example, the length of the upper and lower dividing boards 21 extending from the openings 1a, 1b, 1c into the chambers R1, R2, R3 slightly exceeds the openings 1a, 1b, 1c from the front plate 14b of the supply / exhaust box 17. Up to the position.

  FIG. 12 shows the air flow in the chamber R1. The airflow flows as arrow a → m → n → o → b. At this time, since there is the upper and lower dividing board 21, there is an effect of ensuring the flow toward the back side of the room R 1 and the flow toward the ventilation louver 18 on the ceiling side.

According to the structure of the air supply / exhaust box, this box is equipped with a windproof plate for building exhaust and a backflow prevention louver for exhaust, individual ventilation of windows by a windproof plate and a backflow prevention louver for supply, partial opening of the building, and full opening. , Can be totally closed. If the windproof plate 14 is made of aluminum and the blades 18a of the ventilation backflow prevention louver 18 are formed of aluminum, the air supply / exhaust box 17 blocks the sunlight SL as shown in FIG. Can be prevented.
Example 4

  This embodiment relates to the structure of an air supply / exhaust member provided on the outer wall side of each chamber. FIG. 13 shows the configuration of the opening on the supply side for the building A of the room R1. The same applies to the chambers R2 and R3. The outer wall of the building A is a double skin curtain wall.

The opening between the floor R1f and the ceiling R1c on the outer wall surface 1 side of the chamber R1 is closed by a flat plate-like separating member 22 as a whole except for the upper and lower ends. The isolation member 22 is, for example, a sliding-in shoji. At the upper part of the separating member 22, an exhaust opening 22a is provided between the ceiling R1c and near the ceiling R1c. The bottom of the isolation member 22, the opening 22b for air supply until close on or between floor R1f the floor R1f is provided.

On the outside surface of the opening 22a (surface substantially the same as the outer wall surface 1) , outside air flows into the chamber R1 through the upper opening 22a by the air flow of the outside air, and the air pressure in the chamber R1 is higher than the outside air. When the airflow is large , a ventilation backflow prevention louver 23 that does not block airflow from the chamber R1 through the opening 22a is provided. On the outside surface of the lower opening 22b (substantially the same surface as the outer wall surface 1), the outside air is not prevented from flowing into the chamber R1 through the opening 22b, but the air in the chamber R1 flows out through the opening 22b. A backflow prevention louver 24 for supplying air that suppresses the above is provided. Opening 22a, the chamber R1 inner respective 22b, the exhaust-side damper (hereinafter, also referred to as upper damper) 25, supply air damper (hereinafter, also referred to as lower damper) 26 is provided. The dampers 25 and 26 open or close the openings 22a and 22b, respectively. The dampers 25 and 26 are flat plate blades pivotally attached to the respective edges of the openings 22a and 22b by hinges 25a and 26a. The dampers 25 and 26 are configured to take an open position facing the horizontal direction or a closed position facing the vertical direction by an operation member (not shown). The upper damper 25 opens to the indoor side and becomes horizontal. The lower damper 26 is an inward opening that moves in the opening 22b.

  Since such an air supply / exhaust configuration is configured on the outer wall surface 1 side of the building A, the outer wall surface 1 side in FIG. 1 or FIG. 5 has the configuration of FIG. 13 (the entire building is not shown). First, an operation when the openings 1ra, 1rb, and 1rc facing the blowout 4 of the chambers R1, R2, and R3 are closed will be described.

  When the openings 1ra, 1rb, and 1rc are closed, individual ventilation of the chambers R1, R2, and R3 is performed. FIG. 13 (a) shows the state of the louvers and dampers during individual ventilation. The upper damper 25 and the lower damper 26 are open. In the wind w of normal wind, outside air flows in as indicated by an arrow j through an opening 22b in which an air supply louver 24 and a lower damper 26 are open, and after circulating through the chamber R1, the upper damper 25 is open as indicated by an arrow k. It is discharged through the opening 22a and the ventilation louver 23. Since the ventilation louver 23 is closed during a strong wind, the wind blown into the lower opening 22b does not blow through the chamber R1.

The entire ventilation of the building A is performed in a state where at least one of the openings 1ra, 1rb, and 1rc of the rooms R1, R2, and R3 is open. In this example, the opening 1ra is open. As shown in FIG. 13B, the upper damper 25 is closed and the lower damper 26 is open. The air flow in the overall ventilation at this time is the same as that described in the first embodiment.
In FIG. 13 (c), the dampers 25 and 26 are closed, and ventilation of the entire building A and individual ventilation of the rooms R1, R2, and R3 are not performed.
(Example 5)

  FIG. 14 is a longitudinal sectional view of a building according to the fifth embodiment. The structure of the whole building is the same as that of the building shown in (Example 1) of FIG. 1 except for the air supply side. A configuration different from the building shown in FIG. 1 will be described below.

In FIG. 14, the opening 27 of each room R1, R2, R3 is provided in the one outer wall surface 1 side of the building A which the wind w blows. The opening 27 is provided on the ceiling side of each chamber R1, R2, R3. An air supply / exhaust device 28 is provided in each opening 27.
The air supply / exhaust device 28 can selectively perform individual ventilation of each room R1, R2, and R3 and overall ventilation of the building A.

15 and 16 are longitudinal sectional views of the air supply / exhaust device 28. The above-described opening 27 in FIG. 14 is divided into an upper opening 27a and a lower opening 27b. A lower side of the lower opening 27b is a window 31 partitioned by a horizontal member 29 that becomes an upper frame of the window. The opening 27 corresponds to a random part. For example, the window 31 is fitted with glass. A blind 32 is provided inside the horizontal member 29 .

The opening 27 is vertically divided by a horizontally extending partition member 33 that partitions the opening 27 up and down to form an upper opening 27a and a lower opening 27b. From the tip of the bottom plate 34a and the bottom plate 34a which projects outward and front plate 34b that rises from the partition member 33 is a member of the windbreak plate 34 constituting the wind box is a windbreak member. The front plate 34b is parallel to the outer wall surface 1 and has substantially the same shape and size as the upper opening 27a, and faces the upper opening 27a with a space 34c. Both ends of the space 34c inside the windbreak plate 34 are closed by a plate material parallel to the paper surface of FIGS. A backflow prevention louver 35 for individual ventilation is provided in the opened upper opening of the space 34c surrounded by the windbreak plate 34. The configuration of the ventilation backflow prevention louver 35 is a configuration in which the backflow prevention louver 9 described with reference to FIG. 3 (the louver provided in the exhaust opening for ventilation as a building) is not provided with the piece 12a. Therefore, the backflow preventing louver 35 for ventilation is closed when the wind speed is low due to the wind force that increases the wind speed of the wind w.

  The damper 36 is supported on the partition member 33 by a hinge 36 a having a center in a direction orthogonal to the drawing sheet. The damper 36 rotates around the hinge 36a to close the upper opening 27a in the vertical position and open the upper opening 27a in the horizontal position. The damper 36 has a wind guide action in a horizontal position, and outside air that has entered the room R1 from the lower opening 27b during indoor ventilation is blown through the upper opening 27a, the space 34c, and the backflow prevention louver 35 for ventilation without being blown into the room R1. It has a function to suppress The horizontal state of the damper 36 is maintained by a stopper (not shown) that prevents the damper 36 from rotating clockwise around the hinge 36a of the damper 36.

  A backflow preventing louver 37 for supplying air is disposed so as to block the lower opening 27b. The louver 37 has a function of suppressing the outside air from freely entering and the indoor air from flowing out.

17, 18 and 19 are schematic side sectional views of the backflow preventing louver 37 for supplying air. The blades 37a of the backflow preventing louver 37 for supplying air have a strip shape that is long in a direction perpendicular to the drawing sheet. Blade 37a is supported on both sides of the vertical frame constituting the swingably lower opening 27b in the direction of the support shaft 37b which is perpendicular to the plane of FIG. The support shaft 37b is in the middle of the width direction of the blade 37a (finding direction in FIG. 19). The large portion 37a2 separated by the support shaft 37b of the blade 37a is wider than the small width portion 37a1. The first moment due to gravity around the support shaft 37b is slightly smaller in the narrow portion 37a1 than in the large portion 37a2. As a result, the blade 37a rotates clockwise around the support shaft 37b. The rotation of the blade 37a is stopped by a stopper 37c.

As shown in FIG. 16, between the blades 37a is open in the air supply state regardless of the wind speed of the wind w. The stopper 37c may be provided near the support shaft 37b on the upper side of the narrow portion 37a1 of the blade 37a.

When the air supply backflow prevention louver 37 is in the backflow prevention state of FIG. 18 when the entire building A is ventilated or when the room R1 is individually ventilated , the airflow of the air supply is as indicated by the arrow q in FIGS. Thus, the blade 37a remains open only by increasing the clockwise moment about the support shaft 37b. Incidentally, the force experienced by the blade 37a by the air flow, the vanes table positive pressure becomes negative in the blade back, the blade 37a receives the same force at the front and back by the air stream. In FIG. 14, when an air flow is generated from the room R1 toward the outside, the blades 37a rotate counterclockwise around the support shaft 37b in FIG. The space between the opening frame 27b is also closed. Accordingly, the room air flows backward and is not discharged from the lower opening 27b.

Similar to the exhaust backflow prevention louver 9 shown in FIGS. 2, 3, and 4 of the first embodiment, an opening / closing device 12 including a piece 12 a is provided. The piece 12a in this example moves in the vertical direction. Except for the point that the piece 12a according to the first embodiment moves in the left-right direction, the constitutional action of the piece 12a is the same, and thus the description in the first embodiment is used for the description.
(Operation of Example 5)
(Whole ventilation)

As shown in FIG. 16, the damper 36 is closed via an operation member (not shown), and there is no air flow through the upper opening 27a. Chamber through the non preventing louver 37 for supply air which is opened to supply air forgive but reverse flow is suppressed as shown in FIG. 18 R1, R2, R3, blow 4, the air flow and ventilation chamber 6, an exhaust The air is exhausted through the backflow prevention louver 9.

When the exhaust backflow prevention louver 9 is closed by the strong wind, the air in the lower floor room R1 is directed to the lower opening 27b of the room R3 through the blow-off 4 and the upper floor room R3 as shown in FIG. In the opening 27, since the upper opening 27a is closed by the damper 36, when the indoor air is going to go outside through the lower opening 27b, the side of the blade 37a facing the room is pressed by the air flow, and the blade 37a is supported by the support shaft. Since the air supply backflow prevention louver 37 is rotated counterclockwise around the center 37b, no backflow occurs in the upper floor chamber R3. Therefore, dirty air from the lower floor room R1 is prevented from entering the upper floor room R3.
(Individual ventilation)

A case where the openings 1ra, 1rb, and 1rc between the chambers R1, R2, and R3 and the blowout 4 are closed will be described. Hereinafter, the description about the room R1 is the same for the rooms R2 and R3. At this time, the damper 36 is opened in the chamber R1 as shown in FIG. As indicated by the arrow q, outside air flows into the chamber R1 through the air supply backflow prevention louver 37. The damper 36 does not generate an air flow that tends to flow directly from the lower opening 27b to the upper opening 27a in the chamber R1. The air flow indicated by the arrow q based on the wind w is an air flow that is pushed into the room R1, and therefore proceeds to the lower side of the room R1 and the air heated by the office equipment, lighting, human body, etc. in the room R1 rises. It reverses to the ceiling side at the back of the advancing chamber R1 and proceeds to the upper opening 27a through the ceiling side, and is discharged as indicated by an arrow r through the upper opening 27a, the space 34c, and the exhaust backflow prevention louver 35 for individual ventilation. At this time, since the damper 36 is present, the air flow indicated by the arrow q is prevented from flowing into the chamber R1 from the lower opening 27b and then directly toward the upper opening 27a, so that the air flow indicated by the arrow r is secured.

  When the wind speed of the wind w increases, the ventilation backflow prevention louver 35 is closed. The air flow as the supply of the arrow q attenuates the velocity of the air in the chamber R1 because it is closed, so that only a part of the air in the chamber R1 is disturbed.

  According to this embodiment, ventilation of the entire building and individual ventilation of each room can be effectively performed, and switching between the whole ventilation and the individual ventilation is performed only by the damper 36, so that there is no troublesome operation.

  In the above, by operating the operation member of the damper 36 and the operation member such as the shoji that opens and closes the openings 1ra, 1rb, and 1rc of the chambers R1, R2, and R3, the shoji can be opened and closed without being aware of the opening and closing of the damper 36. Therefore, switching between general ventilation and individual ventilation is preferable.

In the above, even if the air supply backflow prevention louver 37 is forcibly opened as shown in FIG. 17, the action of individual ventilation is the same. The forced closing of the air supply backflow prevention louver 37 shown in FIG. 19 is used in bad weather such as wind and rain where the wind w is extremely strong. At this time, the exhaust by strong winds louver 9, ventilation louver 35 is not blowing strong winds into the building A so close.

(Example 6)
A specific configuration of each apparatus that supplies or exhausts air to the whole building or a part of the building will be described.
Figure 20 is a windbreak plate 8 and side sectional view of the exhaust back-flow prevention louvers 9 for buildings A whole of the exhaust, 21 is a horizontal sectional view. A six-cubic frame 8b is formed of a structural material that is integrally formed by arranging a frame material of an aluminum extrusion mold at the position of the ridgeline of the six-cubic space 8a. A front windshield 8d, which is a front plate, is fitted into a groove 8c on the inner periphery of a four-sided frame that is bent and configured by an upper frame, a lower frame, and a collar frame on the front side of the six-cubic frame 8b. A bottom windproof plate 8f serving as a lower plate is provided in the groove 8e provided on the inner periphery of the four-sided frame on the lower surface side of the six cubic frame 8b. Side windbreak 8g serving as a side plate parallel to the plane of FIG. 20 is in parallel across the plane of FIG space 8a 20 As shown in FIG. 21, the inner periphery of the four-way frame six cubic frame 8b at the position It is fitted in the side groove 8h. An exhaust backflow prevention louver 9 is provided on the inner peripheral side of the upper four-sided frame of the six-cubic frame 8b.

In the opening 6i between the ventilation chamber 6 and the space 8a , a four-sided frame is fixed to the housing, and a sliding screen 41 is fitted into the four-sided frame so as to be freely opened and closed. The external appearance of the upper part of the building A provided with such a three-dimensional windproof plate 8 and exhaust backflow prevention louver 9 is shown in FIG. 22 of a perspective view.

The windbreak plate 8 described above is at the highest position of the building A, and protrudes from a box-shaped surface on which the sash shoji 46 is provided. In FIG. 22, a shoji 46 is provided in the case where it is provided under the windbreak plate 8 as a light for the blow-off 4. In FIG. 22, (14) indicates a case where it is used at an intermediate position of the building A as a windbreak plate on the air supply side.
(Example 7)

FIGS. 23 and 24 show a configuration in which windproof plates, louvers, and the like for ventilation or exhaust provided at the positions of the windows of the rooms R1, R2, and R3 of the building A can be stored. The present invention is applied to the supply / exhaust box 17 shown in FIGS. The present invention can also be applied to the exhaust windbreak plate 8 and the air supply windbreak plate 14 .

Peripheral frame 18b for ventilation in the upper frame 42a of the four-way frame 42 backflow prevention louver 18 is pivotably mounted with a hinge 42a1 constituting the transom 23. The center axis of the hinge 42a1 is parallel to the upper frame 42a of the four-way frame 42. The ventilation backflow prevention louver 18 to indicate the trajectories r1 by a dotted line in FIG. 23, a position along the four sides frame 42 rotates from the horizontal position and horizontal position by the hinge 42a1 centered counterclockwise Can be taken. The ventilation backflow prevention louver 18 is supported by the upper frame of the four-sided frame 14e that holds the front plate 14b of the wind-proof plate 14 in the horizontal position.

The lower frame 42b of the four-way frame 42 constituting the transom, the peripheral frame 13b of the air supply backflow prevention louver 13 is pivotably mounted with a hinge 42b1. The center axis of the hinge 42b1 is parallel to the lower frame 42b of the four-sided frame 42. As shown by the dotted line in FIG. 23 , the backflow prevention louver 13 for supply of air can take a position along the four-sided frame 42 by rotating clockwise from the horizontal position around the hinge 42b1. . When the backflow preventing louver 13 for supplying air is in a horizontal position, downward rotation is stopped by a stopper (not shown) provided on the lower frame of the four-sided frame 14e holding the front plate 14b.

As shown in FIG. 24, the side plate 14c of the windbreak plate 14 is a side plate held by a four-sided frame 14d. The side plates 14c are pivotally connected to the flange frame 42c of the four-side frame 42 constituting the ranch by hinges 42c1 having a central axis in the vertical direction. As shown in FIG. 24 , the side plate 14c held by the four-sided frame 14d has a backflow prevention louver 13 for supplying air at a position orthogonal to the plane including the four-sided frame 42 parallel to the outer wall surface 1 and the plane including the four-sided frame 42, ventilation. The backflow prevention louver 18 for use is placed in an overlapping position.

The edge of the front plate 14b of the windbreak plate 14 is fitted and held in the groove 14e1 on the inner periphery of the four-sided frame 14e. Front plate 14b, a four-way frame 14e is 23, can take a position that overlaps in close proximity to the position and the four-way frame 42 shown in FIG. 24. In this example, the front plate 14b and the four-sided frame 14e are configured to take a parallel motion with respect to the four-sided frame 42 which is a random one. Various configurations are adopted as the parallel motion device.

As shown in FIG. 23, the upper end of the link 43 is pivotally attached to the upper part of the collar frame 42c of the four-way frame 42 by a pin 43a. The lower end of the link 43 is pivotally attached to the slider 43c by a pin 43b. The slider 43c is fitted in a guide groove 14f1 that is long in the vertical direction below the collar frame 14f of the four-way frame 14e so as to be movable up and down. The links 43 and 44 are pivoted by pins 45.
The upper end of the link 44 is pivotally attached to the upper part of the collar frame 14f of the four-way frame 14e by a pin 44a. The lower end of the link 44 is pivotally attached to the slider 44c by a pin 44b. The slider 44c is fitted in a guide groove 42c2 that is long in the vertical direction below the collar frame 42c so as to be movable up and down.

  The storage of the air supply / exhaust box 17 in this embodiment will be described. The engagement of the outer peripheral frame 18b of the ventilation backflow prevention louver 18 shown in FIG. 23 to the four-sided frame 14e is released. The ventilation backflow prevention louver 18 is rotated counterclockwise around the hinge 42a1 and overlapped with the upper half of the four-sided frame 42. The backflow prevention louver 13 for supplying air is rotated counterclockwise around the hinge 42b1 and overlapped with the lower half of the four-sided frame 42.

  As shown in FIG. 24, the side plates 14c are respectively rotated around the hinge 42c1 and overlapped via the air supply backflow prevention louver 13 and the ventilation backflow prevention louver 18 previously stored in the four-sided frame 42. As a result, the front plate 14b held by the four-sided frame 14e via the links 43 and 44 and the sliders 43c and 44c, which are members of the parallel motion device, is positioned in the space in front of the four-sided frame 42.

Finally, when the front plate 14b is moved toward the four-sided frame 42, the links 43 and 44 increase the crossing angle θ, and at the same time, the sliders 43c and 44c are guided by the guide grooves 14f1 and 42c2 and descend. As a result, the front plate 14b held on the four-sided frame 14e is overlapped on the ventilation louver 18, the air supply louver 13, and the side plate 14c held on the four-sided frame 14d.
In order to make the housed air supply / exhaust box 17 act, it is developed in the reverse order.

  In this embodiment, when the upper surface is closed with a plate material instead of the ventilation louver 18, it is applied to the air supply box provided with the windproof plate 14 and the air supply louver 13 in the first embodiment. Further, when the lower surface is closed with a plate material instead of the air supply louver 13, it is applied to an exhaust box provided with a box-shaped windproof plate 8 and an exhaust louver 9.

In the above description, the air supply / exhaust box 17 is built on the four-sided frame 42 of the opening of the building, but by using the four-sided frame 42 as a member constituting the air supply / exhaust box 17, the air supply / exhaust box 17 is unitized. The attachment to the building can be made only by fastening members. Therefore, attachment to a building becomes easy by unitization.
(Example 8)

  FIG. 25 is a horizontal sectional view showing attachment of the box-shaped windbreak plate 8 provided with the air supply / exhaust box 17 or the exhaust backflow prevention louver 9 to the existing frame to the existing frame. On the outer side of the frame 47 of the opening frame provided on the inner periphery of the opening (6i, 1a, 1b, 1c) of the building A, a protrusion 47a is provided in the vertical direction.

The attachment of the exhaust box having the windbreak plate 8 and the exhaust backflow prevention louver 9 shown in FIGS. 20 and 21 to the protrusion 47a will be described. The vertical frame 8i on the side along the building A of the exhaust box is a groove steel plate (material is aluminum) as a whole, and the flange 8j on one side is folded back at the tip 8j1, and the tongue 8j2 is overlapped with the flange 8j. . The width of the groove 8j3 formed by the tongue 8j2 is equal to the thickness of the protrusion 47a in the assembled state. The tip of the tongue portion 8j2 is bent downward in the drawing to form an introduction portion 8j4. In the state of the part, the mouth portion 8j5 which is the root of the introduction portion 8j4 is in contact with or close to the flange 8j.

Exhaust box, inserted from the mouth portion 8j5 of grooves 8j3 in the building A side protrusion 47a. Between the introduction portion 8j4 and the mouth portion 8j5 of the tongue portion 8j2 and the flange 8j, the protrusion 47a is pushed and expanded, and the protrusion 47a is strongly pressed by the flange 8j and the tongue portion 8j2.
In this way, the exhaust box can be attached to an exhaust opening of an existing building. Similarly, an air supply box and an air supply / exhaust box can be attached to the existing frame.

DESCRIPTION OF SYMBOLS 1 ... One outer wall surface 1a, 1b, 1c, 1ra, 1rb, 1rc ... Opening 1d ... 庇
2 ... The other outer wall
4 ... Blow-through 5 ... Roof 6 ... Ventilation room 6i ... Opening 8 ... Windproof plate 8a ... Space 8b ... Six cubic frame 8c ... Groove 8d ... Front windshield 8e ... Groove 8f ... Bottom windshield 8g ... Side windbreak 8h ... slot 8i ... saddle frame 8j ... flange 8j1 ... tip 8j2 ... tongue 8j3 ... slot 8j4 ... introduction 8j5 ... mouth
DESCRIPTION OF SYMBOLS 9 ... Backflow prevention louver for exhaust 9a ... Blade 9a1 ... Lower side part 9a2 ... Upper part 9b ... Support shaft 9c ... Four-sided frame 10 ... Rooftop 11 ... Stopper 12 ... Opening / closing device 12a ... Piece 13 ... Backflow prevention louver 13a for supply air Blade 13a1 ... Lower side portion 13a2 ... Upper side portion 13b ... Outer frame 14 ... Windproof plate 14a ... Space 14a1 ... Upper space 14a2 ... Lower space 14b ... Front plate 14c ... Side plate 14d ... Four-sided frame 14e ... Four-sided frame 14e1 ... Strip groove 14f ... Fence frame 14f1 ... guide groove 15 ... support shaft 16 ... corridor 17 ... supply / exhaust box
DESCRIPTION OF SYMBOLS 18 ... Backflow prevention louver for ventilation 18a ... Blade 18b ... Outer frame 21 ... Upper and lower dividing board 22 ... Separation member 22a, 22b ... Opening 23 ... Backflow prevention louver for ventilation 24 ... Backflow prevention louver for supply 25 ... Exhaust side damper (upper) Damper) 25a ... Hinge 26 ... Supply side damper (lower damper) 26a ... Hinge 27 ... Opening 27a ... Upper opening 27b ... Lower opening
28 ... Air supply / exhaust device 29 ... Horizontal member 31 ... Window 32 ... Blind 33 ... Partition material 34 ... Windproof plate 34a ... Bottom plate 34b ... Front plate 34c ... Space 35 ... Backflow prevention louver for individual ventilation
36 ... Damper 36a ... Hinge 37 ... Backflow prevention louver for air supply 37a ... Vane 37a1 ... Small width portion 37a2 ... Large portion 37b ... Support shaft 41 ... Shoji 42 ... Four-side frame 42a ... Upper frame 42a1 ... Hinge 42b ... Lower frame 42b1 ... Hinge 42c ... frame 42c1 ... hinge 42c2 ... guide groove 43 ... link 43a, 43b ... pin 43c ... slipper 44 ... link 44a, 44b ... pin 44c ... slipper
45 ... pin 46 ... shoji 47 ... saddle frame 47a ... projection A ... building R1, R2, R3 ... room R1f ... floor R1c ... ceiling FL ... floor surface H ... heat pool SL ... sunshine w ... wind w1, w1-1 w2, w3, w4, w5, w6, w7, w10 ... air flow w8, w9 ... upward flow θ ... crossing angle

Claims (16)

One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
A building having a natural ventilation device, wherein the exhaust backflow prevention louvers are arranged at substantially the same height as the top roof of the building. One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
A natural ventilator characterized by having a ventilation chamber above the roof on the top floor, and an opening facing the direction of the wind blown on one outer wall surface for exhaust in the ventilation chamber. Building that has. The exhaust backflow prevention louver has blades that are rotatably supported by a support shaft that is transverse to the wind direction, and the support shaft is closed or opened by the strength of the wind blowing toward the windbreak member. The building having a natural ventilation device according to any one of claims 1 to 2 , wherein a position relative to the blade is defined. The building having a natural ventilation device according to claim 3 , further comprising a blade rotation control device that takes a position in which the blade is opened and closed by wind force and a forced open or closed position. It has a chamber facing an opening provided on one outer wall surface side, and is provided with a backflow prevention louver for supplying air that is taken in by this air flow but is closed by an air flow from the indoor side toward the outside. A building having the natural ventilation device according to any one of claims 1 to 4 . One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
It has a chamber facing an opening provided on one outer wall surface side, and is equipped with a backflow prevention louver for supplying air that is taken in by this air flow but is closed by an air flow from the indoor side toward the outside,
There is a windproof member that forms a space communicating with this opening outside the opening of the chamber provided on one outer wall surface, and the windproof member flows into the chamber on the lower surface side, but does not allow the indoor air to flow backward from the chamber to the outside. A building having a natural ventilation device, which is a windproof member having a closed space having an opening with a backflow prevention louver for air supply to be suppressed . One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
The building has a room having an opening on one outer wall surface, and the opening in the building on the opposite side of the room having the opening on one outer wall surface is connected to the exhaust backflow prevention louver. An opening / closing member is provided in the opening, and an opening on one outer wall surface side ventilates the entire building when the opening / closing member is opened, and supplies or exhausts air to ventilate the room when the opening / closing member is closed buildings with natural ventilation apparatus according to claim <br/> to have. One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
One of the openings on the outer wall surface is a ventilation backflow louver that suppresses the inflow of outside air into the room or discharges the room air by the magnitude of wind power on the upper surface, a supply louver that supplies air to the lower surface, and a ventilation The building which has a natural ventilation apparatus characterized by having a wind-proof member which obstruct | occludes the space between a backflow prevention louver and an air supply louver with respect to the building exterior . 9. The natural ventilation device according to claim 8 , further comprising: a wind guide member that divides the backflow prevention louver for ventilation and the supply louver vertically in a windproof member and extends indoors beyond an opening on one outer wall surface side. Having a building. One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
An opening in the building opposite to this opening of the room having an opening on one outer wall surface side and communicating with the backflow prevention louver for exhaust has an opening and closing member,
One opening on the outer wall surface is provided separately on the ceiling side and floor side of the room, and the opening on the ceiling side is operated by the wind of outside air and closed when the wind is large, Closed when performing general ventilation, and opened by overlapping an upper damper when performing individual ventilation of the room. It opens when the outside air flows into the opening on the floor side, and the air in the room tends to flow outside. A building having a natural ventilation device, characterized by having a lower damper that is closed when not performing both general ventilation and individual ventilation together with a backflow prevention louver for air supply that is closed and an upper damper . A partition member that forms an upper opening and a lower opening by vertically dividing the opening of one outer wall surface, and a backflow prevention louver for air supply that is provided in the lower opening and can supply outside air but suppresses outflow of indoor air to the outside of the building A windproof member provided on the outer side of the upper opening and having an upper surface that opens and communicates with the upper opening through a space; and a windproof member that is provided in the opening on the upper surface of the windproof member and discharges the room air outside the building. The backflow prevention louver for individual ventilation that acts to close when the size becomes large, and the position where it is pivotally attached to the partitioning member and the upper opening is closed and the inner opening is opened to take the almost horizontal position, and the wind guide action at the horizontal position The building having a natural ventilation device according to claim 7 , wherein the building has a damper. The building having a natural ventilation device according to claim 11 , wherein the backflow prevention louver for supplying air is erected in parallel with one outer wall surface. One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
The members that supply or exhaust air are a front plate parallel to one outer wall surface, a side plate perpendicular to one outer wall surface, and a flat surface in a horizontal direction perpendicular to one outer wall surface. It has a lower air supply backflow prevention louver and an upper ventilation backflow prevention louver to form a hollow six-cube shape in the assembled state, and the side plate, the air supply backflow prevention louver, and the ventilation backflow prevention louver Are respectively pivotally attached to the edge of the opening provided on one outer wall surface so as to take a position parallel to and perpendicular to the one outer wall surface, and the front plate is positioned along the one outer wall surface and one outer wall surface side. A building having a natural ventilation device, wherein the building is connected to one outer wall surface by a parallel motion device so as to take a position parallel to the one outer wall surface away from the outer wall . The building having a natural ventilation device according to claim 13 , wherein a plate material is used instead of the backflow prevention louver for ventilation. 14. The building having a natural ventilation device according to claim 13 , wherein the building is replaced with a backflow prevention louver for supplying air to form a plate material. One outer wall surface having an opening;
The other outer wall surface that does not have an opening that allows ventilation on the opposite side with respect to one outer wall surface;
An exhaust opening that opens in the same direction as the opening provided on the one outer wall surface provided at the top of the building,
In a building having a multi-story natural ventilation device that has a space that becomes a ventilation passage from the opening provided on one outer wall surface to the opening for exhaust,
It has a hollow windproof member that forms a space communicating with the exhaust opening on the outside of the exhaust opening, and the windproof member has an opening on the upper surface,
And have a top opening to an exhaust backflow prevention louvers wind and the direction of air flow blown onto the air outer wall surface of it is discharged either outside the building inside the building acts to close the a large is the windbreak member And
A multi-story room having one opening provided on one outer wall side and the other opening provided with an opening and closing member in a space in the building;
A building having a natural ventilator, wherein the building communicates with the other opening of each of the rooms and has the space communicating with the opening for exhaust at the top .