JP3128566B2 - Buildings with natural ventilation - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a building capable of performing natural ventilation in a room by effectively utilizing a natural wind from the outside and a temperature difference or a pressure difference between the inside and outside of the building. .

[0002]

2. Description of the Related Art Recent buildings have high airtightness even if they are made of wood, and various types of indoor ventilation are being studied. Indoor ventilation includes natural ventilation and artificial ventilation. Natural ventilation can be broadly classified into wind ventilation, which is driven by wind pressure applied to the outer wall of the building, and gravity ventilation, which is driven by a difference in air density due to a temperature difference between the room and the outside.

[0003] Wind ventilation is a ventilation system in which a wind hits a building, and a positive pressure (push-in force) is generated on the windward side wall and a negative pressure (sucking force) is generated on the leeward side. To tell. Wind pressure is generated by this pressure, and the wind pressure changes greatly depending on the wind speed, and also differs depending on the windward or leeward side, the shape of the building, and the surrounding conditions of the building. How to apply wind pressure is indicated by a wind pressure coefficient. Wind ventilation is proportional to wind speed, and this difference in wind pressure coefficient is also an important factor affecting ventilation. If openings are provided on the leeward and leeward sides, the difference in wind pressure coefficient will be large and the ventilation will also be large.

[0004] Gravity ventilation refers to ventilation in which heavy outside air flows into the room from below, and light air in the room flows out from above to ventilate. That is, since there are various heat sources in the room, it is normal that the temperature is higher than the outside.
As a result, the air in the room expands and is light, and coexists at the boundary between the heavy air on the low-temperature side outside and the wall, so that the heavy outside air flows into the room from below, and the light air in the room flows out from above and ventilates. Is performed.

On the other hand, for artificial ventilation, a method using mechanical power for both supply and exhaust (first-type ventilation method), a method for supplying air by a blower but allowing exhaust to be performed naturally (second-type ventilation method), Exhaust air is supplied by a blower, but air is supplied naturally (type 3 ventilation).

In either method, ventilation is forcibly performed using mechanical force. However, if the air supply is not sufficient, the exhaust is not sufficiently performed. On the other hand, if the exhaust is not sufficient, the air supply is sufficient. Disappears. Either way, ventilation will not be effective. In this sense, the first type is a stable ventilation method. In the second and third species, the amount of ventilation greatly depends on the state of naturally occurring exhaust and air supply.

[0007] When the wind blows toward the exhaust port, the path of the wind ventilation and the path of the artificial ventilation are reversed, so that the exhaust is of course forced in the second-class ventilation method in which the exhaust is performed naturally. Even in the first and third-class ventilation methods, the ventilation volume decreases because the wind offsets the exhaust. Therefore, the position of the exhaust port is
It is necessary to think in relation to the wind direction of the land.

[0008] In such a ventilation method, an artificial ventilation using mechanical force can always provide an appropriate ventilation volume.
The power consumption of the driving source becomes enormous over a long period of time.
Therefore, there has been proposed a natural ventilation system in which some equipment is provided to enhance the ventilation effect without using power.

[0009] For example, a ventilation tube such as a roof ventilator is the most common one for this purpose, and mainly utilizes a suction force by external wind. That is, a negative pressure portion is created by wind power to suck indoor air.

[0010]

However, in the case of a ventilation tube such as a roof ventilator, special consideration must be given to construction work such as providing an opening on the roof of a building.

SUMMARY OF THE INVENTION It is an object of the present invention to obtain a building having an enhanced natural ventilation effect by using a window mounted on the building. Another object of the present invention is to provide a building that can be opened and closed naturally without using a special driving source.

[0012]

According to the first aspect of the present invention, there is provided a building for performing natural ventilation, wherein the building is provided with a window in an outer wall constituting portion of the building, and the building is provided with no wind or the building. In a building comprising a sash part opening means for opening a sash part of a window located on the leeward side of the window and a sash part closing means for closing a sash part of a window located on the leeward side of the building, the window,
Window frame, and attached to this window frame via a horizontal rotating shaft so as to be freely rotatable
A flat plate-shaped shoji part and an upper or lower part of the shoji part
Having a weight installed on at least one of the
A rotation axis includes the weight about the rotation axis.
The rotational moment pertaining to one center of gravity of the shoji
Set at a position where the rotational moment of the other center of gravity is balanced.
And no wind or building due to the action of the weight.
In the window located on the leeward side of the building, the shoji part is attached to the window frame.
Shoji opening means for opening at a predetermined angle
And the wind pressure received on the outer surface of the window located on the windward side of the building
And closing means for closing the sash portion .

[0013] The building according to the present invention comprises a shoji part opening means for opening a shoji part of a window located in a windless state or on a leeward side of the building, and a shoji part closing a shoji part of a window located on the windward side of the building. Part closing means. Here, the windless state is
It refers to a state where there is no wind (the wind power is 0) or a light wind state that is equal to or less than a predetermined value. Further, the state located on the leeward side includes a window located on the leeward side of the building or includes a case where the pressure is lower outside the building than inside the building. Therefore, for example, when there is no wind or when the air pressure on the leeward side of the building or the inside pressure of the building is higher than the outside air pressure, the sash portion of the window may be opened by the sash portion opening means. In such a case, if the window is opened, the air inside is effectively discharged, and natural ventilation is performed well. In addition, windows located on the windward side of the building indicate windows that receive air around the building,
This includes the case where the outside pressure is higher than the inside of the building. For this reason, when the window receives wind from the outside or the air pressure inside the building is lower than the outside air pressure, the sash portion of the window may be closed by the sash portion closing means. In this state,
By closing the window, the exhaust from the leeward side can be transmitted efficiently.

The building according to the present invention has an outer wall structure such as a house or a warehouse, and has a room (space) at least inside. Windows on the building are provided through the outer walls of the building for ventilation of the interior air. For example, a general window structure, a ventilation window structure, and an exhaust window structure are also included. Therefore, the sash portion of the window may be a plate-like material such as glass or plate. Such a supply / exhaust opening structure in which a shoji portion is disposed through the outer wall is generally called a ventilation window, but the window in the present invention refers to not only the ventilation window but also the illuminating window. Further, the side wall of the ventilation room provided on the roof of the building may be used.

[0015] Such windows are provided at each of the opposing positions in the outer wall component of the building. Thereby, the indoor natural ventilation effect is enhanced by effectively utilizing the negative pressure due to the natural wind, the pressure difference between the inside and outside of the room, and the like. The wind direction to the building may periodically change depending on the time, such as sea breeze or mountain breeze, depending on the location conditions. In a building set up in such a location condition, the above-mentioned window may be provided at each of the opposing positions in the outer wall component of the building. However, in many cases, the wind to the building changes. Therefore, windows as described above should be provided at a plurality of positions around the outer wall constituting portion of the building.

Therefore, in the building according to the second aspect of the present invention which performs natural ventilation, the building is provided with windows at a plurality of positions all around the outer wall constituting portion of the building, and is provided with no wind or A building provided with a shoji part opening means for opening a shoji part of a window located on the leeward side of a building and a shoji part closing means for closing a shoji part of a window located on the windward side of the building.
The window is a window frame, and the window frame is
A flat-plate-shaped shoji portion rotatably mounted, and the shoji portion
The weight installed on at least one of the upper and lower parts of the
Having the horizontal rotation axis as a center with respect to the rotation axis.
Rotating moment about one center of gravity of the shoji part including the weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where they meet, and by the action of the weight,
The window is located in the windless state or on the leeward side of the building.
Part is opened at a predetermined angle with respect to the window frame
Outside of the shoji part opening means and the window located on the windward side of the building
Occlusion of the shoji part due to wind pressure applied to the surface
Means .

The operation of the sash opening means and the sash closing means is performed by using the wind received at each window of the building as power.
Open or close the shoji depending on the balance of the shoji
You. However, in order to ensure the opening or closing operation of the individual windows of the building, the opening or closing operation may be triggered using the detection means.

[0018] That is, in the building to perform natural ventilation according to the invention described in claim 3, a building including a window in the outer wall structure of the building, each of the opposite outer wall structure of a building Wind detecting means for detecting the direction and / or the degree of the wind with respect to the wind, and based on the result of the wind detecting means, open the sash portion of the window located in the no wind or on the leeward side of the building, and In a building provided with a sash part opening / closing control means for closing a sash part of a window located on the upper side, the window has a window frame.
And this window frame is rotatably mounted via a horizontal rotating shaft.
Flat sash and a small upper or lower part of the sash
At least one of which is installed on one side,
An axis is a shoji including the weight about the rotation axis.
Moment of one center of gravity of the part and the other
At a position where the rotational moment of the center of gravity of the
It is, by the action of the weight, still air or buildings
The shoji part of the window located on the leeward side of
Open at a predetermined angle and located on the windward side of the building
The sash is closed by wind pressure applied to the outer surface of the window
And a shoji part opening / closing control means .

[0019] In the architecture to perform natural ventilation according to the invention described in claim 4, a building including a window in a plurality of positions of the entire circumference of the outer wall structure of the building, the building Wind detection means for detecting the direction and / or degree of the wind with respect to each of the outer wall components, and based on the result of the wind detection means, open the sash portion of the window located in a no wind condition or on the leeward side of the building. And a sash part opening / closing control means for closing a sash part of a window located on the windward side of the building.
The window is a window frame, and the window frame is
A flat-plate-shaped shoji portion rotatably mounted, and the shoji portion
The weight installed on at least one of the upper and lower parts of the
Having the horizontal rotation axis as a center with respect to the rotation axis.
Rotating moment about one center of gravity of the shoji part including the weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where they meet, and by the action of the weight,
The shoji part of the window located in the windless state or on the leeward side of the building
At a predetermined angle with respect to the window frame,
Due to the wind pressure applied to the outer surface of the window located on the windward side of the building,
And a sash part opening / closing control means for closing the sash part .

The wind detecting means disclosed in the present invention may be any as long as it detects the direction and / or degree of the wind with respect to each of the outer wall components. For example, the direction and degree of wind may be grasped by a wind vane or anemometer for the entire building, and the pressure difference between the inside and outside of each outer wall component may be individually determined by a pressure sensor etc. individually attached to each outer wall component. May be detected.

In addition to detecting the direction and / or degree of wind, any one or more of wind direction, wind, temperature, humidity, and weather may be detected to control the opening and closing of the sash. However, in an extremely severe weather condition such as a typhoon or heavy rain, a mechanism for locking the blockage of the sash portion may be provided. When the window is opened, it is to prevent rainwater from entering the room or incurring excessive wind into the room. In addition, a window that opens and closes while maintaining the balance of the rotational moment has the effect of preventing the sound due to the fluttering of the shoji part and the failure from occurring.

[0022] Thus, in the architecture to perform natural ventilation according to the invention described in claim 5, a building including a window in a plurality of positions of the entire circumference of the outer wall structure of the building, the building A meteorological condition detecting means for detecting any one or more of wind direction, wind force, temperature, humidity, and weather for each of the outer wall components, and a no wind condition or a leeward side of a building based on a detection result of the meteorological condition detecting means. The sash part opening and closing control means for opening the sash part of the window located at the side of the building and closing the sash part of the window located on the windward side of the building, and the detection result of the weather condition detecting means exceeds a predetermined set value. In such a case, a building with a shoji lock control means for fixing the shoji in a closed state is provided.
And the window is provided with a window frame and a horizontal rotation axis connected to the window frame.
A flat-shaped shoji portion rotatably attached to the
With a weight installed on at least one of the upper or lower part of the part
Having the horizontal rotation axis around the rotation axis,
Rotational moment relating to one center of gravity of the shoji part including the weight
And the rotational moment related to the other center of gravity of the shoji part
It is provided at a position where it is balanced , and
In windows without wind or on the leeward side of buildings,
Open the shoji at a predetermined angle with respect to the window frame.
With means to open the shoji part and the window located on the windward side of the building
Is a shoji part that closes the shoji part by wind pressure applied to the outer surface
And closing means .

The meteorological condition detecting means disclosed in the present invention means, like the wind detecting means, the wind direction, the wind force, the wind direction, the wind direction, the wind meter, the thermometer, the hygrometer, or the rain gauge as the whole building. Any of temperature, humidity, and the presence or absence of rain may be grasped. The wind direction, which is individually attached to each outer wall component,
The weather conditions for each of the outer wall components may be individually detected by any of a wind sensor, a temperature sensor, and a humidity sensor.

In the building as described above, natural wind power can be satisfactorily ventilated using natural wind applied to the outer wall of the building.

On the other hand, it is also possible to obtain a building that performs natural ventilation by paying attention to gravity ventilation using a difference in air density due to a difference in temperature between the inside and outside the room as a driving force. In buildings, the interior of the building is often divided into several rooms. Since the room has various heat sources, it is normal for the room to be hotter than the outside. For this reason, the air in the room expands and is light, and coexists at the upper part of the room with the heavy air on the low-temperature side outside as a boundary.

Therefore, in the building for performing natural ventilation according to the invention described in claim 6, the outer wall constituting portion of the building is provided at an upper position of at least one of the peripheral walls constituting the interior of the building. an upper window provided through, meet building including a lower window provided through the outside air and with the lower position of the at least one wall of the entire circumference of the wall constituting the interior of the building
The upper window, when there is no pressure difference between the room and the outdoor or when the indoor air pressure is higher than the outdoor air pressure, a sash portion opening means for opening the sash portion of the upper window; A sash portion closing means for closing the sash portion of the upper window when the pressure is lower than the atmospheric pressure , wherein the window is a window frame
And this window frame is rotatably mounted via a horizontal rotating shaft.
Flat sash and a small upper or lower part of the sash
At least one of which is installed on one side,
An axis is a shoji including the weight about the rotation axis.
Moment of one center of gravity of the part and the other
At a position where the rotational moment of the center of gravity of the
It is, by the action of the weight, still air or buildings
For windows located on the leeward side of the
Shoji opening means for opening at a predetermined angle,
The windows located on the windward side of the building
And a sash portion closing means for closing the sash portion .

That is, according to the present invention, when there is no difference between the indoor air pressure and the outdoor air pressure, or for example, when the air pressure inside the building is higher than the air pressure outside on the leeward side of the building, the sash opening means is used. As a result, the sash portion of the upper window is permanently open. In such a case, the air in the upper part of the room expands and becomes lighter, the air in the room is discharged to the outside from the upper window, and an amount corresponding to the discharged air enters the room through the lower window.
When the pressure inside the window or the building located on the windward side of the building is lower than the pressure outside the building, the sash portion of the upper window is closed by the sash portion closing means. Therefore, the air inside is not discharged from the outside of the room, and unnecessary air particles in the room due to the inflow of air from above are prevented from being disturbed. Further, when all the upper windows are closed, the indoor air is not discharged from the upper portion, so that it is difficult for outside air to enter the room through the lower windows. In such a case, if the lower window is also controlled to open and close in response to the upper window, indoor ventilation can be performed more effectively. Thus, the indoor natural ventilation effect is enhanced by effectively utilizing the convection of air in the room.

The operation of the shoji part opening means and the shoji part closing means may be performed using a power source such as a prime mover, or the action of the wind or the like received on each window of the building as a power. The sash part may be opened or closed depending on the balance. Further, in order to ensure the opening or closing operation of the individual windows of the building, the opening or closing operation may be triggered by using the detecting means.

According to a seventh aspect of the present invention, there is provided a building for performing natural ventilation, wherein the building is provided at a position above at least one of all the peripheral walls constituting the interior of the building through the outer wall forming portion. and an upper window, a building including a lower window provided through the outside air and with the lower position of the at least one wall of the entire circumference of the wall constituting the interior of the building, and the indoor and outdoor A pressure difference detecting means for detecting a pressure difference between the room and the outside based on the detection result of the pressure difference detecting means, when there is no pressure difference between the room and the outside or when the pressure inside the room is higher than the pressure outside the room, In a building having a sash part opening / closing control means for opening a sash part of a window and closing the sash part of the upper window when the indoor air pressure is lower than the outdoor air pressure , the window comprises a window.
Frame, and rotatably mounted on this window frame via a horizontal rotating shaft
Flat-shaped shoji part, and the upper or lower part of the shoji part
A weight mounted on at least one of the
An obstacle that includes the weight around the rotation axis
The rotational moment pertaining to one center of gravity of the
Provided at a position where the rotational moment related to the center of gravity of the
And the action of the weight causes no wind or building
In a window located on the leeward side of an object, the shoji part is opposed to the window frame.
Opening means for opening the shoji part at a predetermined angle
And the wind pressure received on the outer surface of the window located on the windward side of the building
And closing means for closing the sash portion .

The atmospheric pressure difference detecting means disclosed in the present invention includes:
What is necessary is just to detect the air pressure difference between the indoor and the outdoor. In particular, the air pressure difference at the position of the upper window that performs the opening / closing operation is detected. This air pressure difference may be of any type, such as one due to the effect of wind on the building or one due to the temperature difference between the inside and outside.

The sash part opening / closing control means performs an operation of opening the sash part at a predetermined angle with respect to the window frame when there is no wind or when the air pressure inside the window (opening) is higher than the air pressure outside the window (opening). The present invention discloses an operation for closing the sash portion when the pressure inside the opening is lower than the pressure outside the opening. This increases the natural ventilation effect.

As described above, windows mounted on buildings that perform natural ventilation such as wind ventilation or gravity ventilation include window frames,
It is preferable to select a window frame provided with a flat screen part that is rotatably attached to the window frame via a horizontal rotation shaft.

It is important that the horizontal rotating shaft is installed on the window frame via a bearing or the like in order to minimize friction caused by opening and closing the shoji part. This makes it possible to respond with high sensitivity under the influence of natural wind and gravity ventilation, with almost no force required to open and close the shoji part.

In the case where a separate drive unit is provided with a motor for driving the sliding door and a transmission mechanism for transmitting the drive, the window can be opened and closed with a small force. still,
In the case where the horizontal rotation axis is mechanically opened and closed by the driving unit, the horizontal rotation axis may not be limited to an equal position or an unequal position with respect to the shoji part.

In this case, the driving of the shoji portion may be performed according to the instruction of the operator. However, by combining the above-described detecting means and the control means for controlling the driving, the windless or air pressure inside the window is reduced. The air supply / exhaust window provided in the corresponding wind direction may be automatically closed when a desired wind speed is reached, when the air pressure is higher than the outside air pressure. In any case, since the horizontal rotating shaft is provided at a position where the rotational moment of the shoji part is substantially balanced, even a driving part using a small output motor can easily open and close the shoji part. .

As described above, it may be performed using a power source such as a prime mover, but from the viewpoint of maintenance costs and maintenance, etc.
The one that opens or closes the sash part is selected according to the balance of the sash part using the wind received by the windows of the building as power.

For example, by installing a weight to make the surface of the shoji part divided by the horizontal rotation axis uneven, the shoji part may be used when natural wind is blowing or when there is a pressure difference between inside and outside. The portion can be opened or closed by generating a force for rotating the portion. Thereby, even if a special driving source is not required, the sash portion is automatically opened by blowing the natural wind.

[0038] Preferably, the rotational moment related to one center of gravity of the shoji portion including the weight and the rotational moment related to the other center of gravity of the shoji portion are provided at a position where they are balanced.
The one provided at a position higher than the center of gravity of the two centers of gravity is selected.

In this method, both rotational moments are offset, and a horizontal rotational axis is installed at a position higher than the position of the center of gravity where both the centers of gravity are combined, and the sash is opened in a natural state according to the so-called "Yagirobee" principle. It is an opening mechanism that causes That is, the horizontal rotation axis is installed at a position higher than the position of the center of gravity where both the centers of gravity are combined, and the apparatus is stopped so that the horizontal rotation axis is directly above the position of the center of gravity. As a result, the sash portion can be opened when there is no wind or the like without any artificial or mechanical operation.

More preferably, the window is provided on a window frame, a flat-plate-shaped shoji portion rotatably attached to the window frame via a horizontal rotation shaft, and at least one of an upper portion and a lower portion of the shoji portion. The horizontal rotation axis has a rotation moment about one rotation center of the shoji portion including the weight, and a rotation moment regarding the other gravity center of the shoji portion around the rotation axis. Provided at a position to be balanced, by the action of the weight, in a window located on the leeward side of a windless state or a building, a shoji part opening means for opening the shoji part at a predetermined angle with respect to the window frame. A window provided on the windward side of a building is provided with a sash portion closing means for closing the sash portion by wind pressure received on the outer surface.

As still another preferred embodiment, the window has a window frame, a flat-plate-shaped shoji portion rotatably attached to the window frame via a horizontal rotating shaft, and an upper or lower portion of the shoji portion. Having a weight installed on at least one side, wherein the horizontal rotation axis is about the rotation axis, a rotation moment related to one center of gravity of the shoji part including the weight, and a rotation moment related to the other center of gravity of the shoji part. It is provided at a position where the rotational moment is balanced, and by the action of the weight, the sash portion of the window located on the leeward side of the windless state or the building is opened at a predetermined angle with respect to the window frame, There is provided a sash portion opening / closing control means for closing the sash portion by wind pressure received on an outer surface of a window located on the windward side of a building.

That is, in these inventions, the sash portion itself is in an open state in a natural state (for example, in a windless state), and rotates in a closing direction when wind is received from the outside. Therefore, in these inventions, the weight and the window structure themselves constitute a shoji part opening means, a shoji part closing means, and a shoji part opening / closing control means. The flat-plate-shaped sash portion rotatably attached to the above-described window frame via a horizontal rotating shaft has a simpler sash-portion opening / closing mechanism than a sliding-door sash portion. Air supply from outside can be used as a neutral zone near the horizontal rotation axis, the upper part of the rotation axis can be used for exhaust and the lower part can be used for air supply, and indoor ventilation can be performed well.

Here, if the opening operation of the shoji part is made unlimited, the operation becomes large, and the reaction operation due to natural wind or a pressure difference becomes slow. In addition, a large space requires a sufficient space for moving inside. For this reason, it is preferable to provide a stopper or the like for restricting the opening operation of the shoji part. This may be, for example, one that prevents the shoji part from opening beyond a predetermined angle. The opening (rotation) angle of the shoji part with respect to the window frame is
Various selections are made in a range where the wind can be favorably received when a natural wind blows. In the horizontal, even if natural wind blows, it can not be closed,
Conversely, at an angle almost close to the standing state, the opening width becomes narrow, and natural ventilation in the room is not performed well. Therefore, the inclination angle from the vertical is preferably selected from the range of 30 to 60 degrees. In addition, in order to close when a natural wind is blowing, the wide surface divided by the horizontal rotation axis can be inclined so that it is always outward. Considering the exhaust efficiency in the open state and the angle of the surface of the sash portion that receives wind from the outside, about 45 degrees is optimal.

If this stopper is provided with a contact portion that comes into contact with the sash portion in an opened state to an appropriate angle, the sash portion is pivotally moved within the angular range until it comes into contact with the stopper, and is opened and closed. I do. In addition, it is preferable to provide a buffer means for absorbing a shock when the shoji part comes into contact with the contact part of the stopper. For example, when the wind is strong, a large impact force or sound is generated when the sash portion moves in the opening direction toward the stopper and comes into contact with the sash portion, so that the cause of the window failure and the noise are reduced.

When a window which opens in such a natural state (no wind or leeward) is used, there is a problem that the window flaps in a strong wind. Only in such a case, the window is fixed (or locked). It is preferable to provide a sash part lock control means. In a normal state, ventilation is naturally performed without using power, so that energy consumption is reduced, and the control means is operated only when necessary, so that energy such as required electric power is minimized. is there.

The shoji part lock control means is for locking the shoji part in a closed state when a predetermined limit value (set value) of wind power or the like is exceeded based on the detection result of weather conditions such as wind power. Should be fine. Further, the limit value may be set as a set value of the control means by previously specifying a state in which it is preferable to close and fix the window under the influence of weather conditions such as wind power by an experiment or the like.

When the weather conditions such as wind force change and fall below a set value, it is preferable to release this fixed state and return to a normal natural state. This is because the building is properly ventilated by following changes in the natural state. Further, the actuation or release of the lock mechanism in the lock means does not operate immediately when the limit value such as wind power is exceeded, but only when it continues for a certain period of time or exceeds a larger critical value. Preferably, This is because the natural state changes every moment, and if the operation of the lock control means is performed frequently, the ventilation efficiency is reduced and wasteful energy is consumed.

In a strong wind such as a typhoon, a cushioning material may be provided between the sash portion and the window frame to buffer vibrations caused by severe opening and closing of the sash portion. Further, a lock mechanism may be provided on the shoji portion and the window frame so that the lock mechanism cannot be opened / closed in a strong wind when a typhoon or the like accompanies the wind, so that not only the wind but also the rain does not enter the room.

Further, a net may be provided between the window frame and the sash portion, or outside or inside the supply / exhaust window, in order to prevent insects from entering when the sash portion of the air supply / exhaust window is opened. In addition, when a large number of air supply / exhaust windows are provided adjacent to the outer wall of the building, adjacent sash parts are connected to each other, or when the sash parts are driven by a motor or the like, they are controlled in synchronization with each other, The opening and closing operations may be synchronized. In addition, in this case, if a mechanism for forcibly opening is installed, by opening all or a part of these air supply / exhaust windows at the time of fire, it is possible to use the window as a smoke exhaust window.

[0050]

DESCRIPTION OF THE PREFERRED EMBODIMENTS According to the present invention, in a building having a window on an outer wall constituting portion of a building, a shoji part opening means for opening a shoji part of a window located in a windless state or on a leeward side of the building. And a sash part closing means for closing the sash part of the window located on the windward side of the building. FIG. 1 is an explanatory view schematically showing a configuration of an example of a building that performs natural ventilation according to the present invention.

As shown in FIG. 1, when a natural wind blows against the building (10), a positive pressure area (11) is located on the windward side and a negative pressure area is located on the leeward side of the building (10). A pressure zone (12) is generated. Therefore,
Since the inside pressure of the leeward window is higher than the outside pressure, the flat-shaped sash (13) is in an open state, and the inside pressure of the leeward window is lower than the outside pressure. ,
The shoji part (13) is in a closed state. Thereby, the internal air flows out to the outside from the open window, and natural ventilation is performed well.

The wind to the building depends on the location conditions.
Like the sea breeze and the mountain breeze, the wind direction may periodically change depending on the time. In a building built in such a location condition, the windows described above may be provided at each of the opposing positions in the outer wall component of the building (for example, walls on the wind surface and wind surface) while paying attention to the wind direction. . However, in many cases, the wind direction to the building changes. Therefore, it is preferable to provide the above-described windows at a plurality of positions on the entire outer wall of the building.

FIG. 2 is an explanatory view showing the entire structure of another building for natural ventilation according to the present invention. As shown in Figures a and b, for example, a rooftop building that ventilates on the roof of a building (20)
(20 ') is installed, and a window (24) is installed along the entire circumference.
In these windows (24), there is no wind or the sash part of the window on the leeward side of the building is in the open state, and the sash part of the window on the leeward side of the building is in the closed state. By this operation, as in the example shown in FIG. 1, natural ventilation can be performed well even when the direction of the wind changes.

The opening of the sliding door and the closing of the sliding door are performed by using wind or the like received at individual windows of the building as power.
Opening or closing of the shoji part depending on the balance of the part
I do. Further, in order to ensure the opening or closing operation of the individual windows of the building, the opening or closing operation may be triggered by using the detecting means.

In the building shown in FIG. 1 and FIG. 2, the natural wind applied to the outer wall of the building makes it possible to properly perform natural wind power ventilation.

On the other hand, it is also possible to obtain a building that performs natural ventilation by focusing on gravity ventilation using the temperature difference between the indoor and outdoor areas (or the difference in air density) as a driving force. FIG. 3 is an explanatory diagram showing the configuration of yet another building that performs natural ventilation according to the present invention.
In a building, the space inside the building is often divided into several rooms. Since these rooms have various heat sources, it is normal for them to be hotter than the outside. As a result, the air in the room expands and becomes lighter, and moves upward. Therefore, in the upper part of the room, the air coexists with the heavy air on the low-temperature side outside and on the wall.

As shown in FIG. 3, for example, a three-story building (3
0) is provided with an upper window (31) and a lower window (32) provided in each of the rooms (30a) to (30d) through the outer wall constituting portion. The upper window (31) is opened when there is no difference between the indoor air pressure and the outdoor air pressure or when the indoor air pressure is higher than the outdoor air pressure, and the indoor window air pressure is lower than the outdoor air pressure. In this case, the sash portion of the upper window is closed. On the other hand, the lower window (3
In 2), it can be arbitrarily opened or closed. Usually, the lower window can be easily operated manually, but the upper portion (near the ceiling) is not easy. In general, the height and pressure difference do not matter in a general living room. However, in a large building such as a factory or a hall, the problem due to the height or heat is large, and the present invention is particularly effective in such a case. It is. Here, it is assumed that the wind is not blowing.

For example, when the room air is heated by various heat sources in the room as in the room (30a) on the third floor,
The air in the room is light at the top and heavy at the bottom. Therefore, the air in the upper part is naturally lighter than the outside air, and the air pressure in the room in this part is higher than the air pressure outside the room, so that the air is naturally discharged from the upper window (31a) in which the sash is opened. In addition, the lower window (3
2a). Similarly, in the left room (30c) on the first floor, the upper air is similarly discharged from the upper window (31c) and supplied from the lower window (32c) as much as the indoor air is lost.

Further, for example, in a room (30b) on the second floor,
If there is no heat source, the outside air may be hotter with the lower window (32b) closed. At this time, since the indoor air pressure is lower than the outdoor air pressure, the sash portion of the upper window (31b) is closed, and the outside air is shielded from the indoor air.

When the room temperature is high with the lower window (32b) closed, as in the right room (30d) on the first floor, the air pressure in the upper part of the room is higher than the air pressure outside the room. The sash is discharged from the opened upper window (31d), but the lower window (32d) is closed, so that the outside air is hard to enter the room.

As described above, in a building that performs natural ventilation, as a window to be attached, a windless state or a sash portion of a window located on the leeward side of the building is opened and a window located on the windward side of the building. A window that closes the sash portion of the window, and
When there is no air pressure difference between the indoor and outdoor, or when the indoor air pressure is higher than the outdoor air pressure, the sash portion of the upper window is opened,
What is necessary is just to provide the building with the window which closes the sash part of the upper window when the indoor air pressure is lower than the outdoor air pressure.

For example, in the window shown in FIG. 1 or FIG. 2, the opening operation of the sash portion and the closing operation of the sash portion may be performed by using a power source such as a prime mover. In consideration of the above, it is preferable that the sash portion is opened or closed by the balance of the sash portion using the wind received at each window of the building as power. However, in order to ensure the opening or closing operation of the individual windows of the building, it is preferable that the opening or closing operation is triggered by using the detecting means to limit the opening or closing operation of the shoji.

That is, the window sash portion that performs the opening operation or the closing operation by using the wind received by the window as a power is adopted, and the wind direction and / or the wind direction with respect to each of the opposing outer wall components of the building.
Or the degree of that is detected by the detection means, and based on this wind detection result, the opening operation of the shoji part of the window located in the no wind or the leeward side of the building, and the shoji of the window located on the leeward side of the building It is preferable to control the opening / closing of the sash portion of each window so as to limit the closing operation of the portion and to perform natural ventilation efficiently.

For example, an anemometer and an anemometer are installed as detection means on the roof of the building shown in FIG. 1 or FIG. 2 and if the direction and the degree of the wind (wind force, etc.) are detected, the results are used. Therefore, the opening operation of the window corresponding to the windward side is restricted, and
In order to remove the restriction of the opening operation of the window corresponding to the leeward side,
Control. Thereby, natural ventilation by natural wind is efficiently performed. In addition to detecting the direction and / or degree of the wind, the weather detection means may detect any one or more of the wind direction, wind, temperature, humidity, and weather to control the opening and closing of the shoji. Good. Furthermore, in an extremely severe weather condition such as a typhoon or heavy rain, a mechanism for not only restricting the closing operation of the sash part but also locking the closed state of the sash part by the lock control means may be provided. Regarding the restriction of the movement of the sash portion and the lock mechanism, it is preferable to employ a device provided with a command means so that the operator can arbitrarily perform the operation regardless of the presence or absence of natural wind.

The upper window of each room of the building shown in FIG. 3 also uses a power source such as a prime mover for the opening operation of the sliding door and the closing operation of the sliding door in consideration of energy saving and maintenance. It is more preferable to open or close the sash part by the balance of the sash part by utilizing the pressure difference between the inside and the outside received by the upper window of the building, than performing the sash part. In this case, in particular, when the weather condition is severe, for example, when rain or wind is strong, it is preferable to fix to the closed state. That is,
When rain or wind is equal to or greater than a predetermined value by the weather condition detecting means, the shoji part is fixed to a closed state by the lock control means in order to prevent flapping of the shoji part or intrusion of rain by the wind.

In particular, it is preferable to adopt an opening or closing operation using a difference in air pressure between the inside and outside of the window as the sash portion of the upper window of a large building. In this case, the pressure difference between the inside and outside is detected by the detecting means, and based on the detection result of the pressure difference, when there is no pressure difference between the room and the outside or when the pressure inside the room is higher than the pressure outside the room. It is preferable to control the opening and closing of the sash portion of the upper window by limiting the opening operation of the sash portion of the upper window and the closing operation of the sash portion of the upper window when the indoor air pressure is lower than the outdoor air pressure. This is because control by human power or the like is difficult.

For example, a pressure sensor is installed near the upper window of the building shown in FIG. 3 to detect a pressure difference between the inside and outside of the building. The opening operation is restricted, and when there is no pressure difference between the room and the outside or when the air pressure in the room is higher than the air pressure outside, the opening / closing control means controls the opening operation so as to eliminate the restriction. Thereby, gravity ventilation based on the difference in air density due to the temperature difference between the indoor and outdoor areas is efficiently performed. In addition to detecting indoor and outdoor air pressure differences, wind direction, wind power, temperature, humidity,
Any one or more of the weather may be detected to control the opening and closing operation of the shoji part. Further, in an extremely severe weather condition such as a typhoon or heavy rain, a mechanism for not only restricting the closing operation of the sash part but also locking the closed state of the sash part may be provided. This is because when rain or wind is strong, it is possible to prevent intrusion of rainwater or intrusion of wind into a room, and to prevent a failure of a movable portion of a window. Regarding the restriction of the movement of the sash portion and the locking mechanism, it is preferable to employ a device provided with a command means so that the operator can arbitrarily perform the operation regardless of the presence or absence of the atmospheric pressure difference between the inside and outside the room.

The following are specific examples of such a window (upper window). FIG. 4 is an explanatory view showing a configuration of an embodiment of a window installed in any of the buildings in FIGS. 1 to 3. FIG. 4A is a front view, and FIG. 4B is a side view showing the operation of a shoji part. is there. FIG. 5 is a side view of the shoji part of FIG. FIG. 6 is an explanatory view showing the structure of the opening / closing restricting means for restricting the opening / closing functioning also as a stopper for the sash portion of the window shown in FIG. 7A and 7B are explanatory views showing the configuration of a locking means for locking the closing of the sash portion of the window shown in FIG. 4, wherein FIG. 7A is a plan view and FIG. 7B is a sectional view.

FIG. 4 shows four windows in one set. A sash part (41) on a flat plate is rotatably attached to a window frame (40) mounted on an upright wall surface via a horizontal rotation shaft (42). The sash part (41) is moved from a vertical state (closed state) to a room side at an inclination angle of 45 degrees (rotation range) by stopper means (shown by a dotted line in FIG. 6) provided on the window frame (40). It can be tilted (rotated) freely.

As shown in FIG. 5, a balance weight (53) is attached to the upper end of the shoji part (41) via a mounting bracket (54) inside a protective cover (43) protruding inward. ) Is installed so that it can move in the horizontal direction.
2) is the shoji part (4) including these balance weights (53).
It is installed at a position where the rotational moment of the upper part and the rotational moment of the lower part of 1) are substantially balanced, and is provided at a position higher than the center of gravity where both centers of gravity are combined. Further, since the balance weight (53) is covered with the protective cover (43), dust and the like hardly adhere.

Therefore, since the horizontal rotating shaft (42) is provided at a position where the rotational moment is balanced, the shoji part (41) can freely rotate around the horizontal rotating shaft (42) with a small force.
In addition, the horizontal rotation shaft (42) is provided at a position higher than the center of gravity centering both centers of gravity with the horizontal rotation shaft (42) as a center. Furthermore, even when the wind hits from the inside of the shoji part (41) or when the outside air pressure is low, it is opened according to the so-called "Yagirobe" principle.

As an opening / closing restricting means for restricting an opening / closing angle of the shoji part (41) with respect to the window frame (40), a horizontal opening / closing shaft (42) installed near the horizontal rotation axis (42) of the shoji part (41) is used. A regulating arm (44) protruding from 46) and a buffer arm (45) having a T-shaped cross section attached to the distal end of the regulating arm (44). As shown in FIG. 6, the regulating arm (44) rotates around the opening / closing shaft (46) to which the drive of the motor (65) is transmitted by the gear box (66). The angle of rotation of the regulating arm (44) is changed from the position where it comes into contact with the upper part of the shoji part (41) in the vertical state (that is, the state where it abuts on the window frame (40) and closes the window). Can be rotated at a position exceeding a state inclined inward by 45 degrees (indicated by a dotted line), and the rotation angle of the shoji part is determined by the position of the opening / closing control means.

A shock absorbing member (61) made of elastic rubber is provided at the tip of the regulating arm (44), and absorbs a shock when it comes into contact with the sash (41). At the tip of the regulating arm (44), a buffer arm (45) is connected via a fulcrum (62).
Is installed. A spring member (63) having the other end fixed to the regulating arm (44) is attached to the end of the buffer arm (45), and the buffer arm (45) is urged by the spring member (63).
The two T-shaped shoulder ends of the arm protrude beyond the tip of the regulating arm (44). In addition, shock absorbing members (64) made of elastic rubber are also provided at both T-shaped shoulder ends of the buffer arm (45), and the tip of the regulating arm (44) comes into contact with the shoji (41). Before this, both shoulder ends of the buffer arm (45) come into contact with each other, and the impact of the contact is cushioned by the action of rubber and a spring. That is, these arms also serve as stopper means at the time of opening movement of the window.

The opening / closing (rotation) angle of the shoji part (41) with respect to the window frame (40) is limited by the regulating arm (44) and the buffer arm (45). For example, in the window provided in the building shown in FIG. 1 or FIG. 2, in the window corresponding to the windward side, the shock absorbing member (61) at the tip of the regulating arm (44) and the buffer arm (45)
By contacting the shock absorbing members (64) at the ends of both shoulders with the upper part of the horizontal rotating shaft (42) of the shoji part (41), the opening operation of the shoji part is restricted and the closed state can be maintained. . On the other hand, in the window corresponding to the leeward side, the regulating arm (44) is rotated so that the buffer arm (45)
Shoji part with shock-absorbing members (64) at both shoulder ends inclined at 45 degrees
If the upper part of (41) is brought into contact, the sash part is naturally opened, but its opening (rotation) angle does not exceed 45 degrees. This is because if the opening is too large, the operation of returning to the closed state becomes dull. Further, since the stopper means absorbs the impact, failure of each part and generation of rattling noise are prevented. In addition, by these opening / closing controls, natural ventilation by natural wind is efficiently performed. Note that the window in this example is closed when wind is applied from the outside, so that control to the closed state is usually unnecessary.

In the upper window provided in the building shown in FIG. 3, even when the indoor air pressure is lower than the outdoor air pressure, even if the stopper means itself is in the open position (45 degree position), It is closed naturally due to the pressure difference. In addition, when there is no pressure difference between the room and the outside or when the pressure in the room is higher than the pressure outside the room, it is opened due to the balance or the effect of the pressure.
The shock-absorbing member (61) at the tip of the and the shock-absorbing member (64) at both shoulder ends of the shock-absorbing arm (45) abut on the shoji (41), and up to a 45-degree inclined position, the shoji (41) Is controlled so as to suppress the rotation of. As a result, gravity ventilation utilizing the difference in air density due to the temperature difference (or pressure difference) between the room and the outside is efficiently performed.

In the window shown in FIG.
Locking means for maintaining the closed state is provided at the lower part of the device. As shown in FIGS. 4 and 7, a latch pin (71) is provided at the lower end of the shoji (41). A locking piece (72) for locking the locking pin (71) is provided on the slide shaft (73). Motor (76) by gearbox (77)
The slide shaft (73) to which the driving force is transmitted is moved in parallel with the window frame (40) by the guide roller (74), and the hook-shaped engaging portion (75) of the engaging piece (72) is engaged. The stopper pin (71) is hooked to lock the blockage of the sash (41).

That is, in this embodiment, in the normal state,
The open / close control means, which also functions as a stopper, is held at a position where the shoji part is rotated to a position of 45 degrees, and in a windless state or a leeward state, the shoji part is opened and rotates within a range of up to 45 degrees. are doing. Similarly, when the internal air pressure is high, it is open. On the other hand, since the windward window receives wind from the outside or the outside air pressure is higher than the inside, the shoji portion is maintained in the closed state by these actions. At this time, the stopper means is at the same position as the previously opened state. That is, the movement itself to the closed state is performed irrespective of the opening / closing control means by the action of the balance of the window, the wind or the pressure difference, or the like.

However, for example, when the wind or pressure difference is large due to a typhoon or the like, if the windows are opened and closed under the influence of the balance and the wind, there is a problem that the opening / closing operation is repeated and the sash part flaps. May cause. Also, if the window is opened in such a situation, naturally rainwater will enter the inside,
There is a problem that turbulence occurs in the room. For this reason, when the weather or the like is equal to or more than a certain limit value by the weather condition detecting means, the opening / closing control means also serving as the stopper means is operated, and the regulating arm is operated so as to rotate the sash part to the closing position. Rotate. By operating the lock means in this state, the sash portion can be fixed in a closed state.

With this lock mechanism, the closing operation of the sash portion under extremely severe weather conditions such as a typhoon or heavy rain can be ensured. Regarding the restriction of the movement of the shoji part and the lock mechanism, regardless of whether the operator has a natural wind,
It is preferable to employ one provided with a command means so that it can be arbitrarily performed.

[0080]

As described above, according to the present invention, it is possible to obtain a building capable of performing natural ventilation in a room by effectively utilizing a pressure difference between the room and the outside, for example, natural wind or convection of the room air. There is an effect that can be.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram schematically showing a configuration of an example of a building that performs natural ventilation according to the present invention.

FIG. 2 is an explanatory diagram showing the entire configuration of another building that performs natural ventilation according to the present invention.

FIG. 3 is an explanatory diagram showing the configuration of yet another building that performs natural ventilation according to the present invention.

FIG. 4 is an explanatory diagram showing a configuration of an embodiment of a window installed in any of the buildings in FIGS. 1 to 3;

FIG. 5 is a side view of a shoji part of the window shown in FIG.

6 is an explanatory diagram showing a configuration of an opening / closing restricting unit that restricts opening / closing of a sash portion of a window shown in FIG. 4;

FIG. 7 is an explanatory view showing a configuration of a lock means for locking the closing of the sash portion of the window shown in FIG. 4; FIG. 7A is a plan view;
FIG. b is a sectional view.

[Explanation of symbols]

(10)… Building, (11)… Positive pressure area, (12)… Negative pressure area, (13)… Shoji part, (20)… Building, (20 ′)… Rooftop building, (24)… window,
(30)… Three-story building, (31)… Top window, (32)… Bottom window,
(30a) ... room on the third floor, (31a) ... upper window, (32a) ... lower window, (30b) ... room on the second floor, (31b) ... upper window, (32b) ... lower window, (30c) ... The left room on the first floor, (31c) ... the upper window, (32
c) ... lower window, (30d) ... right room on the first floor, (31d) ... upper window, (32b) ... lower window, (40) ... window frame, (41) ... shoji (42)
… Horizontal rotation axis, (43)… Protective cover, (44)… Regulation arm,
(45): buffer arm, (46): opening / closing shaft, (53): balance weight (weight), (61): shock absorbing member, (62): fulcrum, (6)
3) Spring member, (64) Shock absorbing member, (65) Motor, (6
6) Gear box, (71) Lock pin, (72) Lock piece, (7
3)… Slide shaft, (74)… Guide roller, (75)… Key-shaped hook, (76)… Motor, (77)… Gearbox

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Takao Iwazuki 6-5-1 Nishi-Shinjuku, Shinjuku-ku, Tokyo Japan Design Co., Ltd. (72) Atsushi Suzuki 6-5- Nishi-Shinjuku, Shinjuku-ku, Tokyo 1 Nippon Sekkei Co., Ltd. (72) Tatsuro Shiobara, Inventor 2-27-3 Nishigotanda, Shinagawa-ku, Tokyo Azusa Sekkei Co., Ltd. (72) Hideo Hachi, 2-27-3 Nishigotanda, Shinagawa-ku, Tokyo No. Azusa Design Inc. (72) Inventor Kazuo Iwaki 550 Hayakawa, Takaoka City, Toyama Prefecture Inside Tateyama Aluminum Industry Co., Ltd. (72) Inventor Osamu Arayama 3-11 Nishi Shinjuku, Shinjuku-ku, Tokyo Tateyama Aluminum Industry Stock In-house (72) Inventor Masanori Hirata 3-2-11 Nishi-Shinjuku, Shinjuku-ku, Tokyo Tateyama Aluminum Industry Co., Ltd. (72) Inventor Yoshikazu Nomura 550 Hayakawa, Takaoka City, Toyama Prefecture Inside Yama Aluminum Industry Co., Ltd. (72) Inventor Kunihiko Ebitani 550 Hayakawa, Takaoka City, Toyama Prefecture Inside Tateyama Aluminum Industry Co., Ltd. (72) Atsushi Nakamura 550 Hayakawa, Takaoka City, Toyama Prefecture Inside Tateyama Aluminum Industry Co., Ltd. 56) References JP-A-5-194340 (JP, A) JP-A-5-248674 (JP, A) JP-A-6-82249 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , (DB name) E04B 1/70 E05F 1/00 E05F 1/02

Claims (7)

(57) [Claims] 1. A building having a window on an outer wall component of the building.
It is provided with a sash part opening means for opening a sash part of a window located on the leeward side of a building in a calm state or a sash part closing means for closing a sash part of a window located on the windward side of the building. Building
The window is pivoted through a window frame and a horizontal rotating shaft.
A flat-shaped shoji part that is freely mounted, and
With a weight installed on at least one of the
And the horizontal rotation axis is, with this rotation axis as the center,
Rotational moment about one center of gravity of the shoji part including weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where it fits, by the action of the weight, in the windless state or on the leeward side of the building
In the window located, the shoji part is predetermined with respect to the window frame.
Means to open at a given angle and the wind of the building
In the window located on the upper side, the shoji
A building for performing natural ventilation, comprising: a shoji part closing means for closing a part . 2. A building including a window in a plurality of positions of the entire circumference of the outer wall structure of the building, shoji portion opened to open the shoji of the window located on the leeward side of the still air or buildings Means and a sash part closing means for closing a sash part of a window located on the windward side of the building.
The window is pivoted through a window frame and a horizontal rotating shaft.
A flat-shaped shoji part that is freely mounted, and
With a weight installed on at least one of the
And the horizontal rotation axis is, with this rotation axis as the center,
Rotational moment about one center of gravity of the shoji part including weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where it fits, by the action of the weight, in the windless state or downwind side of the building
In the window located, the shoji part is predetermined with respect to the window frame.
Means to open at a given angle and the wind of the building
In the window located on the upper side, the shoji
A building for performing natural ventilation, comprising: a shoji part closing means for closing a part . 3. A building having a window on an outer wall component of the building.
And a wind detecting means for detecting a direction and / or a degree of the wind with respect to each of the opposing outer wall components of the building, based on a result of the wind detecting means, in a no wind condition or on a leeward side of the building. In a building provided with a sash portion opening / closing control means for opening a sash portion of a window located and closing a sash portion of a window located on the windward side of the building, the window has a window frame and a window frame. Rotation via horizontal rotation axis
A flat-shaped shoji part that is freely mounted, and
With a weight installed on at least one of the
And the horizontal rotation axis is, with this rotation axis as the center,
Rotational moment about one center of gravity of the shoji part including weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where it fits, by the action of the weight, in the windless state or on the leeward side of the building
The shoji part of the window located is predetermined with respect to the window frame.
At an angle and open outside the window on the windward side of the building
Opening and closing a shoji part that closes the shoji part by wind pressure received on the surface
A building for performing natural ventilation, characterized by comprising a control means . 4. A building including a window in a plurality of positions of the entire circumference of the outer wall structure of a building, for detecting the orientation and / or its degree of wind for each of the outer wall structure of the building wind Based on the result of the wind detecting means, based on the result of the wind detecting means, open the shoji part of the window located on the leeward side of the building or the leeward side of the building, and close the sash part of the window located on the leeward side of the building. In a building provided with opening / closing control means , the window is rotated through a window frame and a horizontal rotation axis around the window frame.
A flat-shaped shoji part that is freely mounted, and
With a weight installed on at least one of the
And the horizontal rotation axis is, with this rotation axis as the center,
Rotational moment about one center of gravity of the shoji part including weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where it fits, by the action of the weight, in the windless state or downwind side of the building
The shoji part of the window located is predetermined with respect to the window frame.
At an angle and open outside the window on the windward side of the building
Opening and closing a shoji part that closes the shoji part by wind pressure received on the surface
Building performing natural ventilation, wherein the control means Bei Eteiru it. 5. A building including a window in a plurality of positions of the entire circumference of the outer wall structure of the building, wind direction for each of the outer wall structure of the building, wind, temperature,
A meteorological condition detecting means for detecting at least one of humidity and weather, and, based on a result of the detection by the meteorological condition detecting means, open a sash portion of a window located in a windless state or on a leeward side of the building to construct a building. A sash part opening / closing control means for closing a sash part of a window located on the windward side of an object, and a sash for fixing the sash part to a closed state when a detection result of a weather condition detecting means exceeds a predetermined set value. In a building provided with a section lock control means , the window is rotated by a window frame and the window frame via a horizontal rotation axis.
A flat-shaped shoji part that is freely mounted, and
With a weight installed on at least one of the
And the horizontal rotation axis is, with this rotation axis as the center,
Rotational moment about one center of gravity of the shoji part including weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where it fits, by the action of the weight, in the windless state or downwind side of the building
In the window located, the shoji part is predetermined with respect to the window frame.
Means to open at a given angle and the wind of the building
In the window located on the upper side, the shoji
A building for performing natural ventilation, comprising: a shoji part closing means for closing a part . 6. An upper window provided at a position above at least one of the walls of the entire circumference constituting the interior of the building and penetrating the outer wall constituting portion of the building, and an entire window constituting the interior of the building. the bottom position of at least one wall of the circumferential wall a building including a lower window provided through the outside air communication, the upper window, if there is no pressure difference between the indoor and the outdoor or indoor A sash part opening means for opening the sash part of the upper window when the air pressure is higher than the outdoor air pressure, and a sash part closing means for closing the sash part of the upper window when the indoor air pressure is lower than the outdoor air pressure. Scented building
Te, the window, through the window frame, a horizontal shaft to the window frame rotated
A flat-shaped shoji part that is freely mounted, and
Yes a weight disposed on at least one of the parts or lower
And the horizontal rotation axis is, with this rotation axis as the center,
Rotational moment about one center of gravity of the shoji part including weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where it fits, by the action of the weight, in the windless state or downwind side of the building
In the window located, the shoji part is predetermined with respect to the window frame.
Means to open at a given angle and the wind of the building
In the window located on the upper side, the shoji
A building for performing natural ventilation, comprising: a shoji part closing means for closing a part . 7. An upper window provided at an upper position of at least one wall of the entire peripheral wall constituting the room of the building and penetrating the outer wall constituting portion, and a wall of the entire peripheral constituting the room of the building. at least one of the bottom positions of the wall a building including a lower window provided through the outside air communication with the pressure difference detection means for detecting a pressure difference between the indoor and the outdoor, the air pressure difference detection Based on the detection result of the means, when there is no pressure difference between the room and the outside or when the indoor pressure is higher than the outdoor pressure, the sash portion of the upper window is opened, and the indoor pressure is higher than the outdoor pressure. In a building having a sash part opening / closing control means for closing the sash part of the upper window when the height is also low , the window is rotated through a window frame and a horizontal rotation axis on the window frame.
A flat-shaped shoji part that is freely mounted, and
With a weight installed on at least one of the
And the horizontal rotation axis is, with this rotation axis as the center,
Rotational moment about one center of gravity of the shoji part including weight
And the rotational moment related to the other center of gravity of the shoji
It is provided at the position where it fits, by the action of the weight, in the windless state or on the leeward side of the building
In the window located, the shoji part is predetermined with respect to the window frame.
Means to open at a given angle and the wind of the building
In the window located on the upper side, the shoji
A building for performing natural ventilation, comprising: a shoji part closing means for closing a part .