JP3065914B2 - Ventilated structures - 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 having a ventilation structure which improves the durability of the building by ventilation and which is cool in summer and warm in winter.

[0002]

2. Description of the Related Art In recent years, in a building such as a general house, a heat insulating material is stretched inside an exterior material to improve a heat insulating property and an airtightness, thereby increasing a cooling / heating efficiency, achieving energy saving, and improving comfort. A living space is being obtained. By the way, when the heat insulating property and the airtightness are enhanced in this way, there is a possibility that the inside of the building is dewed and the wooden part is deteriorated, and the propagation of mold, mites and the like is promoted. Further, in the summer, hot air accumulated in the daytime heat insulating material may be dissipated into the room as nighttime radiant heat and felt unpleasant. These are mainly due to the lack of air permeability inside the building, depending on the arrangement of the heat insulating material. Therefore, between the heat insulating material and the exterior material, the upper and lower ends communicate with the outside. Architectural structures are being constructed in which a ventilation layer is provided to improve air permeability.

[0003]

However, in a building having the above-mentioned ventilation layer, air permeability is improved by air flowing through the ventilation layer. However, since the ventilation layer communicates with the outside at the upper and lower ends, the building is not exposed to sunlight. The warmed air is discharged to the outside as it is, and as a result, there is a problem that natural heat energy accumulated due to solar radiation is wasted, especially in winter. In addition, a decrease in heat insulating properties due to the formation of the ventilation layer was inevitable. In addition, the exterior wall structure of conventional buildings has insulation and airtightness throughout the year (regardless of the season).
Although constant, this was not only effective in some seasons, but sometimes counterproductive.

The present invention has been made in view of the above circumstances, and can achieve both contradictory characteristics of high heat insulation and airtightness, and high air permeability. As a result, in summer, indoors can be used from outside to outside through outer walls. In order to improve the cooling efficiency by discharging the heat flowing into the room and preventing the transfer of heat to the room, in winter, it prevents the heat from flowing out of the room to the outside through the outer wall, and the thermal energy inside and outside the room It is an object of the present invention to provide a ventilated structure capable of improving the heating efficiency by effectively utilizing the structure.

[0005]

SUMMARY OF THE INVENTION According to the present invention, an outer wall heat insulating material is provided via an air layer having a predetermined width inside an outer material covering the periphery of a building, and an inner material is provided inside the outer wall heat insulating material. Arranged, and while a floor material is disposed below the interior material, under the floor material is a ventilation structure building in which an underfloor space surrounded by a foundation is formed, An internal air layer having a predetermined width is formed between the outer wall heat insulating material and the interior material, and the air layer and the internal air layer are
The underfloor space can be communicated with the underfloor space via a first damper and a second damper which can be freely opened and closed, and the underfloor space communicates with the outdoors via an openable and closable third damper formed on the foundation. Enabled, said first damper
And the third damper are linked while exhibiting the same behavior
The main feature is that it can be opened and closed .

[0006]

In the case of the present invention, first, in the summer, by opening the first damper and the third damper, cool air under the floor caused by chill between the soil is ventilated to the air layer, and the outer wall heated by the solar radiation is heated. Cooling prevents the hot air from accumulating and releasing into the room. Further, by closing the second damper and closing the internal air layer, the heat insulation on the inner side of the wall is enhanced, and the discharge of cool air through the wall is prevented, thereby improving the cooling efficiency.

[0007] Further, by opening the third damper and opening the first damper and / or the second damper, the outside air flowing into the underfloor space via the third damper respectively becomes an air layer and / or an air layer. Ventilated into the internal air layer. Accordingly, the air permeability of the underfloor space, the air layer, and / or the internal air layer is improved, and the dew condensation in the underfloor space, the air layer, and / or the internal air layer is prevented.

On the other hand, in winter, by closing the first damper and the third damper to close the air layer and the underfloor space, the air warmed by the solar radiation and the geothermal heat stays in the air layer to keep the room warm. The heat insulation of the air layer and the underfloor space is enhanced, and heat radiation from the room is prevented. Further, by opening the second damper, warm air in the underfloor space due to geothermal heat is ventilated to the internal air layer, keeping the room warm and also warming the inside of the wall, thereby providing a heating effect by radiation.

[0009]

Embodiments of the present invention will be described below in more detail with reference to the drawings. FIG. 1 shows a first embodiment of the present invention, and is a cross-sectional view near the floor of a ventilation structure building. Reference numeral 1 denotes a foundation laid on the ground, on which a base 3 is supported via a packing 2 for maintaining airtightness, and on the outside (left side in the figure) of the base 3, a building is provided. Is supported at the lower end of the exterior material 4 covering the surrounding area. The exterior material 4 is provided with a base sheet 7 having windproof, waterproof and moisture permeability inside an outer wall 5 made of, for example, a mortar wall, a siding wall, a concrete wall, or the like via a ventilation layer 6 having a predetermined width. The lower end of the ventilation layer 6 is open to the outside.

An outer wall heat insulating material 9 is disposed inside the exterior material 4 via an air layer 8 having a predetermined width, and an interior material is provided inside the outer wall heat insulating material 9 via an internal air layer 10 having a predetermined width. (Wall material) 1
1 is provided. A joist 12 is horizontally supported inward on the base 3, and the floor material 1 is placed on the joist 12.
3 is disposed such that the edge thereof abuts on the lower end of the interior material 11. As a result, a room 14 surrounded by the interior material 11 is formed above the floor material 13, and an underfloor space 1 surrounded by the foundation 1 is formed below the floor material 13.
5 are formed.

Further, in the ventilation structure according to the present invention, a first damper 16 and a second damper 17 are provided at lower ends of the air layer 8 and the internal air layer 10, respectively. These dampers 16 and 17 are openable and closable as indicated by arrows A and B in the figure, and as a result, the air layer 8 and the internal air layer 10 are separated from each other by the dampers 16 and 17 to the underfloor space 15. It is possible to communicate with.

In addition, the foundation 1 has an outdoor and underfloor space 15.
Is formed, and the vent 18
Is provided with a third damper 19. The third damper 19 is openable and closable as shown by an arrow C in the figure, and as a result, the outside air and the underfloor space 15 can communicate with each other via the third damper 19.

Reference numeral 20 denotes a draining material which covers the outside of the ventilation port 18 from above to prevent rainwater or the like from flowing into the ventilation port 18, and reference numeral 21 denotes a heat insulating property between the room 14 and the underfloor space 15. Is an underfloor heat insulating material stretched on the lower surface of the floor material 13 in order to improve the temperature.

Next, the ventilation / insulation action of the ventilation structure having the above-described structure will be described for each season. First,
In summer, as shown in FIG.
6 and the third damper 19 are opened, and the second damper 17 is closed. When the first damper 16 is opened, as shown by reference numeral F ₁ in the drawing, cool air under the floor caused by the slab cooling heat is ventilated to the air layer 8 to cool the outer wall heat insulator 9, and the hot air in the outer wall heat insulator 9 is cooled. Accumulation and release of this hot air into the room 14 is prevented.

Furthermore, by opening the third damper 19, the outside air flows into the underfloor space 15 through the third damper 19 as indicated by reference numeral F _2. Since this outside air is also ventilated to the air layer 8 through the first damper 16,
The air permeability between the underfloor space 15 and the air layer 8 is improved, and dew condensation in the underfloor space 15 and the air layer 8 is prevented.

Further, by closing the second damper 17 and closing the internal air layer 10, the heat insulation of the internal air layer 10 is enhanced, and the discharge of cool air from the room 14 is prevented, and the cooling efficiency is improved. . Here, when the room 14 is not cooled, the second damper 17 is opened, and the cool air under the floor is taken into the internal air layer 10 so that the internal air layer 1 is not cooled.
0 may be cooled and dew condensation in the internal air layer 10 may be prevented.

[0017] Moreover, the ventilation layer 6 is formed between the outer wall 5 and the base sheet 7, and since the lower end is opened to the outside, outside air to the ventilation layer 6 as shown by reference numeral F ₃ It flows in and the air permeability of the exterior material 4 is improved. Therefore, accumulation of hot air and dew condensation on the exterior material 4 are also prevented.

On the other hand, in winter, the first damper 16 and the third damper 19 are closed and the second damper 17 is opened, as shown in FIG. By closing the first damper 16 and the third damper 19 and closing the air space 8 and the underfloor space 15, the heat insulation of the air space 8 and the underfloor space 15 is enhanced, and heat radiation from the room 14 is prevented. . Further, due to the closing of the air layer 8, the air warmed by the solar radiation stays in the air layer 8 to keep the room warm.

Furthermore, by opening the second damper 17, as shown by reference numeral F _4, warm air underfloor space 15 due to geothermal is vented to the inner air layer 10 is kept warm room. Here, by closing the second damper 17 and closing the internal air layer 10, the heat insulation of the internal air layer 10 may be enhanced, and heat radiation from the room 14 may be prevented.

As described above, according to the present invention, both of the contradictory characteristics of high heat insulation and airtightness and high air permeability can be realized, and as a result, in summer, heat transfer to the room is prevented. On the other hand, in the winter season, it is possible to provide a ventilation structure capable of improving the heating efficiency by effectively utilizing indoor and outdoor heat energy.

FIG. 4 shows a second embodiment of the present invention. In this embodiment, in addition to the above structure, the outer wall insulation 9
Is extended above the ceiling 30 of the room 14, so that
The interior of the ceiling is divided by the outer wall heat insulating material 9 into a roof side space 31 communicating with the air layer 8 and a ceiling side space 32 communicating with the internal air layer 10. Further, a cooling radiator 33 and a heating radiator (heating radiator / storage body) 34 are provided in the ceiling space 32 and the underfloor space 15, respectively.

In the case of this embodiment, in summer, the first damper 16 and the third damper 19 are opened, the second damper 17 is closed, and the cooling radiator 33 is operated. Then, the internal air layer 10 and the ceiling-side space 3
2, the temperature of the room 14 is reduced so that the interior material 11
And cooling from the surroundings by radiation cooling from the ceiling 30.

On the other hand, in winter, the first damper 1
The sixth and third dampers 19 are closed, the second damper 17 is opened, and the heating radiator 34 is operated. Then, the warm air heated by the heating radiator 34 passes from the underfloor space 15 to the ceiling space 32 through the internal air layer 10.
As a result, the room 14 is heated from the surroundings by radiant heating not only from the floor 13 but also from the interior material 11 and the ceiling 30.

That is, in this embodiment, the radiator 3
By adjusting the temperature of the plurality of surfaces surrounding the room 14 by using the floor material 13 and the floor material 13 in addition to the effects of the first embodiment.
Or, more uniform radiant cooling and heating can be performed as compared with conventional radiant cooling and heating via one of the ceilings 30.

Further, as shown by reference numeral 35 in FIG. 4, an upper damper (fourth damper) for communicating the outside with the roof side space 31 is provided so as to be openable and closable.
It is also effective to reduce the cooling load by opening 5 and discharging the once-through heat reaching the air layer 8 and the roof-side space 31 by the solar radiation to the outside from the upper damper 35.

The above dampers 16, 17, 1
For opening / closing of the radiators 9 and 35 and ON / OFF of the radiators 34 and 35, manual, electric or any other known means can be used. In addition, each of the dampers 16, 17, 19, 35
May be appropriately opened and closed in conjunction with each other via a known linkage mechanism.

Further, the first damper 16, the upper damper 35 and / or the third damper 18 can be automatically opened and closed so as to open at a predetermined temperature or higher and close at a temperature lower than the predetermined temperature. . In this case, the second damper 17 is connected to each of these dampers 16, 19, 35.
It may be automatically opened and closed in conjunction with.

Further, each of the dampers 16, 17, 18,
As the automatic opening / closing mechanism 35, for example, a device in which a temperature sensor is incorporated in a drive source (for example, a motor or the like) for opening and closing a damper, a shape memory alloy, or the like can be used. On the other hand, radiator 3
It goes without saying that the ON / OFF of 4, 35 can be similarly automated.

[0029]

As described above, according to the present invention,
Both high heat insulation and airtightness, and the opposite properties of high air permeability can be realized, and as a result, in summer,
It is possible to provide a ventilation structure capable of improving the cooling efficiency by preventing the transfer of heat to the room and improving the heating efficiency by effectively utilizing the heat energy of the room and the outside in the winter season. . In other words, in summer, the first Dan
Opening the par and third damper in conjunction
The cool air under the floor caused by the chill between the floors is ventilated to the air layer.
The outer wall heated by the solar radiation cools down and this hot air is stored.
Product and can prevent the release of this hot air into the room
You. Also, in this state, close the second damper and
Insulation on the inner side of the wall by closing the air layer
To prevent the release of cool air through the walls
It is possible to improve the cooling efficiency.

[Brief description of the drawings]

FIG. 1 is a sectional view showing the vicinity of under a floor of a ventilated building according to a first embodiment of the present invention.

FIG. 2 is a cross-sectional view of the vicinity of a floor under the ventilation structure, illustrating a ventilation / heat insulation effect in the ventilation structure according to the embodiment of the present invention.

FIG. 3 is a cross-sectional view of the vicinity of the underfloor portion of the ventilation structure for explaining the ventilation / heat insulation effect in the ventilation structure of the embodiment of the present invention.

FIG. 4 is a schematic sectional view of a ventilated building showing a second embodiment of the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 foundation 4 exterior material 6 ventilation layer 8 air layer 9 outer wall insulation material 10 internal air layer 11 interior material 13 floor material 15 underfloor space 16 first damper 17 second damper 18 ventilation port 19 third damper 21 underfloor insulation material 31 Roof-side space 32 Ceiling-side space 33 Cooling radiator 34 Heating radiator (heating radiator for heating) 35 Upper damper (fourth damper)

──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Osamu Tsuji 1-23-3 Oi, Shinagawa-ku, Tokyo Fukubi Chemical Industry Co., Ltd. Tokyo Branch (72) Inventor Hidetoshi Sato 1-23rd Oi, Shinagawa-ku, Tokyo No. 3 Fukubi Chemical Industry Co., Ltd. Tokyo Branch (56) References JP-A-1-127744 (JP, A) JP-A-3-129608 (JP, U) JP-A-6-40116 (JP, U) ( 58) Field surveyed (Int.Cl. ⁷ , DB name) E04B 1/74 E04B 1/70

Claims (11)

(57) [Claims] 1. An exterior wall heat insulating material is disposed inside a exterior material covering the periphery of a building via an air layer having a predetermined width, an interior material is disposed inside the exterior wall heat insulator, and the interior material is provided. A floor structure is provided below the floor material, and a floor space below the floor material is formed under the floor surrounded by a foundation, between the outer wall insulation material and the interior material. An internal air layer having a predetermined width is formed, and the air layer and the internal air layer can communicate with the underfloor space via a first damper and a second damper that can be opened and closed, respectively, and the underfloor space, through said third damper being formed freely opened and closed to the base is an outdoor communicable with, and the first damper and the third damper, similar
A ventilated building characterized by opening and closing in conjunction with its behavior . 2. The first damper and the third damper.
The par opens at a predetermined temperature or higher, and
Automatically opens and closes to close
Item 7. A ventilation structure building according to item 1. 3. The first damper according to claim 1 , wherein
While exhibiting the opposite behavior to the par and the third damper,
Open in conjunction with the first damper and the third damper.
3. The ventilation structure according to claim 1, wherein the ventilation structure is closed.
Built architecture. 4. The second damper automatically opens and closes.
The ventilation structure building according to claim 3, characterized in that: 5. A predetermined width communicating with the outside in said exterior material.
2. The air-permeable layer of claim 1 is formed.
The ventilation structure building according to any one of the chairs 4. 6. A radiating heat storage element for heating is provided in the underfloor space.
6. The method according to claim 1, wherein
The ventilation structure building according to claim 1. 7. The building according to claim 7, wherein said outer wall heat insulating material is provided on a ceiling of said building.
It is extended to this, by the outer wall insulation,
A roof-side space communicating with the air layer, and the internal air layer
It is divided into a communicating ceiling space
The ventilation structure according to any one of claims 1 to 6.
Kimono. 8. A cooling radiator is provided in the space on the ceiling side.
The ventilation structure according to claim 7, wherein the ventilation structure is provided.
Building. 9. The roof device according to claim 8, wherein the roof side space is a fourth die which can be freely opened and closed.
It is characterized by being able to communicate with the outside through the bumper
The ventilation structure building according to claim 7 or 8, wherein 10. The fourth damper comprises a first damper.
With the first damper while exhibiting the same behavior as the damper.
The ventilation structure according to claim 9, wherein the ventilation structure is opened and closed by moving.
Built architecture. 11. The fourth damper automatically opens and closes.
The ventilation structure building according to claim 10, characterized in that: