JP2013113471A - Underfloor structure of building - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an external insulation foundation structure that can be constructed in a short period without requiring skillful technique, and to provide a method of constructing the same.SOLUTION: In the external insulation foundation structure, a heat insulator is embedded in a riser part of the foundation, and a sectional width of concrete of a raised part of the foundation on the outside of the heat insulator is 20 mm or more. An outer frame erected on leveling concrete is provided with a space securing member for securing a space of a predetermined width with the heat insulator. Reinforcements are arranged on the space securing member and tied with binding bars. The heat insulator is fitted with fasteners to hold the space securing member with the outer frame. An inner frame is erected on the pressure-resistive plate after pressure-resistive plate concrete is cast. Concrete is cast into gaps between the heat insulator with both the frames. The method of constructing the external insulation foundation structure is also provided.

Description

The present invention relates to an underground structure of a building that effectively collects warm air and cold air under the floor of a building and uses them for indoor air conditioning.

In the ground at a certain depth from the ground surface, the temperature difference is small throughout the year, and it is cooler than the ground surface in summer and hotter than the ground surface in winter.
Therefore, conventionally, geothermal energy with a small temperature difference is obtained throughout the year, and cool air in the summer and warm air in the winter are circulated in the building to provide cooling and heating. An invention has been made.
For example, in Patent Documents 1 and 2 below, through underground pipes buried in the ground and a cruciform layer provided in the underfloor space, the air inside and outside the building and the underground with a small temperature difference throughout the year. An air conditioning system for a building using geothermal heat that exchanges air and supplies cold air in the summer in the ground and warm air in the winter in the interior of the building is disclosed.
According to the present invention, air in the ground that is cold in summer and warm in winter can be obtained from underground pipes buried in the ground, and can be used for cooling and heating.

JP 2001-116291 A JP 2000-097586 A

However, in the inventions according to Patent Documents 1 and 2, since the stones are spread directly on the ground surface of the foundation part of the building, the underfloor is not insulated and the heat insulation efficiency is low.
Moreover, in order to embed a pipe having a certain depth or more in the ground, there is a problem that the construction cost becomes high.

Therefore, the present invention provides an underfloor structure of a building that can efficiently extract from the underfloor space by using the geothermal energy stored in the crushed stone as warm air or cold air after increasing the heat insulation efficiency of the underfloor structure. It is to be an issue.

In order to solve the above problems, the present invention takes the following technical means.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally along the recess formed in the concrete surface,
It is an underfloor structure of a building characterized by crushed stones spread from above the perforated pipe.

The present invention relates to an underfloor structure for collecting crushed stone in an underfloor space of a building in which the floor surface of the underfloor space is covered with concrete, and collecting geothermal energy stored in the crushed stone as warm air and cold air using a porous tube. It is.
The underfloor space in the present invention is located at the deepest part of the building, for example, if it is a building having an underground floor, it means a space located further below the lowermost floor, It means a space where concrete has been placed (note that concrete can be precast as well as cast in place).
Therefore, the foundation structure of a building is not ask | required, For example, a solid foundation or a cloth foundation may be sufficient.
However, the side surface (wall surface) and top surface (ceiling) other than the floor surface of the underfloor space need not be concreted, but it can also be a space in which concrete is entirely placed, Thus, when the heat storage and cold storage effects of geothermal energy are improved, it is desirable to place concrete on the entire surface.
In addition, regardless of the presence or absence of concrete placement, one or more of the floor surface, the side surface (wall surface), and the top surface (ceiling) of the underfloor space can be provided with a heat insulating structure such as a heat insulating material. .
In particular, the heat insulation structure for the top surface (ceiling) part has a temperature difference between the bottom floor and the underfloor space because the heat of the bottom floor is transferred from the bottom floor of the building through the floor surface to the underfloor space. In this case, this is to prevent warming and cold air from being stored and stored in the underfloor space from being warmed.
The distance (depth) from the ground surface to the floor of the underfloor space varies depending on the number of basement floors of the building, so it is difficult to specify the required distance (depth), but the larger (deeper) is It is easy to obtain geothermal energy with a small temperature difference throughout the year.

The perforated pipe in the present invention is a pipe that is used for collecting warm air and cold air in the underfloor space and supplying it to the building, and is piped in the underfloor space.
Therefore, the perforated pipe is provided with holes for collecting warm air and cold air, for example, one place each on the lower side and one side, and four places on the upper side.
This hole only needs to collect warm air and cold air, and can be appropriately adjusted regardless of the position, number, and size of the holes.
The range in which the perforated pipe is to be piped is preferably uniformly distributed over the entire floor surface of the underfloor space, but the piped range can be adjusted as appropriate.
In addition, since the porous tube only needs to collect warm air and cold air in the underfloor space and supply it to the building, there is an end of the porous tube in the underfloor space. The pipe that is configured to be connected to the pipe to be supplied and supplies the air outside the underfloor space is provided in the underfloor space separately from the porous pipe.

The pipe for supplying air outside the underfloor space may be piped as a pipe for supplying room air from inside the building, or may be piped as a pipe for supplying outside air from outside the building.
When supplying indoor air into the underfloor space from inside a building, for example, a perforated pipe is installed near the roof of the building (the back of the ceiling) or the ceiling of the stairwell, and the warm air inside the building is collected from the perforated pipe. And the said warm air can also be supplied in underfloor space.
In this case, for example, the air in the building that has become warm during the day is supplied to the underfloor space to heat the crushed stone and store it, and the heat is stored when the temperature in the building at night falls. Warm air can be collected from the crushed stone in the underfloor space and supplied into the building.
In addition, the means for supplying outside air from outside the building is to install an opening (for example, a window, etc.) in a part of the underfloor space without depending on the pipe, and open and close this opening to open the outside air in the underfloor space. You may make it supply to.
Furthermore, a plurality of these means can be used in combination.
In order to supply warm air and cold air collected by the perforated pipe into the building, the perforated pipe is provided with a fan such as a ventilation fan.
In addition, a fan may be provided in the pipe | tube side which supplies warm air and cold air in a building, and may be provided in the terminal of the porous pipe connected with the said pipe | tube.

The perforated pipe has a supply pipe that supplies indoor air in the building into the underfloor space, and is connected to the end of the perforated pipe that is connected to the underfloor space. May be.
In this case, the pipe piped from the building to the underfloor space is connected to the porous pipe in the underfloor space and connected to the pipe piped from the underfloor space to the building. Without being closed, it is configured as a continuous pipe in the building → under the floor space → in the building → under the floor space, and the indoor air and the under floor air can be circulated.

The apertures of the perforated pipes may all be the same, or the apertures can be changed depending on the place where piping is performed.
Of the whole perforated pipes, the warmer air is smaller (thin) the diameter of the perforated pipe close to the outlet side supplying air from the underfloor space into the building compared to the perforated pipe far from the outlet side. Efficiently collects cold air and supplies it into the building (a large amount of warm air and cold air can be supplied into the building with the power of a small fan).

Crushed stone is spread over the perforated pipe.
The crushed stone in the present invention is not intended to limit the size because the upper limit and the lower limit of the size are not meaningful, but it is easy to use stones that are crushed into granules having a maximum diameter of about 100 to 120 mm. .
However, crushed stones spread around the perforated pipes have a small maximum diameter and are close to sand in order to avoid the risk of entering the perforated pipes from the holes provided in the perforated pipes and blocking the holes themselves. Undesirably, it is desirable to use a crushed stone having a maximum diameter of about 20 to 80 mm.
Furthermore, instead of using crushed stones with different sizes, it can be used only for crushed stones of the same size, such as only crushed stones with a maximum diameter of around 40 mm, and crushed stones with different sizes. Can be divided and used in multiple layers.
It is also possible to cover the crushed stone covered with a heat shield sheet and reflect the radiant heat of the crushed stone to enhance the heat storage property or cold storage property of the crushed stone.

In the present invention, the concrete surface of the floor surface in the underfloor space is formed in an uneven shape.
Since the surface area is larger than in the case of a flat shape, the heat dissipation efficiency from the concrete is high.
With this uneven shape, more geothermal energy is stored in the crushed stones that are spread in the underfloor space.
The perforated pipe is piped in the horizontal direction along the concave part of the uneven concrete.
Since the recess is closer to the deep underground than the concrete surface, it is easier to obtain geothermal energy and is close to the underground temperature.
Therefore, by providing a porous tube in the recess, geothermal energy closer to the underground temperature can be collected from the porous tube as warm air and cold air.
Moreover, you may provide the groove | channel further formed in the concave shape along the hole provided under the perforated pipe | tube. Since there are no obstacles like crushed stone in the groove, the efficiency of collecting warm and cold air is increased.

In addition, the uneven shape of the concrete surface may be formed in a state in which the convex portions and the concave portions are scattered without regularity, or the convex portions with the raised surface and the concave portions with the concave surface. And may be regularly arranged.
Moreover, the row | line | column of the recessed groove | channel may be simply provided in parallel with the fixed space | interval, and it may be formed so that a convex line and a concave line may be repeated alternately in parallel.
In this case, the convex cross-sectional shape (the shape of the cross-sectional portion in the direction perpendicular to the column direction) may be formed in any shape such as a wave shape, a round shape, a quadrangular shape, and a triangular shape.
In addition, the convex and concave rows are not repeated alternately only in one direction, but, for example, the convex rows and the concave rows are alternately arranged in a direction orthogonal to the mesh shape. It may be formed so as to be repeated.
Even in such a case, the porous tube can be piped by selecting an arbitrary recess.
The concave part where the perforated pipe is not provided simply increases the surface area of the concrete surface and increases the heat dissipation efficiency of the geothermal energy.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is horizontally routed so that it can be placed over the vertices of the protrusions formed on the concrete surface,
It is an underfloor structure of a building characterized by crushed stones spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the others are nectar.

In the present invention, the perforated pipe according to the present invention is not piped along the concave portion of the concrete surface, but is piped so as to be placed between the apexes of the convex portion of the concrete surface.
The shape of the concrete surface is the same as that of the said invention.
The perforated pipe is installed in the horizontal direction so as to span between the vertices of the convex portions formed on the concrete surface.
By piping the porous tube so that it hangs between the apexes of the convex portions, a gap is created immediately below the porous tube between the convex portions.
Since the geothermal energy close to the underground temperature is accumulated in the gap portion, the geothermal energy is collected from the perforated tube as warm air and cold air.
Therefore, crushed stones are laid down so as not to block the gap formed immediately below the porous tube.
Since there are few crushed stones spread directly under the perforated tube, there are no obstacles near the holes provided under the perforated tube, and the perforated tube can easily collect warm air and cold air.
Eventually, warm air and cold air are supplied into the building through the perforated pipe by the force of the fan, etc., but the fan etc. that supplies the air into the building because the perforated pipe makes it easy to collect warm air and cold air, etc. Less power.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
On the concrete surface, an uneven metal plate member is provided,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally along the concave portion of the metal plate member on the upper surface of the metal plate member,
It is an underfloor structure of a building characterized by crushed stones spread from above the perforated pipe.

In the present invention, an uneven metal plate-like member is provided on the concrete surface of the above invention.
The shape of the concrete surface under the metal plate-like member may be flat or uneven.
The metal plate-like member may be integrated with the concrete surface, or may be in a state where it is only placed on the concrete surface.
The concavo-convex shape of the metal plate-like member may be formed in a state where the convex portions and the concave portions are interspersed without regularity, or the convex portions and the surface that are raised are concave. The recesses may be formed regularly in a line.
Moreover, the row | line | column of the groove | channel which was simply depressed may be provided in parallel with the fixed space | interval, and it may be formed so that a convex line and a concave line may be repeated alternately in parallel.
In this case, the convex cross-sectional shape (the shape of the cross-sectional portion in the direction perpendicular to the column direction) may be formed in any shape such as a wave shape, a round shape, a quadrangular shape, and a triangular shape.
In addition, the convex and concave rows are not repeated alternately only in one direction, but, for example, the convex rows and the concave rows are alternately arranged in a direction orthogonal to the mesh shape. It may be formed so as to be repeated.
Further, in the present invention, since the porous tube is piped along the concave portion of the metal plate-like member formed in the concavo-convex shape, even if the concave portion is formed in a mesh shape, the porous tube is not an arbitrary concave portion. Can be selected and piped.
Since the geothermal energy is easily transmitted to the metal plate member through the concrete, the metal plate member is made uneven to increase the surface area of the metal plate member and increase the heat dissipation efficiency of the geothermal energy.
And the recessed part of a metal plate-shaped member is in the state close | similar to the underground temperature as geothermal energy is transmitted through concrete.
Therefore, by providing a porous tube in the recess, geothermal energy closer to the underground temperature can be collected from the porous tube as warm air and cold air.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
An uneven metal plate member is laid on the concrete surface,
A perforated tube that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally on the top surface of the metal plate-like member so as to span the vertices of the convex portions of the metal plate-like member,
It is an underfloor structure of a building characterized by crushed stones spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the others are nectar.

In the present invention, the porous pipe of the above invention is not piped along the concave portion of the metal plate-like member formed in a concavo-convex shape, but is piped so as to be bridged between the apexes of the convex portion of the metal plate-like member. It is a thing.
The perforated pipe is piped in the horizontal direction so as to span between the apexes of the convex portions formed on the metal plate-like member.
By piping the porous tube so that it hangs between the apexes of the convex portions, a gap is created immediately below the porous tube between the convex portions.
Since the geothermal energy close to the underground temperature is accumulated in the gap portion, the geothermal energy is collected from the perforated tube as warm air and cold air.
Therefore, crushed stones are laid down so as not to block the gap formed immediately below the porous tube.
Since there are few crushed stones spread directly under the perforated tube, there are no obstacles near the holes provided under the perforated tube, and the perforated tube can easily collect warm air and cold air.
Eventually, warm air and cold air are supplied into the building through the perforated pipe by the force of the fan, etc., but the fan etc. that supplies the air into the building because the perforated pipe makes it easy to collect warm air and cold air, etc. Less power.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
Shaped steel is arranged on the concrete surface,
The perforated pipe that collects warm air and cold air in the underfloor space and supplies it to the building is installed in a horizontal direction so as to be bridged between the top surfaces of the section steel in a direction perpendicular to the section steel arranged on the concrete surface. And
It is an underfloor structure of a building characterized by crushed stones spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the others are nectar.

In the present invention, a shaped steel material is disposed on a concrete surface, and a porous tube is piped in a direction orthogonal to the shaped steel material so as to be hung between top surfaces of the shaped steel materials.
The shape steel material may be integrated with the concrete surface, or may be just placed on the concrete surface.
As the shape steel material, various shapes such as C-type, U-type, L-type, H-type, and round shape can be used.
The perforated pipe is piped in the horizontal direction so as to be bridged between the top surfaces of the shape steel materials in a direction perpendicular to the shape steel materials.
By placing the perforated pipe in a direction orthogonal to the shape steel material so as to be bridged between the top surfaces of the shape steel material, a gap is formed immediately below the perforated tube between the shape steel material and the shape steel material.
Since the geothermal energy close to the underground temperature is accumulated in the gap portion, the geothermal energy is collected from the perforated tube as warm air and cold air.
Therefore, crushed stones are laid down so as not to block the gap formed immediately below the porous tube.
Since there are few crushed stones spread directly under the perforated tube, there are no obstacles near the holes provided under the perforated tube, and the perforated tube can easily collect warm air and cold air.
Eventually, warm air and cold air are supplied into the building through the perforated pipe by the force of the fan, etc., but the fan etc. that supplies the air into the building because the perforated pipe makes it easy to collect warm air and cold air, etc. Less power.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
Sectional steel with an open top is embedded in the concrete surface,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it to the building is installed horizontally in a direction perpendicular to the structural steel material embedded in the concrete surface and spanning the top surfaces of the structural steel materials. ,
It is an underfloor structure of a building characterized by crushed stones spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the others are nectar.

In the present invention, the structural steel material of the above invention is not disposed on the concrete surface but is embedded in the concrete surface.
The shape steel is embedded so that the top surface portion is exposed from the concrete surface.
In addition, as the shape steel material, for example, a material having a cross-sectional shape with an open top is used, such as a C shape or a U shape.
Even if the perforated pipe is piped in a direction orthogonal to the shaped steel material, the section steel shape material having an open top is embedded so that its top surface is exposed to the concrete surface. There is a gap in the opening of the shape steel material immediately below.
Since the geothermal energy close to the underground temperature is accumulated in the gap portion, the geothermal energy is collected from the perforated tube as warm air and cold air.
Therefore, crushed stones are laid down so as not to block the gap formed immediately below the porous tube.
Since there are few crushed stones spread directly under the perforated tube, there are no obstacles near the holes provided under the perforated tube, and the perforated tube can easily collect warm air and cold air.
Eventually, warm air and cold air are supplied into the building through the perforated pipe by the force of the fan, etc., but the fan etc. that supplies the air into the building because the perforated pipe makes it easy to collect warm air and cold air, etc. Less power.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally along the recess formed in the concrete surface,
A net is laid on the perforated pipe,
It is an underfloor structure of a building characterized by crushed stones spread over a net-like body.

In the present invention, a net-like body is laid on a perforated pipe that is piped along a concave portion of a concrete surface that is formed in a concavo-convex shape.
The net-like body may be laid together so as to be laid over the vertices of the convex portions formed on the concrete surface, or may be laid for each concave portion.
By laying crushed stones in a state where the mesh body is laid on the perforated pipe, the crushed stone is not placed under the mesh body, that is, around the perforated pipe, so there is a gap around the perforated pipe. .
Since the geothermal energy close to the underground temperature is accumulated in the gap portion, the geothermal energy is collected from the perforated tube as warm air and cold air.
Since the crushed stone is not spread around the perforated tube, there is no obstacle near the hole of the perforated tube, and the perforated tube can easily collect warm air and cold air.
Eventually, warm air and cold air are supplied into the building through the perforated pipe by the force of the fan, etc., but the fan etc. that supplies the air into the building because the perforated pipe makes it easy to collect warm air and cold air, etc. Less power.

The present invention
In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A mesh-like body is laid in the concave part of the concrete surface,
A perforated pipe that collects the warm air and cold air in the underfloor space and supplies it into the building is piped horizontally on the mesh body laid on the concrete surface,
It is an underfloor structure of a building characterized by crushed stones spread from above the perforated pipe.

In the present invention, the network according to the present invention is not laid on a porous tube, but is laid on a concave portion of a concrete surface under the porous tube.
In the net-like body, the concave portions may be laid together so as to be laid over the vertices of the convex portions formed on the concrete surface, or may be laid for each concave portion.
A perforated pipe is piped on a net-like body along a concave portion formed on a concrete surface, and crushed stones are spread over the pipe.
As a result, the crushed stone is not spread under the mesh body, that is, in the concave portion of the concrete surface, so that a large gap is generated.
Since the geothermal energy close to the underground temperature is accumulated in the gap portion, the geothermal energy is collected from the perforated tube as warm air and cold air.
Since the crushed stone is not spread in the concave portion directly under the perforated tube, there is no obstacle near the hole provided under the perforated tube, and the perforated tube can easily collect warm air and cold air.
Eventually, warm air and cold air are supplied into the building through the perforated pipe by the force of the fan, etc., but the fan etc. that supplies the air into the building because the perforated pipe makes it easy to collect warm air and cold air, etc. Less power.

The present invention
The porous tube is
For cold air collection,
The underfloor structure for a building according to any one of claims 1 to 8, wherein a porous tube for collecting warm air is provided near the ceiling of the underfloor space for collecting warm air. is there.

In the present invention, the perforated pipes piped in the underfloor space are divided into two types for collecting cold air and for collecting warm air, and the perforated pipe arranged on the floor side of the underfloor space is used for collecting cold air and the ceiling of the underfloor space. A perforated pipe piped in the vicinity is used for collecting warm air.
The perforated pipe for collecting cold air is as described above, and the perforated pipe for collecting warm air for collecting warm air collects at a position where the warm air is high, and is therefore piped near the ceiling of the underfloor space.
The perforated pipe for collecting warm air may be piped so as to be suspended from the ceiling, or may be piped so as to be placed on a crushed stone.
The porous tube for collecting warm air may be piped in the same direction as the porous tube for collecting cold air, or may be piped in a direction orthogonal to the porous tube for collecting cold air.
By using two types of perforated pipes in the underfloor space, one for collecting cold air and one for collecting warm air, it is possible to effectively collect warmer and colder air in the underfloor space. Cold air can be supplied separately into the building, or it can be supplied selectively depending on the room in which it is supplied.

The present invention
The crushed stone is
The building underfloor structure according to any one of claims 1 to 9, wherein the building is divided into a plurality of layers in a height direction by a net.

In the present invention, the crushed stone is divided into a plurality of layers in the height direction by a net rather than simply laying the crushed stone.
Thereby, it can divide | segment into a some layer for every magnitude | size of crushed stone, and the clearance gap between crushed stone and crushed stone can also be provided.
Further, a porous tube can be provided between the crushed stone and crushed stone layers.

1) Geothermal energy can be efficiently collected from the space under the floor as warm air or cold air, and the collected warm air and cold air can be supplied into the building.

2) By making the surface shape of the floor concrete in the underfloor space uneven, it is possible to increase the surface area and dissipate the geothermal energy efficiently, and as a result, effectively collect the geothermal energy as warm air or cold air be able to.

3) By piping the porous tube in the recess, geothermal energy closer to the underground temperature can be collected from the porous tube as warm air and cold air.

4) By providing a gap directly below the porous tube and reducing the number of crushed stones spread, it becomes easier for the porous tube to collect warm air and cold air, and the power of the fan and the like supplied to the building can be reduced.

5) By using the perforated pipe separately for cold air sampling and warm air sampling, warm air and cold air in the underfloor space can be effectively sampled and supplied into the building.

Schematic plan view of underfloor space AA line sectional view of FIG. BB sectional view of FIG. Schematic diagram of a state where a perforated tube is piped in the recess Schematic diagram of the state in which a perforated pipe is piped over the convex part Schematic diagram of the state where crushed stones are laid out so that the area directly below the perforated pipe is sparse Schematic diagram of a state in which a metal plate member is provided on the concrete surface of the floor Schematic diagram of the state where the shape steel material is provided on the concrete surface of the floor

1 is a schematic plan view of the underfloor space, FIG. 2 is a cross-sectional view taken along the line AA in FIG. 1, and FIG. 3 is a cross-sectional view taken along the line BB in FIG.
In the underfloor space, concrete is cast on all of the side surface (wall surface), top surface (ceiling), and floor surface, and the concrete surface on the floor surface is formed with parallel rows of convex and concave portions. Also in the direction orthogonal to each other, the rows of convex portions and concave portions are alternately formed in parallel, and the concave portions are formed in a net shape as a whole.
In addition, the thick line-shaped thing painted black in the figure is a porous tube.
The perforated pipe has an end on the upper right side of FIG. 1 and is uniformly piped in the space under the floor so as to receive the recess, and is piped upward along the side surface (side wall) in the lower left of FIG. It is connected to a pipe that supplies warm air and cold air into the object.
The perforated tube is provided with holes for collecting warm air and cold air at a total of four locations, below, on both sides, and above.
Warm air and cold air collected from the perforated pipe are supplied to the room of the building by a ventilation fan.
A ventilation fan may be provided in the pipe | tube which supplies warm air and cold air in a building, and may be provided in the terminal of the perforated pipe connected to the said pipe | tube.
1 to 3 do not show crushed stones, the crushed stones are spread from the top of the perforated pipe to the entire height of the underfloor space to a height near the top surface (ceiling) of the underfloor space.
It is also possible to cover the crushed stone covered with a heat shield sheet and reflect the radiant heat of the crushed stone to enhance the heat storage property or cold storage property of the crushed stone.

FIG. 4 is a schematic view of a state in which the perforated pipe 1 is piped in the concave portion of the concrete surface of the three types of floor surfaces ((1) to (3) in the figure) formed in an uneven shape, and FIG. It is the schematic of the state which piped the porous pipe 1 so that it might span over the vertex of a convex part.
In the drawing, a thick black solid line is the perforated tube 1, and white holes of the perforated tube 1 are holes for collecting warm air and cold air.
The uneven shape may take various shapes.
As the shape of the concrete surface itself of the floor, it may be formed in an uneven shape, or a convex concrete member may be placed on a concrete surface placed on a flat surface.
In particular, when the porous tube 1 is piped so as to be bridged between the vertices of the convex portions in FIG. 5, a gap is formed immediately below the porous tube 1 between the convex portions. The crushed stone is laid down so that the space immediately below the perforated tube 1 is sparse so as not to block the gap formed immediately below the perforated tube 1.
FIG. 6 is a schematic diagram of a state in which the crushed stones 3 are spread so that the portion directly below the porous tube 1 is sparse.
Since there are few crushed stones 3 directly under the porous tube 1, there are no obstacles near the hole 2 provided below the porous tube 1, and the porous tube 1 can easily collect warm air and cold air.
Eventually, warm air and cold air are supplied into the building through the porous tube 1 by the force of a fan or the like, but the porous tube 1 can easily collect warm air and cold air, so Less is enough.

FIG. 7 is a schematic view showing a state in which the metal plate-like member 44 is provided on the concrete surface of the floor surface.
In the figure, the thick black solid line is the perforated tube 1, and the white dots are the holes for collecting warm air and cold air.
(1)-(3) of FIG. 7 shows the state which mounted the metal plate-shaped member 4 on the concrete surface, (4)-(6) shows the metal plate-shaped member 4 as concrete. It shows the state provided integrally.
As the metal plate member 4, for example, a mortar base material obtained by electrically welding a metal lath to a zinc iron plate can be used.
Geothermal energy is easily transmitted to the metal plate-like member 4 through the concrete on the floor surface.
Therefore, the heat radiation efficiency of the geothermal energy is enhanced by providing the metal plate-like member 4 formed in an uneven shape on the concrete surface.
The perforated tube 1 can be piped so as to be accommodated in the recesses parallel to the rows of recesses, but in the drawing, the direction perpendicular to the protruding rows of the metal plate-like members 4, that is, the protrusions It is plumbed in a horizontal direction so that it can be bridged between the vertices.
By piping the porous tube 1 so as to be bridged between the vertices of the convex portions of the metal plate-like member 4, a gap is generated immediately below the porous tube 1 between the convex portions.
The crushed stone spread in the gap and the effect are the same as in the description of FIG.

FIG. 8 is a schematic view of a state in which the shape steel material 5 is provided on the concrete surface of the floor surface.
In the figure, the thick black solid line is the perforated tube 1, and the white dots are the holes for collecting warm air and cold air.
(1) to (3) in FIG. 8 show a state in which the shape steel material 5 is placed on the concrete surface. In (4) to (6), the shape steel material 5 is provided integrally with the concrete. It shows the state.
When the shape steel material 5 is provided integrally with concrete, for example, if the shape is an open top, it can be disposed on the concrete surface with the opening portion facing upward. A gap is created.
Further, the porous tube 1 is piped in a direction orthogonal to the shape steel material 5, that is, in a horizontal direction so as to be laid over the top surfaces of the shape steel material 5, so that the porous tube 1 between the shape steel material 5 and the shape steel material 5 There is a gap immediately below.
The spread of crushed stones in these gaps and the effect are the same as in the description of FIG.

In addition, a net-like body can be laid in the uneven | corrugated shaped recessed part formed in the concrete surface of a floor surface, the recessed part of the metal plate-shaped member formed in uneven | corrugated shape, and the clearance gap between shape steel materials.
The perforated pipe can be piped under or above the mesh body, and when the perforated pipe is piped under the net body, there is no crushed stone around the perforated pipe, and the warm air around the perforated pipe Easy to collect cold air.
In addition, when the perforated pipe is piped on the mesh body, crushed stone is spread over the perforated pipe, but there is no crushed stone under the mesh body, that is, directly under the perforated pipe, and the perimeter of the perforated pipe. Easy to collect warm and cold air.
In either case, the perforated tube can easily collect warm air and cold air, so that the power of a fan or the like supplied into the building can be reduced.
In addition, warm air and cold air are dissipated from the floor surface because the geothermal energy in the ground travels through the concrete on the floor surface, so if you collect warm air and cold air closer to the floor surface, You can collect near warm and cold air and supply it to the building.

In the underfloor space, two perforated tubes for collecting warm air and collecting cold air can be piped.
The two perforated tubes for collecting warm air and for collecting cool air are the same perforated tubes, except that the positions of piping are different.
The perforated pipe for collecting warm air is preferably piped near the ceiling of the underfloor space because the warm air collects above the underfloor space, and may be hung from the ceiling, or simply crushed stones. You can just place it on top.
By using two types of perforated pipes in the underfloor space, one for collecting cold air and one for collecting warm air, it is possible to effectively collect warmer and colder air in the underfloor space. Cold air can be supplied separately into the building, or it can be supplied selectively depending on the room in which it is supplied.

Moreover, the following Example can be considered as another form of utilization of the porous tube for collecting warm air.
For example, a perforated pipe is piped near the roof of the shed (ceiling) in the building or the ceiling of the stairwell, and from the perforated pipe to the inside of the building during the daytime when indoor air in the building is warm. The warm air is collected and delivered to the space under the floor to heat the crushed stone and store it.
Thereafter, when the temperature in the building falls, such as at night, the warm air can be collected from the crushed stone in the stored underfloor space and supplied into the building by the porous tube for collecting warm air.
The warm air collected from the building can be directly resupplied into the building without being supplied into the underfloor space.

DESCRIPTION OF SYMBOLS 1 Porous pipe 2 Porous pipe hole 3 Crushed stone 4 Metal plate-shaped member 5 Shape steel material

Claims (10)

In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally along the recess formed in the concrete surface,
An underfloor structure of a building, in which crushed stones are spread over the perforated pipe. In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is horizontally routed so that it can be placed over the vertices of the protrusions formed on the concrete surface,
An underfloor structure of a building, in which crushed stones are spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the rest is nectar. In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
On the concrete surface, an uneven metal plate member is provided,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally along the concave portion of the metal plate member on the upper surface of the metal plate member,
An underfloor structure of a building, in which crushed stones are spread over the perforated pipe. In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
On the concrete surface, an uneven metal plate member is provided,
A perforated tube that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally on the top surface of the metal plate-like member so as to span the vertices of the convex portions of the metal plate-like member,
An underfloor structure of a building, in which crushed stones are spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the rest is nectar. In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
Shaped steel is arranged on the concrete surface,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it to the building is installed horizontally in a direction perpendicular to the shape steel material piped on the concrete surface and spans the top surfaces of the shape steel materials. ,
An underfloor structure of a building, in which crushed stones are spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the rest is nectar. In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
Sectional steel with an open top is embedded in the concrete surface,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it to the building is installed horizontally in a direction perpendicular to the structural steel material embedded in the concrete surface and spanning the top surfaces of the structural steel materials. ,
An underfloor structure of a building, in which crushed stones are spread from above the perforated pipe so that the area directly below the perforated pipe is sparse and the rest is nectar. In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A perforated pipe that collects warm air and cold air in the underfloor space and supplies it into the building is piped horizontally along the recess formed in the concrete surface,
A net is laid on the perforated pipe,
An underfloor structure of a building, in which crushed stones are spread over a net-like body. In the underfloor structure where the floor surface of the underfloor space of the building is covered with concrete,
The concrete surface is formed in an uneven shape,
A mesh-like body is laid in the concave part of the concrete surface,
A perforated pipe that collects the warm air and cold air in the underfloor space and supplies it into the building is piped horizontally on the mesh body laid on the concrete surface,
An underfloor structure of a building, in which crushed stones are spread over the perforated pipe. The porous tube is
For cold air collection,
The underfloor structure for a building according to any one of claims 1 to 8, wherein a porous tube for collecting warm air is provided near the ceiling of the underfloor space for collecting warm air. The crushed stone is
The underfloor structure of a building according to any one of claims 1 to 9, wherein the building is divided into a plurality of layers in a height direction by a net.