JP3201755B2 - Building air conditioning system using geothermal energy - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a detached house, apartment, can be applied to the building such as a building, on the air-conditioning system of the building using geothermal.

[0002]

2. Description of the Related Art Conventionally, a cooling and heating system utilizing geothermal energy has been proposed. For example, Japanese Patent Application Laid-Open No. 57-60149
Japanese Patent Application Publication No. JP-A-2002-115873 discloses a cooling device in which a floor below a house and an exposed ground are connected by a tunnel, and air cooled by geothermal heat is supplied into the house through the tunnel.

[0003]

However, in the cooling device and the like disclosed in the above publication, heat is exchanged with geothermal only in the process of moving air in the tunnel, so that the effect of heat conduction from geothermal is extremely limited. It is stopped at
The use of geothermal heat for air conditioning is extremely inadequate. Further, in the cooling device disclosed in the above publication, it is not assumed at all that the air is simply exchanged with the geothermal heat, and that, for example, the air is not humidified or cleaned.

The present invention focuses on such problems of the prior art, and performs highly efficient heat exchange with geothermal heat from outside air and also performs humidity control and purification of the air. on the can help conditioning by supplying the air in the building, and to provide an air conditioning system for buildings using geothermal.

[0005]

The air-conditioning system for a building utilizing geothermal energy according to the present invention for solving the above-mentioned problems is buried underground, takes in outside air, and removes the taken-in air. Underground pipes for heat exchange with geothermal heat, and a height of several hundred mm (eg, about 40 cm or more, more preferably about 50 cm or more, or about 100 cm) surrounded by the building foundation, the entire floor of the building, and the ground. The underfloor space having a size of 60 cm or more) is filled with a large number of quarry stones, and the geothermal heat is efficiently accumulated in an air layer or the like in a minute gap between the multitude of burble stones. A cobblestone layer, from the underground pipe `` air exchanged with geothermal heat in the underground pipe, cooled from the outdoors in the summer and warmed from the outdoors in the winter '' and taken in. The land It includes a floor cobble stone layer for air humidity and cleaning from pipes, and an air supply means for supplying air from the underfloor cobble stone layer in the room of the building.

In the air conditioning system for buildings utilizing city heat according to the present invention, the underground pipe is buried in the ground outside the building.

[0007] In the building air conditioning system utilizing the geothermal of the present invention, the underground pipe is buried in the ground of the interior of the building.

Further, the air-conditioning system for a building utilizing geothermal energy according to the present invention is buried in the ground, takes in outside air, and exchanges the taken-in air with the geothermal heat. An outside air supply means for supplying outside air to the middle pipe, and a height of several hundred mm (for example, about 40 cm or more, more preferably about 50 c
m or more than about 60 cm) is filled with a large number of cobblestones in the underfloor space, and geothermal energy is efficiently accumulated in an air layer or the like in a minute gap between the plurality of cobblestones. The underfloor cobblestone layer that is as follows, from the underground pipe `` air exchanged with geothermal heat in the underground pipe, cooled in the summer in the summer and warmed in the winter in the winter, '' An underground cobblestone layer for controlling and cleaning air from the underground pipe, and a perforated pipe formed with a number of holes provided in the underfloor cobblestone layer, A perforated pipe for sending air from the middle pipe to the underfloor stone layer, and air supply means for supplying air from the underfloor stone layer to the interior of the building.

Further, the air-conditioning system for a building utilizing geothermal energy according to the present invention is buried underground, takes in outside air, and exchanges the taken-in air with geothermal heat. An outside air supply means for supplying outside air to the middle pipe, and a height of several hundred mm (for example, about 40 cm or more, more preferably about 50 c
m or more than about 60 cm) is filled with a large number of cobblestones in the underfloor space, and geothermal energy is efficiently accumulated in an air layer or the like in a minute gap between the plurality of cobblestones. The underfloor cobblestone layer that is as follows, from the underground pipe `` air exchanged with geothermal heat in the underground pipe, cooled in the summer in the summer and warmed in the winter in the winter, '' An underfloor cobblestone layer for controlling and purifying air from the underground pipe, and a perforated pipe that is inserted substantially at the center of the underfloor cobblestone layer and has a large number of holes formed therein. A perforated pipe for sending air from the underground pipe to the underfloor cobblestone layer,
A portion of the underfloor stone layer (e.g., 4) is formed to form a passage for supplying air from the underfloor stone layer into the building.
And a cavity formed at a location of the (corner), comprising a substance for imparting a predetermined scent to air from the underfloor cobblestone layer and a substance for controlling and purifying the air. Air supply means for supplying air from the underfloor cobblestone layer into the interior of the building via the cavity.

Further, in the building air conditioning system utilizing the geothermal of the present invention, the underground pipe, the air from the outdoor flowed from the hole top and bottom formed thereon are plugged An outer pipe for exchanging heat with geothermal heat while moving downward along the inner wall surface, and provided inside the outer pipe with a predetermined gap between the inner wall surface of the outer pipe and the outer pipe. An inner pipe for taking the air that has moved to the bottom along the inner wall surface, taking it up into itself and raising it to send it to the side of the cobblestone layer,
It is composed of

In the air conditioning system for a building utilizing geothermal energy according to the present invention, the outer pipe has a wavy cross section.

Further, in the building air-conditioning system using city heat according to the present invention, when harmful gas (toxic gas) is generated due to smoke or gas leakage, the air from the cobblestone layer is introduced into the building. (This fan includes a fan for introducing the outdoor air into the underground pipe, and a fan for introducing air from the underground pipe into the cobblestone layer). And an abnormal stop device for stopping the harmful gas due to smoke or gas leakage, and a detecting device for detecting the occurrence of harmful gas due to smoke or gas leakage. And control means for stopping the fan based on a signal from the controller.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. Figure 1 is a plan sectional view for explaining the air-conditioning system of a building utilizing geothermal according to the first embodiment of the present invention. In FIG. 1, reference numeral 1 denotes a concrete foundation of a building formed on the outer periphery of the building, and reference numeral 2 denotes a height of about 40 cm or more (more preferably, a height of about 40 cm) surrounded by the foundation 1, the floor of the building, and the ground. A cobblestone layer in which a large number of cobblestones are filled in an underfloor space of 50 cm or more than about 60 cm (in FIG. 1, individual cobblestones are not shown). Is a perforated pipe having a large number of holes 3a formed through a substantially central portion thereof, and 4 is a hole in the underfloor space (cobblestone layer 2).
The cavities 5 and 6 respectively formed at the corners are underground pipes (in the example of FIG. 1, the two underground pipes) buried under the ground outside the foundation 1 (outside the building). The underground pipes 5 and 6 are connected in series, and two sets of the underground pipes 5 and 6 connected in series are connected in parallel to each other through a fan 8 described later. , 7 is a pipe for sending air from the underground pipes 5 and 6 to the perforated pipe 3, and 8 is drawing outdoor air into the underground pipes 5 and 6, and A fan for blowing air from the middle pipes 5 and 6 to the cobblestone layer 2 through the perforated pipe 3;

Next, FIG. 2 shows the underground pipes 5 and 6,
It is a longitudinal cross-sectional view for explaining the cobblestone layer 2 and the perforated pipe 3. In FIG. 2, the underground pipe 5 has an outer pipe 5a (made of metal or plastic) having a large diameter whose top and bottom are closed by a lid, and an outer pipe 5a.
And an inner pipe 5b (made of metal or plastic) having a smaller diameter. The outer pipe 5
A plurality of holes 5c for introducing outside air are formed in the portion a above the ground surface GL. The inner pipe 5b is provided in the outer pipe 5a with a predetermined gap between the inner pipe 5a and the inner wall surface of the outer pipe 5a.
As described above, the underground pipe 5 of the present embodiment has a "double pipe structure" of the outer pipe 5a and the inner pipe 5b.

The bottom surface of the inner pipe 5b is open. The upper part of the inner pipe 5b is
In FIG. 2, a pipe 9 is connected to a gap between the outer pipe 6a and the inner pipe 6b of the underground pipe 6 adjacent to each other. On the other hand, also in the underground pipe 6, the outer pipe 6a has its upper surface and bottom surface closed with a lid. Also,
The inner pipe 6b has an open bottom surface, and the upper surface thereof is connected to the perforated pipe 3 by a pipe 7.

Next, FIG. 3 is a view for explaining the internal structure of the underground pipes 5, 6 in more detail. FIG. 3 (a)
Is a partial perspective view showing a part of the outer pipe 5a;
(b) is a partial sectional view thereof, and (c) is the inner pipe 5.
b is a partial perspective view, and (d) is a plan sectional view of the underground pipe 5. In the present embodiment, the outer pipe 5a
A large number of fins 5e made of metal or plastic are formed on the inner wall surface of the fin 5e.
Are not shown in FIG. 2). This fin 5e
It protrudes from the gap 5d (see FIG. 3D) between the outer pipe 5a and the inner pipe 5b in a direction perpendicular or oblique to the direction in which the air moves. These many fins 5e constitute the "surface contact portion" of the present invention. That is, the air moving in the gap 5d efficiently comes into contact with the surfaces of the fins 5e in the course of the movement.

Next, the underground pipes 5 and 6 of the present embodiment will be described.
Will be described with reference to FIGS. As shown by a plurality of arrows in FIG. 2, when the fan 8 is operated (by the air blown by the fan 8), the outdoor air is removed from the hole 5 c formed above the outer pipe 5 a by the gap. 5d is introduced. The introduced air moves downward in the gap 5d due to the blowing air of the fan 8, and in the course of this movement, comes into contact with the surfaces of the plurality of fins 5e. Geothermal heat is conducted and accumulated in the fins 5e via the outer pipe 5a. Therefore, in the process of moving the air downward in the gap 5d, the air efficiently contacts the inner wall surface of the outer pipe 5a and the plurality of fins 5e so that heat is efficiently exchanged with geothermal heat. Has become.

The fins 5e have the following functions in addition to the function of conducting geothermal heat to the air. That is, when air containing much moisture in summer comes into contact with the fins 5e, moisture (moisture) from the air adheres to the surface of the fins 5e, so that the air is dehumidified. Conversely, when the dry air in winter comes into contact with the fins 5e, the moisture adhering to the surfaces of the fins 5e is supplied to the air to humidify the air. That is, the outdoor air is separated by the gap 5d.
When the air is moist air in summer, the moisture contained in the air is reduced by the large number of fins 5.
e, the air is dehumidified (humidified), and when the outdoor air is dry air in winter, the water adhering to the plurality of fins 5e is supplied to the air. Then, the air is humidified (humidified). As described above, the fins 5e (surface contact portions) also perform the "humidifying effect" of the moving air.

When air containing a large amount of impurities such as fine dust comes into contact with the fins 5e, the impurities adhere to the moisture on the surface of the fins 5e, so that the air is cleaned. That is, when the outdoor air descends through the gap 5d, impurities such as minute dust contained in the air are attached to the moisture on the surfaces of the fins 5e, so that the air is purified. You. As described above, the fins 5e (surface contact portions) also perform the "cleaning action" of the moving air.

Next, as shown by a plurality of arrows in FIG. 2, after the air descends through the gap 5d and reaches the bottom of the outer pipe 5a, the air is transferred to the lower surface (opened) of the inner pipe 5b. Enters the inside of the inner pipe 5b and goes up inside. Then, it moves to the adjacent underground pipe 6 via the pipe 9. In the underground pipe 6, as in the underground pipe 5, the air is
First, a gap 6 between the outer pipe 6a and the inner pipe 6b.
Move d downward. Although not shown, many fins (similar to the fins 5e) are also provided on the inner wall surface of the outer pipe 6a. Therefore, the air comes in contact with the inner wall surface of the outer pipe 6a and the fins 5e in the process of moving down the gap 6d, thereby performing efficient heat exchange with the geothermal heat, humidity control, and cleaning. Will be

Next, in FIG. 2, after the air descends through the gap 6d and reaches the bottom of the outer pipe 6a, it rises inside the inner pipe 6b as shown by an arrow in FIG. Then, it is sent to the perforated pipe 3 via a pipe 7 and a fan 8. The air sent to the perforated pipe 3 is sent into the underfloor cobblestone layer 2 from the large number of holes 3a of the perforated pipe 3 by the wind blast of the fan 8. Since the underfloor cobble stone layer 2 is filled with a large number of cobblestones, geothermal energy is efficiently accumulated in an air layer or the like in a minute gap between the large number of cobblestones. The fan 8
As shown by a plurality of arrows in FIG. 1, the air sent to the underfloor stone layer 2 moves through the underfloor stone layer 2 toward the hollow portion 4 by the blowing air of the fan 8. I will do it. The air moves through the underfloor cobblestone layer 2. When the humid air in summer passes, the underfloor cobblestone layer 2 adheres the water to the surface of the large number of cobblestones to dehumidify the air, and when the dry air in winter passes. Also provides the "humidifying effect of air" by supplying moisture adhering to the surface of the large number of cobblestones to the air to humidify the air. In addition, the underfloor cobblestone layer 2 cleans the air by adhering the impurities to the moisture on the surface of the large number of cobblestones when the air containing impurities such as minute dust passes therethrough. Purifying effect. "

Next, a detailed structure of the cavity 4 of the present embodiment will be described with reference to FIG. The hollow portion 4 is formed by the rising portion of the concrete foundation 1 and a perforated block at four corners of the portion surrounded by the concrete foundation 1 in FIG. 1 (at four corners of the cobblestone layer 2). Wall 11
(Preferably having a plane of about 1 m square). The air that has been heat-exchanged with the geothermal heat, humidified, and purified by the cobblestone layer 2 enters the cavity 4 from the cobblestone layer 2 through the hole in the wall 11 due to the blown air from the fan 8. And a hole 1 formed in the floor 12 of the building.
Through the holes 2a and the holes 20, the air is sent into the building (rooms of the building, an air flow passage between the room and the outer wall, an air flow passage between the floor 12 of the building and the cobblestone layer 2, etc.).

Further, in the hollow portion 4, fragrance, charcoal, and tourmaline (tourmaline is an ore also called tourmaline and constantly generates a small amount of static electricity, so that the surrounding air is deodorized and purified. A net-shaped bag 13 containing ambient air, which is said to have an action of releasing negative ions, etc.) is suspended in the space above the bag. The fragrance has an effect of giving a pleasant scent to the surrounding air. In addition, the charcoal has an effect of adjusting humidity in the air and absorbing odor components in the air to deodorize. In addition, the tourmaline deodorizes and purifies the surrounding air as described above, and releases negative ions to the surrounding air (the negative ions are said to have a function of regulating the autonomic nerves of humans). Has the action of Therefore, in the present embodiment, the air that has been heat-exchanged with the geothermal heat and humidified and purified in the cobblestone layer 2 passes through the bag 13 of the cavity 4 (or contacts the bag 13). ), The air is converted into “comfortable scent, moderately adjusted humidity, deodorized and purified air”, and supplied into the building.

In FIG. 4, reference numeral 12b denotes an inspection port. The user can perform maintenance such as replacing the fragrance, charcoal, and tourmaline in the bag 13 by putting his / her hand through the inspection port 12b.

Next, the operation in summer when the air conditioning system of this embodiment is applied to a house will be described with reference to FIG. In FIG. 5, reference numeral 21 denotes an attic air flow passage for discharging air from the attic of the building to the outside, 22 denotes an underfloor air flow passage provided below the floor 12 of the building, and 23 denotes air from the underfloor air flow passage 22. Is an outer wall air flow passage for allowing air to flow between the outer wall of the building and the room, and 20 is a vent for guiding the air in the underfloor air flow passage 22 into the room.

The cobblestone layer 2 is formed over several hundred meters above and below a GL (ground surface) so as to easily accumulate geothermal energy.
m (for example, about 400 to 600 mm or more). A concrete layer having a thickness of, for example, about 70 to 100 mm is formed on the cobblestone layer 2 or urethane foam (for example, 25 to 3 mm).
A heat insulating material 32 (such as 0 mm thick) is laid so that the geothermal heat stored in the gangue layer 2 does not easily escape to the outside.

A moisture-proof sheet 33 made of, for example, vinyl is provided on the lower surface of the cobblestone layer 2. The moisture-proof sheet 33 prevents the moisture in the ground from rising into the cobblestone layer 2, but allows the water in the cobblestone layer 2 to fall into the ground. That is, since the moisture-proof sheet 33 is arranged so that a plurality of sheets are folded on each other, an increase in moisture from below is prevented, but moisture from above overlaps the plurality of sheets. It can be moved downward from the gap between the parts.

In FIG. 5, reference numeral 25 denotes an inner wall air flow passage for supplying the air in the attic to the cobblestone layer 2 while passing through the space in the inner wall between the rooms. The inner wall air flow passage 25 is formed in a bellows shape having a large surface area in order to enhance heat conduction efficiency. Also,
The lower end of the inner wall air flow passage 25 is connected to the perforated pipe 3 (see FIGS. 1 and 2).

In FIG. 5, reference numeral 26 denotes a fan provided in the attic, and reference numeral 27 denotes a fan provided at an intermediate portion of the attic air flow passage 21 and is provided between the fan 26 and an exhaust port 28 communicating with the outside. Damper. Reference numeral 29 denotes a damper provided at an intermediate portion of the inner wall air flow passage 25 and interposed between the fan 26 and the cobblestone layer 2. The damper 27 is opened by a predetermined temperature sensor and a control device (microcomputer) so that the humid air of the attic is released outside through the attic air flow passage 21 in the summer, and in the winter, Warm air in the attic is closed so that it does not escape outside. The damper 29 is closed by a predetermined temperature sensor and a control device so that the humid air of the attic does not heat the room through the inner wall air flow passage 25 in the summer, and the warm air in the attic in the winter. Are opened so as to be supplied to the cobblestone layer 2 while warming the room through the inner wall air flow passage 25. In FIG. 5, reference numerals 40 and 41 denote indoor ventilation holes for allowing room air to escape to the attic.

In the house shown in FIG. 5, in the summer, the temperature of the air in the attic (attic) is increased by the action of a temperature sensor including a thermostat (not shown) and a control device (microcomputer). When the temperature rises by convection and becomes, for example, 25 ° C. or more, the ventilation motor (motor for the fan 26) automatically starts to rotate, the damper 27 is in an “open” state, and the hot air behind the ceiling is discharged outside (the other end). And the damper 29 is "closed"). On the other hand, in summer (when the temperature is 25 ° C. or higher), the fan 8 (see FIGS. 1 and 2) is set to rotate constantly, so that the outdoor air (high-temperature, humid air) In the process of passing through the underground pipes 5 and 6 in FIG. 2 as described above, it is always cooled by geothermal heat (cold heat) and dehumidified and purified by the fins 5e. Then, the air further flows into the underfloor cobblestone layer 2 (a regenerative heat layer cooled by the geothermal heat from the outdoor temperature) via the perforated pipe 3.
At this time, the moisture in the air is condensed on the surface of many gems and dehumidified to some extent (air conditioning effect of the underfloor quarry layer), and the impurities in the air are dehydrated on the surface of many gems. And is cleaned (air cleaning action of the underfloor cobblestone layer 2).

The air dehumidified and purified by the underfloor cobblestone layer 2 moves into the cavity 4 (see FIGS. 1 and 2), and the sack 13 imparts fragrance, humidity control, and the like. After being deodorized and purified, it is supplied into the building. The air supplied into the building cools the inside of the building by passing through the room or passing through the outer wall air flow passage 23 as shown by the arrow in FIG. 5, and then moves to the attic, The air is discharged outside by the fan 26 and the damper 27.

Next, the operation of the air conditioning system of the present embodiment in winter when used in a house will be described with reference to FIG. In winter, the damper 27 is closed and the damper 29 is open. In the present embodiment, the temperature of a thermostat (not shown) is set to, for example, 15 ° C. Thereby, when the temperature of the attic reaches 15 ° C. or more, the fan 26
The motor for rotation rotates, and the air warmed by the solar heat in the attic further flows through the air flow passage 25 into the perforated pipe 3.
, And moves to the cobblestone layer 2 under the floor (heat storage layer heated by geothermal energy).

In the winter season, the driving device of the fan 8 (see FIGS. 1 and 2) is set to, for example, "3
It is set in advance by a control device or the like, such as "rotate for only minutes." Here, for example, the reason why the fan 8 is rotated at a pace of "only for 3 minutes every hour" is as follows. That is, first,
In winter, even if the outdoor cold air is heated by exchanging heat with the geothermal heat by the underground pipes 5 and 6, the air is often heated only to a temperature lower than the temperature of the indoor heated air. It is not desirable to keep air from the room at all times. However, on the other hand, even in winter, it is necessary to introduce new outdoor air into the building every predetermined time. Therefore, as described above, by driving the fan 8 at a pace of, for example, "every 3 hours every hour", the air from the outdoors is blown out from the underground pipes 5, 6, the perforated pipe 3, While moving in the underfloor cobblestone layer 2 and the hollow part 4 (in the process of this movement, the air from the outside is heated to some extent by heat exchange with geothermal heat, and is conditioned and purified). , And supply it into the building. The air from outside (dry air in winter) is not only warmed by geothermal heat but also humidified (humidified) in the process of moving through the underground puffs 5 and 6 and the underfloor cobblestone layer 2. And cleaned.

Next, in this embodiment, an abnormal stop device as shown in the block diagram of FIG. 7 is provided.
In FIG. 7, reference numeral 92 denotes a smoke sensor provided outside or inside a building for detecting smoke due to a fire, 93 denotes a gas sensor for detecting generation of toxic gas due to gas leakage outside or inside a building, and 94 denotes a gas sensor. A fan motor 95 for driving the fan 8 (see FIGS. 1 and 2) and the fan 26 (see FIG. 6). The fan motor 95 is based on detection signals from the smoke sensor 92 and the gas sensor 93.
Microcomputer to stop the operation. In the present embodiment, when detecting smoke due to fire or toxic gas due to gas leakage, the microcomputer 95
, The rotation of the fans 8 and 26 is stopped, so that "smoke and toxic gas spread over the entire building within a short time due to the rotation of the fans 8 and 26" is effectively set in advance. Is to be prevented.

Embodiment 2 FIG. Next, FIG. 8 is a diagram for explaining Embodiment 2 of the present invention. In the second embodiment,
The underground pipe is configured as a "double pipe" using a spiral pipe made of metal such as aluminum or plastic such as polyethylene or polyester. That is, FIG. 8A is an exploded perspective view of the double pipe used in the second embodiment. In FIG. 8A, reference numeral 51 denotes an outer spiral tube made of, for example, aluminum or polyethylene or polyester having a diameter of 300 to 450 mm. As shown in FIG. 8B, the outer spiral tube 51 is formed of a thin sheet having a corrugated cross section (having irregularities in a spiral shape), and therefore has a larger surface area than a normal tube. Extremely large. When the outer spiral tube 51 is made of plastic, its thickness can be made very thin, for example, about 2 to 4 mm. Therefore, it is generally said that the heat conductivity of a plastic tube is lower than that of a metal tube. However, when manufacturing the outer spiral tube 51 of the present embodiment with plastic, as described above, the surface area is large and Since the wall is formed to be thin, geothermal heat can be easily transmitted to the inside of the pipe. The outer spiral tube 5
Above 1, a plurality of openings (holes) 51 a for allowing air from the gangue layer 2 to flow are formed.

In FIG. 8A, reference numeral 52 denotes a spiral band made of metal, for example, aluminum (or plastic). The spiral band portion 52 constitutes the “surface contact portion” of the present invention, and is formed, for example, by forming a band-shaped (or ribbon-shaped) aluminum sheet in a spiral shape (or a coil shape). ing. The spiral band portion 52 is installed and used inside the outer spiral tube 51 so as to contact (contact) the inner wall portion of the outer spiral tube 51. Therefore, the spiral band portion 52 is formed by the outer spiral tube 51.
From the ground, and is maintained at approximately the same temperature as the geothermal.

In FIG. 8 (a), reference numeral 53 denotes a plastic or metal inner spiral tube which is installed inside the spiral band 52. This inner spiral tube 53 is also the outer spiral tube 5.
Similar to 1, the cross section is wavy and the surface area is large,
Further, the thickness is formed thin.

As described above, in the second embodiment, the outer spiral tube 51 having good heat conduction efficiency because of its large surface area and small wall thickness, and the metal spiral band portion 52 having good heat conduction efficiency are provided. The inner spiral tube 53 having a large surface area and a small wall thickness and having good heat conduction efficiency forms a "double pipe".

In the second embodiment, the temperature of the outdoor air is adjusted by contact with the outer spiral tube 51 and the spiral band 52 (that is, the air is cooled in summer and cooled in winter). Warmed up). Also,
At the same time, the air is humidified by contacting the outer spiral tube 51 and the spiral band 52 (that is, moisture in the air is condensed on the surface of the spiral band 52 and the like in summer). While the air is dehumidified, the water attached to the surface of the spiral band 52 and the like is supplied to the air in the winter to humidify the air.) At the same time, the air is supplied to the outer spiral tube 51.
In addition, the air is purified by contact with the spiral band 52 (that is, the impurities in the air are removed by being adsorbed to the water on the surface of the spiral band 52 and the like). ). Note that the state of air movement in the underground pipe (the above-described double pipe) and the configuration other than the underground pipe in the second embodiment are the same as those described in the first embodiment, and a description thereof will be omitted. I do.

In each of the above embodiments, the underground pipes 5 and 6 are buried in land outside the building (land such as a garden or a parking lot outside the building (outdoor)). According to the present invention, the underground pipes 5 and 6 are buried in the ground inside the building, and the underground pipes 5 and 6 buried in the ground inside the building allow the air from outside to be geothermally heated. The heat-exchanged, moisture-conditioned and purified air may be sent to the cobblestone layer 2.

[0041]

As described above, in the building air-conditioning system using geothermal energy according to the present invention, heat exchange with geothermal energy is performed by underground pipes. Heat exchange can be performed with extremely high efficiency as compared with the related art. Further, in the present invention, since the air exchanged with the geothermal heat by the underground pipe is passed through the underfloor consolidation layer filled with the large number of the consolidation stones, the air is used as the underfloor consolidation stone. In the formation, it is conditioned and purified before being supplied into the building. That is, in the present invention, when high humidity summer air moves in the underfloor cobblestone layer,
The moisture contained in the air is condensed on the surface of the large number of quarries, and the air is dehumidified (humidified). Further, when the dry air in winter moves in the underfloor stone layer, the moisture adhering to the surface of the large number of stones is supplied to the air to humidify (humidify) the air. You will be Furthermore, impurities such as dust contained in the air moving in the underfloor stone layer are attached to the water present on the surface of the large number of stones, so that the air is cleaned. .

In the present invention, when the underground pipe is buried in the land outside the building, the underground pipe can be easily attached to an existing building later. Work for retrofitting (externally attaching) a building air-conditioning system using city heat according to the present invention to a building of the present invention can be performed extremely easily and at low cost. Also,
Since the underground pipe is arranged in the ground outside the building, maintenance such as repair or replacement of the underground pipe can be performed extremely easily and at low cost.

Further, in the present invention, by providing a surface contact portion in a gap between the outer pipe and the inner pipe constituting the underground pipe, air moving in the gap is applied to the surface contact portion. Due to the efficient contact, heat exchange with the geothermal heat of the air can be performed with extremely high efficiency, and humidity control and purification of the air can be performed. That is, in the present invention, when high humidity air in summer travels in the underground pipe, moisture contained in the air is condensed on the surface of the surface contact portion to dehumidify (humidify) the air. Is performed. Further, when the dry air in winter moves in the underground pipe, the moisture adhering to the surface of the surface contact portion is supplied to the air so that the air is humidified (humidified). Become. Further, in the present invention, impurities such as dust contained in the air moving in the underground pipe are attached to moisture existing on the surface of the surface contact portion, so that the air is cleaned. .

Further, in the present invention, at a part of the cobblestone layer, there is provided a cavity serving as a passage for sending air from the cobblestone layer into the building, and in this cavity,
The air from the cobblestone layer is provided with a substance that gives a predetermined scent to the air and deodorizes and purifies the air. Can be supplied inside.

In the present invention, when an abnormality such as a fire or gas leak occurs, the presence of the fan (constituting the air supply means of the present invention) and the air flow passage reduces the amount of smoke and harmful gas. Although it may spread to the entire building in time, the present invention includes an abnormal stop device for stopping the fan and stopping the operation of the system of the present invention in an emergency such as a fire or gas leak. Therefore, it is possible to prevent the possibility that smoke or harmful gas spreads over the entire building in an emergency in a short time.

[Brief description of the drawings]

FIG. 1 is a plan sectional view for explaining the overall configuration of a first embodiment of the present invention.

FIG. 2 shows an underground pipe, a perforated pipe,
It is sectional drawing which shows a cobblestone layer.

3A is a perspective view showing a part of an outer pipe of the underground pipe of the first embodiment, FIG. 3B is a partial longitudinal sectional view showing the outer pipe, and FIG. Perspective view showing a part of an inner pipe of an underground pipe, and FIG.
It is a plane sectional view showing an underground pipe.

FIG. 4 is a diagram for explaining a cobblestone layer and a cavity according to the first embodiment.

FIG. 5 is a diagram illustrating an operation in summer when the first embodiment is applied to a house.

FIG. 6 is a diagram illustrating an operation in winter when the first embodiment is applied to a house.

FIG. 7 is a block diagram for explaining an abnormal stop device provided in the system of the first embodiment.

FIG. 8 is a diagram illustrating a structure of an underground pipe according to a second embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Concrete foundation of building 2 Cobblestone layer 3 Perforated pipe 3a, 5c hole 4 Cavity part 5, 6 Underground pipe 5a, 6a Outer pipe 5b, 6b Inner pipe 5d Gap 5e Fin (surface contact part) 7, 9 Piping 8, 26 Fan 13 Mesh-shaped bag 51 Outside spiral tube 52 Spiral band (surface contact portion) 53 Inside spiral tube 92 Smoke sensor 93 Gas sensor 94 Fan motor 95 Microcomputer

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-60-263055 (JP, A) JP-A-8-74344 (JP, A) JP-A-57-268956 (JP, A) JP-A-57-6896 454 (JP, A) JP-A-8-312248 (JP, A) JP-A 7-44538 (JP, U) JP-A 60-151028 (JP, U) JP-A 57-195030 (JP, U) Japanese Utility Model Showa 58-16854 (JP, U) Japanese Utility Model Application Hei 4-46647 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) F24F 3/00 F24F 11/02 F24F 13/02 F24J 3/08

Claims (2)

(57) [Claims] 1. An underground pipe buried underground for taking in outdoor air and exchanging heat with the geothermal heat, and an underground pipe formed below the floor of the building having a diameter of several hundred mm. An underfloor cobble layer in which an underfloor space having a height is filled with a large number of cobblestones, and geothermal heat is accumulated in an air layer or the like in a minute gap between the plurality of cobblestones. And, from the underground pipe, `` air exchanged with geothermal heat in the underground pipe and cooled from the outdoors in summer and warmed from the outdoors in winter '' is taken into the inside, and the taken underground pipe is taken in. Underfloor stone layer for humidifying and purifying air from the air; air supply means for supplying air from the underfloor stone layer to the interior of the building; rising section of concrete foundation and the underfloor stone Formed in contact with layers And a cavity in which "air freshener, charcoal and tourmaline" is placed, wherein air from the underfloor cobblestone layer is formed in the wall. Taken into it through the hole made, and the taken-in air is converted into `` scented, deodorized and negatively ionized air '' by the `` fragrance, charcoal and tourmaline '', And a cavity for supplying the inside of the building through a hole formed in the floor. An air conditioning system for a building using geothermal energy. 2. The maintenance port according to claim 1, wherein the inspection port is formed on a floor above the cavity, and the maintenance of the cavity is performed such as replacing the “fragrance, charcoal and tourmaline”. An air conditioning system for buildings using geothermal energy, which has an inspection port for