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JP4902622B2 - Air conditioning system - Google Patents
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JP4902622B2 - Air conditioning system - Google Patents

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JP4902622B2
JP4902622B2 JP2008281708A JP2008281708A JP4902622B2 JP 4902622 B2 JP4902622 B2 JP 4902622B2 JP 2008281708 A JP2008281708 A JP 2008281708A JP 2008281708 A JP2008281708 A JP 2008281708A JP 4902622 B2 JP4902622 B2 JP 4902622B2
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政義 福井
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フクイ産業株式会社
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Description

本発明は、建物の各居室空間を、地熱を利用して快適温度に空調する空調システムに関する。   The present invention relates to an air conditioning system that air-conditions each living room space of a building to a comfortable temperature using geothermal heat.

居室空間内の空調には、従来から電力や燃料を利用する冷房システムや暖房システム広く用いられている。この冷房システムや暖房システムでは居住空間内を任意かつ急速に冷房または暖房して速やかに快適空間を得ることができる点で有利である。しかし、これらのいずれのシステムでも電力や燃料を消費するため,大きな経済的負担と資源の損失を招き、省資源に逆行する。特に厳寒時や猛暑時にはこうした経済的負担および損失が過大となり、好ましくない。   Conventionally, a cooling system and a heating system using electric power and fuel have been widely used for air conditioning in a living room space. This cooling system or heating system is advantageous in that a comfortable space can be quickly obtained by arbitrarily or rapidly cooling or heating the living space. However, since any of these systems consumes electric power and fuel, it causes a great economic burden and loss of resources, and goes against resource saving. Such economic burdens and losses are excessive, especially when it is extremely cold or extremely hot.

また、前記のような空調システムでは、空調によって居室空間内外の温度差が急速に変化することによって、壁面や窓ガラスに結露が発生したり、健康被害を招き易くなったりするという不都合があった。さらに、このような空調は、密閉空間での利用を前提とするため定期的に換気が必要になり、この換気による室温の急激な変化が避けられない。   In addition, the air conditioning system as described above has a disadvantage that the temperature difference between the inside and outside of the living room changes rapidly due to the air conditioning, which causes condensation on the wall surface and the window glass or easily causes health damage. . Further, since such air conditioning is premised on use in an enclosed space, ventilation is required regularly, and a sudden change in room temperature due to this ventilation is inevitable.

一方、これに対して、外気を地中に埋設した地下ダクトに導入し、この地下ダクト内で地熱によって熱交換した空気を建物の床下から居室空間内に引き込んだ後、居室空間外へ排出する空調システムが提案されている(例えば、特許文献1参照)。
特開平07−248130号公報
On the other hand, outside air is introduced into an underground duct buried in the ground, and the heat exchanged by geothermal heat in the underground duct is drawn into the living room space from under the floor of the building and then discharged outside the living room space. An air conditioning system has been proposed (see, for example, Patent Document 1).
JP 07-248130 A

しかしながら、前記従来の空調システムにあては、地中に埋設する地下ダクトが、熱伝導率の高い耐食製の金属からなる蛇腹状のパイプを層状に屈曲させた構成であるために、敷地の地中内に占める空間が大きいにも拘らず、パイプが層状に重なるために熱容量が比較的小さく、従って地熱の利用効率が悪いという不都合があった。また、地下ダクトがステンレスなどの金属材料を管状に成形したものからなり、これらが変形しないように屈曲加工および地中埋設する必要から、設置の作業効率が悪く、しかも設置コストが高くつくという不都合があった。   However, in the conventional air conditioning system, since the underground duct buried in the ground has a structure in which a bellows-like pipe made of corrosion-resistant metal having high thermal conductivity is bent in layers, In spite of the large space in the interior, the pipes are stacked in layers, so that the heat capacity is relatively small, and therefore the utilization efficiency of geothermal heat is poor. In addition, the underground duct is made of a metal material such as stainless steel formed into a tubular shape, and it is necessary to bend and embed in the ground so that they do not deform, so that the installation work efficiency is low and the installation cost is high. was there.

本発明は前記のような従来の問題点に着目してなされたものであり、既存の安価な管材を用いることで、地中への埋設または設置を安価かつ容易に実施できるとともに、熱交換効率が比較的高い空調を容易に実現できる空調システムを提供することを目的とする。   The present invention has been made paying attention to the conventional problems as described above, and by using an existing inexpensive pipe material, it is possible to embed or install in the ground at low cost and easily, and heat exchange efficiency It aims at providing the air-conditioning system which can implement | achieve comparatively high air conditioning easily.

前記目的達成のために、本発明にかかる空調システムは、地中に埋設した地下熱交換部に外気を吸入し、この地下熱交換部内で地熱を利用して熱交換した空気を建物の居室空間に引き込み、一方この居室空間の空気を居室空間外へ排気する空調システムであって、前記地下熱交換部は、天部が塞がれ、下端部がコンクリート基板上に支持された状態にて地中に埋設された、大径のコンクリート管、土管およびヒューム管のいずれかからなる第1の管体および第2の管体を備え、前記第1の管体および第2の管体は上下部の少なくとも2箇所で連結パイプにより相互に連結および連通され、前記第1の管体の前記天部には、上端が大気に開放し、他端が第1の管体内に開放し、かつ周囲に多数の吸気孔が設けられた吸気管が貫通するように取り付けられ、第2の管体の周壁には、一端が第2の管体内に開口し、他端には建物の居室空間に連通するダクトを接続する給気管が取り付けられて、
前記第1の管体内の空気温度よりも外気温が低い場合には、前記吸気管を通して前記第1の管体内へ外気を流入させ、この空気の流入により前記第1の管体内の空気(暖気)を前記第2の管体内に流入させ、前記第1の管体から第2の管体内への空気の流入によって、該第2の管体内の空気を前記ダクトを通して前記居室空間へ送り出すことを特徴とする。
In order to achieve the above object, an air conditioning system according to the present invention sucks outside air into an underground heat exchange section buried in the ground, and air exchanged using geothermal heat in the underground heat exchange section. In the air conditioning system, the air in the room space is exhausted to the outside of the room space, and the underground heat exchanging portion is grounded with the top portion closed and the lower end portion supported on the concrete substrate. Embedded with a first tube and a second tube made of any one of a large-diameter concrete tube, a soil tube and a fume tube, the first tube and the second tube being upper and lower parts Are connected and communicated with each other by a connecting pipe at at least two locations, the top of the first tubular body has an upper end opened to the atmosphere, the other end opened to the first tubular body, and Make sure that the intake pipe with many intake holes passes through it. Vignetting, the peripheral wall of the second tube, one end opening into the second tube body, the other end to supply pipe is attached to connect the duct communicating with the room space of a building,
Wherein when the first tube body outside air temperature is lower than the air temperature, the flow Toe enter the outside air into the first tubular body through the intake pipe, the first tubular body of the air by the inflow of air ( Warm air) flows into the second tubular body, and the air in the second tubular body is sent out to the living room space through the duct by the inflow of air from the first tubular body into the second tubular body. It is characterized by.

この構成により、外気を自然の流れに従って熱容量の大きい第1の管体内に取り込んで、地熱による所定温度の空気と効率的に熱交換し、この熱交換を行って暖められた空気を同じく熱容量の大きい第2の管体に貯留して、ここで再び十分に地熱に近い温度の空気温度に暖められることで、この熱交換した空気を建物の床下から側壁などに配したダクトを通して各居室空間に供給することができる。このため、各居室空間を、外気温度に比べて暖かい室温に空調することができる。 With this configuration, outside air is taken into the first pipe body having a large heat capacity according to a natural flow , and efficiently exchanges heat with air at a predetermined temperature by geothermal heat. The air heated by this heat exchange also has the same heat capacity. By storing it in a large second tube and heating it to an air temperature that is sufficiently close to geothermal heat here, this heat-exchanged air is passed through the ducts placed from the bottom of the building to the side walls, etc., into each room space. Can be supplied. Therefore, each room space, can be conditioned to room temperature paddle warm compared to the outside air temperature.

この場合において、第1の管体および第2の管体として、既存のコンクリート管、土管、ヒューム管のいずれかを選択して用いることができ、地中への埋設、設置作業が容易で、設備コストおよび施工コストを従来品に比べて格段に低く抑えることができる。   In this case, as the first tubular body and the second tubular body, any one of existing concrete pipes, earthen pipes, and fume pipes can be selected and used. Equipment costs and construction costs can be significantly reduced compared to conventional products.

また、本発明に掛かる空調システムは、地中に埋設した地下熱交換部に外気を吸入し、この地下熱交換部内で地熱を利用して熱交換した空気を建物の居室空間に引き込み、一方この居室空間の空気を居室空間外へ排気する空調システムであって、前記地下熱交換部は、天部が塞がれ、下端部がコンクリート基板上に支持された状態にて地中に埋設された、大径のコンクリート管、土管およびヒューム管のいずれかからなる第1の管体および第2の管体を備え、
前記第1の管体および第2の管体は上下部の少なくとも2箇所で連結パイプにより相互に連結および連通され、前記第1の管体の前記天部には、上端が大気に開放し、他端が第1の管体内に開放し、かつ周囲に多数の吸気孔が設けられた吸気管が貫通するように取り付けられ、前記第2の管体の周壁には、一端が第2の管体内に開口し、他端には建物の居室空間に連通するダクトを接続する給気管が取り付けられて、
前記第1の管体内の空気温度よりも外気温が高い場合には、小型の換気ファンにより前記吸気管を通して前記第1の管体内へ外気を流入させ、この空気の流入により該第1の管体内の空気(冷気)を前記第2の管体内に流入させ、前記第1の管体から第2の管体内への空気の流入によって、該第2の管体内の空気を前記ダクトを通して前記居室空間へ送り出すことを特徴とする。
In addition, the air conditioning system according to the present invention draws outside air into the underground heat exchange section buried in the ground, and draws the air heat-exchanged using the geothermal heat in the underground heat exchange section into the room space of the building. An air conditioning system that exhausts air in a living room to the outside of the living room, wherein the underground heat exchange part is buried in the ground with the top part closed and the lower end supported on a concrete substrate. A first pipe body and a second pipe body made of any of a large-diameter concrete pipe, a clay pipe and a fume pipe,
The first tube body and the second tube body are connected and communicated with each other by a connection pipe at at least two locations in the upper and lower parts, and the top of the first tube body is open to the atmosphere, The other end is open to the first pipe body, and an intake pipe having a large number of intake holes is provided therethrough so that one end is connected to the peripheral wall of the second pipe body. An air supply pipe that connects to a duct that opens into the body and communicates with the room space of the building is attached to the other end.
Wherein when the outside air temperature than the air temperature of the first tube body is high, Toe inflows outside air through the intake pipe by a small ventilation fan to the first tubular body, the first by the inflow of air Air in the tube (cold air) is caused to flow into the second tube, and air inflow from the first tube into the second tube causes the air in the second tube to pass through the duct. It is characterized by being sent out to the living room space.

この構成により、小型の換気ファンを用いて、外気を熱容量の大きい第1の管体内に取り込んで、地熱による所定温度の空気と効率的に熱交換し、この熱交換を行って冷やされた空気を同じく熱容量の大きい第2の管体に貯留して、ここで再び十分に地熱に近い低温度の空気温度に冷やすことで、冷やされた前記第1の管体内の空気温度よりも外気温が高い場合には、小型の換気ファンにより前記吸気管を通して前記第1の管体内へ外気を流入させ、この空気の流入により該第1の管体内の空気(冷気)を前記第2の管体内に流入させ、前記第1の管体から第2の管体内への空気の流入によって、該第2の管体内の空気を前記ダクトを通して前記居室空間へ送り出すことを特徴とする空気を建物の床下から側壁などに配したダクトを通して各居室空間に供給することができる。このため、各居室空間を、外気温度に比べて涼しい室温に空調することができる。 With this configuration, a small ventilation fan is used to take outside air into the first tube having a large heat capacity, efficiently exchange heat with air at a predetermined temperature by geothermal heat, and cool air that is cooled by performing this heat exchange. Is stored in a second tubular body having a large heat capacity, and then cooled again to a low-temperature air temperature sufficiently close to geothermal heat, so that the outside air temperature becomes lower than the cooled air temperature in the first tubular body. If it is high, outside air is caused to flow into the first tubular body through the intake pipe by a small ventilation fan, and air (cold air) in the first tubular body is caused to flow into the second tubular body by the inflow of this air. Inflow of air from the first pipe body into the second pipe body causes air in the second pipe body to be sent out to the living room space through the duct from the bottom of the building. Each through a duct on the side wall It can be supplied to the chamber space. For this reason, each living room space can be air-conditioned to a room temperature that is cooler than the outside air temperature .

また、本発明にかかる空調システムは、 前記第1の管体および第2の管体が、前記建物の基礎より内側の地中に埋設されていることを特長とする。   The air conditioning system according to the present invention is characterized in that the first tube body and the second tube body are buried in the ground inside the foundation of the building.

この構成により、建物の敷地が狭い場合でも狭い敷地内での空調システムの施工が可能になる。   With this configuration, it is possible to construct an air conditioning system in a narrow site even when the site of the building is small.

本発明によれば、既存の安価な管材を用いることで、地中への埋設または設置を安価かつ容易に実施できるとともに、設置コストが安価で、運転コストが掛からず、熱交換効率の高い空調を容易に実現できるという効果が得られる。   According to the present invention, an existing inexpensive pipe material can be used to embed or install in the ground at low cost and easily, and the installation cost is low, the operation cost is not applied, and the air conditioning has high heat exchange efficiency. Can be easily realized.

以下に、本発明の実施形態による空調システムを、図面を参照して詳細に説明する。   Hereinafter, an air conditioning system according to an embodiment of the present invention will be described in detail with reference to the drawings.

図1は、本発明の実施形態による空調システムの要部を示す断面図、図2は、この空調システムの設置例を示す説明図である。図1および図2において、本実施形態にかかる空調システムは、地下熱交換部を構成する大径の第1の管体1および第2の管体2を一組として形成され、これらが家屋の敷地の略同一レベルの地中に埋設されている。   FIG. 1 is a cross-sectional view showing a main part of an air conditioning system according to an embodiment of the present invention, and FIG. 2 is an explanatory view showing an installation example of the air conditioning system. In FIG. 1 and FIG. 2, the air conditioning system according to the present embodiment is formed as a set of a large-diameter first tubular body 1 and a second tubular body 2 constituting the underground heat exchange section, and these are the houses. It is buried in approximately the same level of the site.

この埋設深さは、地表から例えば200ミリ以上とされる。これらの第1の管体1および第2の管体2はいずれも内径が900ミリ以上、長さが1800ミリ以上の大容量のコンクリート管、土管およびヒューム管のいずれかから構成される。これらのコンクリート管、土管およびヒューム管は地熱容量を十分に確保できるサイズとされ、必要に応じてこれ以上のサイズとすることは任意である。   This embedding depth is, for example, 200 mm or more from the ground surface. Each of the first tube 1 and the second tube 2 is composed of a large-capacity concrete tube, earth tube, or fume tube having an inner diameter of 900 mm or more and a length of 1800 mm or more. These concrete pipes, earth pipes, and fume pipes are sized to ensure a sufficient geothermal capacity, and it is optional to make them larger than necessary.

さらに、第1の管体1および第2の管体2は上端部が天板(天部)3、4によってそれぞれ塞がれており、下端部は暑さ50ミリの板状のコンクリート基板5、6上に支持され、さらに地中に埋設されている。   Further, the first tube body 1 and the second tube body 2 are respectively closed at the upper end portions by top plates (top portions) 3 and 4 and the lower end portion is a plate-like concrete substrate 5 having a heat of 50 mm. , 6 and further buried in the ground.

第1の管体1の開口上部を塞ぐ天板3には、この天板3を貫通するように吸気管7が取り付けられている。この吸気管7は、例えば内径が100ミリで、天板3より下方の長さが例えば150ミリとされ、この第1の管体1内に臨む吸気管7の周囲には、多数の通気孔8が貫通するように穿接されている。   An intake pipe 7 is attached to the top plate 3 that closes the upper opening of the first tubular body 1 so as to penetrate the top plate 3. The intake pipe 7 has, for example, an inner diameter of 100 mm and a length below the top plate 3 of, for example, 150 mm. A number of ventilation holes are provided around the intake pipe 7 facing the first pipe body 1. 8 is penetrated so that it may penetrate.

これらの通気孔8は、例えば10〜15ミリで、20〜30個とされ、後述のように吸気管7内に取り込まれる外気を、その吸気管7の下端から放出するのみでなく、吸気管7の周囲から第1の管体内に略均等に拡散するように機能する。   These vent holes 8 are, for example, 10 to 15 mm and have 20 to 30 holes. As will be described later, not only the outside air taken into the intake pipe 7 is discharged from the lower end of the intake pipe 7 but also the intake pipe. 7 so as to diffuse substantially evenly from the periphery of 7 into the first tubular body.

また、吸気管7の上部および上端は地上に臨み、地上の外気を上端から吸入して第1の管体1内へ導入するように機能する。この吸気管7の上端部は逆U字状に曲折されて端部が下方に向き、この端部から吸気管7内への雨や雪などが入り込むのを防止している。   Further, the upper and upper ends of the intake pipe 7 face the ground, and function to suck the outside air on the ground from the upper end and introduce it into the first tubular body 1. The upper end portion of the intake pipe 7 is bent in an inverted U shape so that the end portion faces downward to prevent rain, snow, etc. from entering the intake pipe 7 from this end portion.

第1の管体1および第2の管体2には、上下部において互いに略水平方向に連通する連通管9、10が接続されている。これらの連通管9、10は第1の管体1および第2の管体2内に各端部が開口し、第1の管体1内で熱交換を行った空気を第2の管体2内に導入可能にしている。この場合において、上部の連通管9は第1の管体1および第2の管体2の上端より600ミリの深さに、また下部の連通管10は第1の管体1および第2の管体2の上端より1300ミリの深さに、それぞれ略水平に配置されている。なお、これらの連通管9、10の内径寸法は、例えば100ミリとされる。   Connected to the first tube body 1 and the second tube body 2 are communication tubes 9 and 10 that communicate with each other in the substantially horizontal direction at the upper and lower portions. These communicating pipes 9 and 10 are opened at the ends in the first pipe body 1 and the second pipe body 2, and the air that has undergone heat exchange in the first pipe body 1 is supplied to the second pipe body. 2 can be introduced. In this case, the upper communication tube 9 is 600 mm deep from the upper ends of the first tube body 1 and the second tube body 2, and the lower communication tube 10 is the first tube body 1 and the second tube body 2. They are arranged substantially horizontally at a depth of 1300 mm from the upper end of the tube body 2. The inner diameter of these communication pipes 9 and 10 is, for example, 100 mm.

さらに、第2の管体2には、これの上端からの高さが、例えば500ミリの位置に給気管11の一端が連結されている。この給気管11は第2の管体2との連結部から地上に向かって高くなるように、勾配をつけて地中に埋設され、上端は建物12の床下13に導かれている。   Furthermore, one end of the air supply pipe 11 is connected to the second pipe body 2 at a height of 500 mm, for example, from the upper end thereof. The air supply pipe 11 is buried in the ground with a gradient so that the air supply pipe 11 becomes higher toward the ground from the connecting portion with the second pipe body 2, and the upper end is led to the under floor 13 of the building 12.

この建物12は敷地内の基礎14上に設立され、床下13に臨む給気管11の先端には、建物12の外壁および内壁間の空隙(図示しない)と、屋根15および2階の天井間の空隙(屋根裏)17とに連続して配設されたダクト18の一端が接続されている。従って、給気管11を通る空気はダクト18を介して、その天井に設けられた給気孔19を通して、各室20内へ送り出される。なお、図示しないが、床下13で給気管11に繋がれるダクト18を2階の床と1階の天井との間に分岐させるようにして導き、この天井に設けられた給気孔(図示しない)から1階の各室20内へ送出可能にすることもできる。   This building 12 is established on the foundation 14 in the site, and at the tip of the air supply pipe 11 facing the floor 13, there is a gap (not shown) between the outer wall and the inner wall of the building 12 and the roof 15 and the ceiling of the second floor. One end of a duct 18 disposed continuously with the gap (attic) 17 is connected. Therefore, the air passing through the air supply pipe 11 is sent out into the chambers 20 through the air supply holes 19 provided in the ceiling via the duct 18. Although not shown, a duct 18 connected to the air supply pipe 11 at the lower floor 13 is led to be branched between the floor on the second floor and the ceiling on the first floor, and an air supply hole (not shown) provided in the ceiling is provided. Can be sent into each room 20 on the first floor.

なお、給気管11の地上に露出する部位とこの給気管11に接続されるダクト18の周囲には、それぞれ発泡材などの断熱材21が被覆されている。これにより、地熱によリ熱交換された第2の管体2内の空気が各室20内に導かれる前に、外気温度の影響を受けて温度上昇または下降することを回避することができる。   A portion exposed to the ground of the air supply pipe 11 and the periphery of the duct 18 connected to the air supply pipe 11 are each covered with a heat insulating material 21 such as a foam material. Thereby, before the air in the 2nd pipe body 2 reheat-exchanged by geothermal heat is guide | induced into each chamber 20, it can avoid that a temperature rises or falls under the influence of external temperature. .

かかる構成になる空調システムでは、第1の管体1および第2の管体2が、これらの内部の空気を地熱またはこの地熱に近い温度に維持するように熱変換する。従って、例えば、春、秋、冬の肌寒い時期には吸気管7内に空気の流れが生じ、外気(冷気)が吸気管内を第1の管体内に向って自然に下降する。そして第1の管体1内に吸入された外気は、第1の管体1内で地熱によって熱交換された温度またはこれに近い温度の空気と混合される。この混合気はさらに連通管9、10を通じて第2の管体2内に送り出され、この第2の管体2内の地熱に近い温度の空気に混合されて温度上昇する。 In the air conditioning system having such a configuration, the first tube body 1 and the second tube body 2 perform heat conversion so as to maintain the air inside thereof at geothermal heat or a temperature close to the geothermal heat. Therefore, for example, in the spring, autumn, and winter, when it is cold, air flows in the intake pipe 7, and the outside air (cold air) naturally falls in the intake pipe toward the first pipe. The outside air sucked into the first tube body 1 is mixed with the air temperature close to the temperature or which is heat-exchanged by the geothermal in the first tube within 1. Mixture This is further fed to the second tube body 2 through the communication pipe 9 and 10, the temperature is mixed in the air temperature rises close to the geothermal the second tube 2.

第1の管体1の容積と同様に、第2の管体2の容積も大きく、しかも熱容量が大きいコンクリート管や、土管や、ヒューム管などによって作られているため、第2の管体2内の空気温度は大きく変化しない。従って、この第2の管体2内に送り込まれた空気は、その地熱に近い温度に変換されて、給気管11へ導かれる。この給気管11は地中から地上に向かって傾斜しており、第2の管体2内の空気は地上方向へ流出する。つまり第2の管体2内で再び暖められ空気が給気管11を通って建物12の床下13に至る。 Similar to the volume of the first tube 1, the second tube 2 has a large volume and is made of a concrete tube, a clay tube, a fume tube, or the like having a large heat capacity. The air temperature inside does not change greatly. Therefore, the air sent into the second tubular body 2 is converted to a temperature close to the geothermal heat and guided to the air supply pipe 11. The supply pipe 11 is inclined toward the ground on the ground, the air of the second tubular body 2 flows out into the land on direction. That is, the air is reheated in the second tubular body 2, and the air passes through the air supply pipe 11 and reaches the underfloor 13 of the building 12.

また、この給気管11の上端は、断熱処理されたダクト18を通じて2階の天井に設けられた給気孔19から2階の各室20内や、1階の天井に設けられた給気孔(図示しない)を通じて1階の各室20内へ送り出される。これにより、各室20内は大気を地熱温度に近い温度に変換した空気によって暖房の空調がなされる。なお、各室20内で空調を行った空気は、ドアのアンダーカット部等や隙間などから居室空間外へ排出される。 In addition, the upper end of the air supply pipe 11 extends from an air supply hole 19 provided in the ceiling on the second floor through a duct 18 subjected to heat insulation to an air supply hole (illustrated) provided in each room 20 on the second floor or in the ceiling on the first floor. No) is sent into each room 20 on the first floor. Thus, within each chamber 20 the air-conditioning of the warm tufts are made by the air to convert the atmosphere to a temperature close to the geothermal temperature. Air that has been air-conditioned in each room 20 is discharged out of the room space through an undercut portion of the door or a gap.

従って、冬季には低温の大気を地熱に近い温度に暖めて、各室20内を暖房することができる。   Therefore, in the winter season, the interior of each room 20 can be heated by warming the low-temperature atmosphere to a temperature close to geothermal heat.

この場合において、前記空気の流れは、地上の冷気である外気が地下の第1の管体1内に自然に送り込まれることによって、その送り込まれた空気の容量分の第1の管体1内の空気を、第2の管体2、給気管11、ダクト18を介して各居室空間20に順に送り込まれる。このため換気ファンは使用されない。しかし、必要に応じて小型の換気ファンを一時的に併用することもできる。従って、このような空調方法によって、電力や化石燃料等を用いることなく、家屋の居室空間を最適温度に冷房持することができる。なお、夏季などには、吸気管を通じての地上から第1の管体1への気温の高い外気の移動がなくなり、第1の管体1および第2の管体それぞれの内部空気は滞留状態になる。このため夏季などのように外気温度が前記第1の管体1内の気温より高い場合には、小型の換気ファンを用いて、吸気管7からダクト18までの空気の流通経路内に空気の流れを積極的に作る。 In this case, the flow of the air is such that the outside air, which is cold air on the ground, is naturally sent into the underground first tubular body 1, whereby the capacity of the fed air is increased in the first tubular body 1. The air is sequentially fed into each living room space 20 through the second tubular body 2, the air supply pipe 11, and the duct 18. For this reason, a ventilation fan is not used. However, a small ventilation fan can also be used temporarily as needed. Therefore, by such an air conditioning method, without using the power and fossil fuels such as, a room space of the house can be cooling lifting the uppermost suitable temperature level. In summer and the like, there is no movement of high-temperature outside air from the ground to the first tubular body 1 through the intake pipe, and the internal air of each of the first tubular body 1 and the second tubular body is in a staying state. Become. For this reason, when the outside air temperature is higher than the temperature in the first tube body 1 such as in summer, air is introduced into the air flow path from the intake pipe 7 to the duct 18 using a small ventilation fan. Make the flow positive.

図3は、2008年8月7日〜9月9日の29日間での空調実験データを示す。これによれば、8月7日は天気が晴れで、午後3時半の外気温が25℃、地中の温度が16℃であるとき、本実施形態による空調システムによる給気孔(室内吹出し口)19の空気温度が18℃となる。また、このとき、1階および2階の北向きの室(居室空間)20では室内温度(内気温)がそれぞれ24℃および25℃、南向きの室20では室内温度がそれぞれ24℃、25℃、西向きの室20では室内温度がそれぞれ23℃、24℃となる。   FIG. 3 shows air conditioning experiment data for 29 days from August 7, 2008 to September 9, 2008. According to this, when the weather is clear on August 7, the outside air temperature at 3:30 pm is 25 ° C., and the underground temperature is 16 ° C., the air supply holes (indoor outlets) by the air conditioning system according to the present embodiment ) 19 air temperature is 18 ° C. Also, at this time, the room temperature (inside air temperature) in the north-facing room (room space) 20 on the first and second floors is 24 ° C. and 25 ° C., respectively, and the room temperature in the south-facing room 20 is 24 ° C. and 25 ° C., respectively. In the west facing room 20, the room temperature becomes 23 ° C. and 24 ° C., respectively.

一方、外気温が低い9月9日は天気が晴れで、午後4時半の外気温度が18.7度であるとき、本実施形態による空調システムによる給気孔19の空気温度が17℃となる。このときは、1階および2階の北向きの室20では室内温度がそれぞれ20℃および21℃、南向きの室20では室内温度がそれぞれ20℃、22℃、西向きの室20では室内温度がそれぞれ20℃、21℃となる。   On the other hand, when the outside air temperature is low on September 9 and the outside air temperature at 4:30 pm is 18.7 degrees, the air temperature of the air supply holes 19 by the air conditioning system according to this embodiment is 17 ° C. . At this time, the room temperature in the north facing room 20 on the first and second floors is 20 ° C. and 21 ° C., respectively, the room temperature in the south facing room 20 is 20 ° C. and 22 ° C., and the room temperature in the west facing room 20 is 20 ° C. 20 ° C. and 21 ° C., respectively.

これによれば、外気温が25℃〜18℃では、各室20の温度が20℃〜24℃の間で緩やかに変動し、安定した室内温度の環境が得られることが分かる。   According to this, it can be seen that when the outside air temperature is 25 ° C. to 18 ° C., the temperature of each chamber 20 varies gently between 20 ° C. and 24 ° C., and a stable indoor temperature environment can be obtained.

また、吸気管7に設けられる通気孔8は、この吸気管7を通じて大気が第1の管体1内に抵抗なく吸入、拡散可能なサイズおよび個数とすることが望ましい。さらに、第1の管体1と第2の管体2とを連通する連通管9、10を上下に設けることで、第1の管体1内の上位および下位にある低温および高温の空気を共に第2の管体2内に送り込んで、地熱温度に近い均一温度への熱変換を可能とすることができる。   Further, it is desirable that the ventilation holes 8 provided in the intake pipe 7 have a size and the number that allow the atmosphere to be sucked and diffused through the intake pipe 7 into the first tube 1 without resistance. Further, by providing upper and lower communication pipes 9 and 10 that communicate the first tubular body 1 and the second tubular body 2, low-temperature and high-temperature air at the upper and lower positions in the first tubular body 1 can be reduced. Both can be fed into the second tubular body 2 to enable heat conversion to a uniform temperature close to the geothermal temperature.

さらに、給気管11は傾斜管であるために、第2の管体2内の空気を自然に建物12の床下13からダクト18を通して上昇させるようにして各室20内に送り出すことができる。 Furthermore, it is possible to feed to the air supply pipe 11 is inclined tube, so as to increase in each chamber 20 through the duct 18 from the second tube 2 in the floor 13 of the air naturally building 12.

このように本実施形態による空調システムは、地下熱交換部を、天部が塞がれ、下端部がコンクリート基板6上に支持された状態にて地中に埋設された、大径のコンクリート管等の、第1の管体1および第2の管体2から構成し、第1の管体1および第2の管体2を上下部の少なくとも2箇所で連結パイプ9、10により連結および連通し、第1の管体1の天部に、上端が大気に開放し、他端が第1の管体1内に開放し、かつ周囲に多数の通気孔8が設けられた吸気管7が貫通するように取り付け、第2の管体2の周壁には、一端が第2の管体2内に開口し、他端が建物12の床下13を通って居室空間(室)20内に開口する給気管11を連設した構成を持つ。   As described above, the air conditioning system according to the present embodiment has a large-diameter concrete pipe embedded in the ground in a state in which the top is closed and the lower end is supported on the concrete substrate 6. The first tube body 1 and the second tube body 2 are connected to and communicated by the connection pipes 9 and 10 at at least two locations in the upper and lower parts. An intake pipe 7 having an upper end opened to the atmosphere and the other end opened into the first pipe 1 and provided with a number of vent holes 8 around the top of the first pipe 1 is provided. It is attached so as to penetrate, and one end opens in the second tube 2 on the peripheral wall of the second tube 2, and the other end opens in the living room space (room) 20 through the underfloor 13 of the building 12. It has the structure which provided the air supply pipe | tube 11 to connect.

従って、外気を熱容量の大きい第1の管体1内に取り込んで効率的に熱交換し、この熱交換を行った空気を同じく熱容量の大きい第2の管体2に一旦貯留し、さらに十分に地熱に近い温度に熱交換することで、この熱交換した地熱に近い温度の空気を建物12の床下13から側壁などに配したダクト18を通して各居室空間20内に供給することができる。このため、各居室空間20内は、外気温度に比べて低いかまたは暖かい室温に空調することができる。この結果、既存の安価な管材を用いることで、地中への埋設または設置を安価かつ容易に実施できるとともに、設置コストが安価で熱交換効率の高い空調を容易に実現できるものとなる。   Accordingly, outside air is taken into the first tubular body 1 having a large heat capacity and efficiently exchanged heat, and the air subjected to this heat exchange is temporarily stored in the second tubular body 2 having the same large heat capacity, and more fully. By exchanging heat to a temperature close to geothermal heat, air having a temperature close to that of the heat-exchanged geothermal heat can be supplied from the under floor 13 of the building 12 to each side space 20 through a duct 18 arranged on a side wall or the like. For this reason, each room space 20 can be air-conditioned to a room temperature that is lower or warmer than the outside air temperature. As a result, by using an existing inexpensive pipe material, it is possible to easily embed or install it in the ground at a low cost, and easily realize air conditioning with a low installation cost and high heat exchange efficiency.

本発明は、地中への埋設または設置を安価かつ容易に実施できるとともに、設置コストが安価で熱交換効率の高い空調を容易に実現できるという効果を有し、
建物の居住空間を省エネルギを維持しながら快適温度に空調する空調システム
等に有用である。
The present invention has the effect that it can be easily and inexpensively and easily embedded or installed in the ground, and can easily realize air conditioning with low installation cost and high heat exchange efficiency,
This is useful for an air conditioning system that air-conditions the living space of a building to a comfortable temperature while maintaining energy saving.

本発明の実施形態による空調システムを示す要部の断面図である。It is sectional drawing of the principal part which shows the air conditioning system by embodiment of this invention. 図1に示す空調システムの設置状態を示す説明図である。It is explanatory drawing which shows the installation state of the air conditioning system shown in FIG. 本発明の実施形態による空調システムを用いた空調実験の実験データを示す説明図である。It is explanatory drawing which shows the experimental data of the air conditioning experiment using the air conditioning system by embodiment of this invention.

符号の説明Explanation of symbols

1 第1の管体(地下熱交換部)
2 第2の管体(地下熱交換部)
3、4 天板(天部)
5、6 コンクリート基板
7 吸気管
8 通気孔
9、10 連通管
11 給気管
12 建物
13 床下
14 基礎
15 屋根
16 天井
17 空隙
18 ダクト
19 給気孔
20 居室空間(室)
21 断熱材
1 First tube (underground heat exchange section)
2 Second pipe (underground heat exchanger)
3, 4 Top plate (top)
5, 6 Concrete substrate 7 Intake pipe 8 Vent hole 9, 10 Communication pipe 11 Air supply pipe 12 Building 13 Under floor 14 Foundation 15 Roof 16 Ceiling 17 Void 18 Duct 19 Air supply hole 20 Living room space (room)
21 Insulation

Claims (3)

地中に埋設した地下熱交換部に外気を吸入し、この地下熱交換部内で地熱を利用して熱交換した空気を建物の居室空間に引き込み、一方この居室空間の空気を居室空間外へ排気する空調システムであって、
前記地下熱交換部は、天部が塞がれ、下端部がコンクリート基板上に支持された状態にて地中に埋設された、大径のコンクリート管、土管およびヒューム管のいずれかからなる第1の管体および第2の管体を備え、
前記第1の管体および第2の管体は上下部の少なくとも2箇所で連結パイプにより相互に連結および連通され、
前記第1の管体の前記天部には、上端が大気に開放し、他端が第1の管体内に開放し、かつ周囲に多数の吸気孔が設けられた吸気管が貫通するように取り付けられ、
第2の管体の周壁には、一端が第2の管体内に開口し、他端には建物の居室空間に連通するダクトを接続する給気管が取り付けられて、
前記第1の管体内の空気温度よりも外気温が低い場合には、前記吸気管を通して前記第1の管体内へ外気を流入させ、この空気の流入により前記第1の管体内の空気(暖気)を前記第2の管体内に流入させ、前記第1の管体から第2の管体内への空気の流入によって、該第2の管体内の空気を前記ダクトを通して前記居室空間へ送り出すことを特徴とする空調システム。
Outside air is sucked into the underground heat exchange section buried in the ground, and the heat exchanged using geothermal heat in this underground heat exchange section is drawn into the room space of the building, while the air in this room space is exhausted outside the room space. An air conditioning system
The underground heat exchanging section is composed of any one of a large-diameter concrete pipe, earth pipe and fume pipe embedded in the ground with the top portion closed and the lower end portion supported on the concrete substrate. Comprising one tube and a second tube;
The first tube body and the second tube body are connected and communicated with each other by a connection pipe at at least two locations in the upper and lower parts,
The top portion of the first tubular body has an upper end opened to the atmosphere, the other end opened to the first tubular body, and an intake pipe provided with a number of intake holes in the periphery passes therethrough. Attached,
An air supply pipe is attached to the peripheral wall of the second tubular body, and one end opens into the second tubular body, and the other end is connected to a duct communicating with the living room space of the building.
Wherein when the first tube body outside air temperature is lower than the air temperature, the flow Toe enter the outside air into the first tubular body through the intake pipe, the first tubular body of the air by the inflow of air ( Warm air) flows into the second tubular body, and the air in the second tubular body is sent out to the living room space through the duct by the inflow of air from the first tubular body into the second tubular body. An air conditioning system characterized by
地中に埋設した地下熱交換部に外気を吸入し、この地下熱交換部内で地熱を利用して熱交換した空気を建物の居室空間に引き込み、一方この居室空間の空気を居室空間外へ排気する空調システムであって、
前記地下熱交換部は、天部が塞がれ、下端部がコンクリート基板上に支持された状態にて地中に埋設された、大径のコンクリート管、土管およびヒューム管のいずれかからなる第1の管体および第2の管体を備え、
前記第1の管体および第2の管体は上下部の少なくとも2箇所で連結パイプにより相互に連結および連通され、
前記第1の管体の前記天部には、上端が大気に開放し、他端が第1の管体内に開放し、かつ周囲に多数の吸気孔が設けられた吸気管が貫通するように取り付けられ、
第2の管体の周壁には、一端が第2の管体内に開口し、他端には建物の居室空間に連通するダクトを接続する給気管が取り付けられて
前記第1の管体内の空気温度よりも外気温が高い場合には、小型の換気ファンにより前記吸気管を通して前記第1の管体内へ外気を流入させ、この空気の流入により該第1の管体内の空気(冷気)を前記第2の管体内に流入させ、前記第1の管体から第2の管体内への空気の流入によって、該第2の管体内の空気を前記ダクトを通して前記居室空間へ送り出すことを特徴とする空調システム。
Outside air is sucked into the underground heat exchange section buried in the ground, and the heat exchanged using geothermal heat in this underground heat exchange section is drawn into the room space of the building, while the air in this room space is exhausted outside the room space. An air conditioning system
The underground heat exchanging section is composed of any one of a large-diameter concrete pipe, earth pipe and fume pipe embedded in the ground with the top portion closed and the lower end portion supported on the concrete substrate. Comprising one tube and a second tube;
The first tube body and the second tube body are connected and communicated with each other by a connection pipe at at least two locations in the upper and lower parts,
The top portion of the first tubular body has an upper end opened to the atmosphere, the other end opened to the first tubular body, and an intake pipe provided with a number of intake holes in the periphery passes therethrough. Attached,
An air supply pipe is attached to the peripheral wall of the second tubular body, and one end opens into the second tubular body, and the other end is connected to a duct communicating with the living room space of the building .
Wherein when the outside air temperature than the air temperature of the first tube body is high, Toe inflows outside air through the intake pipe by a small ventilation fan to the first tubular body, the first by the inflow of air Air in the tube (cold air) is caused to flow into the second tube, and air inflow from the first tube into the second tube causes the air in the second tube to pass through the duct. An air conditioning system characterized by being sent out to the living room space.
前記第1の管体および第2の管体が、前記建物の基礎より内側の地中に埋設されていることを特長とする請求項1または請求項2に記載の空調システム。     The air conditioning system according to claim 1 or 2, wherein the first tube body and the second tube body are embedded in the ground inside the foundation of the building.
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