JP2012012769A - Solar light reflecting and heat insulating structure - Google Patents

Solar light reflecting and heat insulating structure Download PDF

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JP2012012769A
JP2012012769A JP2010147288A JP2010147288A JP2012012769A JP 2012012769 A JP2012012769 A JP 2012012769A JP 2010147288 A JP2010147288 A JP 2010147288A JP 2010147288 A JP2010147288 A JP 2010147288A JP 2012012769 A JP2012012769 A JP 2012012769A
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layer
shell
heat
reflection
sunlight
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JP5588239B2 (en
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Nobuo Sakuse
信夫 柵瀬
Yukinari Miyamae
行成 宮前
Hiroshi Ito
洋 伊藤
Yoshitaka Koshimura
吉隆 越村
Kazuhiko Miura
一彦 三浦
Boon Ken Lin
ブーン ケン リン
Hanako Nakamura
華子 中村
Manabu Yamamoto
学 山本
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Kajima Corp
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Abstract

PROBLEM TO BE SOLVED: To provide a fully durable solar light reflecting and heat insulating structure which is used at a part of a building requiring the improvement of reflecting and heat insulating effects for irradiation heat by the solar light, requires almost no maintenance, does not require a running cost, is capable of reducing power consumption needed for air conditioning since the solar light reflecting and heat insulating structure can be realized, is useful for Coreduction, and is capable of effectively utilizing shells that are generated in Japan and disposed as industrial waste taking huge time, labor and costs at present.SOLUTION: At the part to receive the irradiation heat, the shells 2 having a pearly layer 2a are laid in a layer structure shape so that the pearly layer 2a is turned to the reflection surface of the irradiation heat by the solar light.

Description

本発明は、太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位に用いる反射及び断熱構造体に関するものである。   The present invention relates to a reflection and heat insulation structure used for a part of a building or the like that needs to improve the reflection of heat and the heat insulation effect of sunlight.

一般に都市部では、コンクリート建築物が多く、また、道路などの路面はコンクリートやアスファルトで覆われている。これらのコンクリート面は、太陽熱によって温度が上昇し、夏期には例えば建築物の屋根で65〜70℃にも達することから、都市のヒートアイランド現象を引き起こす要因のひとつとなっている。   In general, there are many concrete buildings in urban areas, and road surfaces such as roads are covered with concrete or asphalt. These concrete surfaces rise in temperature due to solar heat and reach 65 to 70 ° C., for example, on the roof of a building in the summer, which is one of the factors causing the urban heat island phenomenon.

特に、コンクリート造の建物では、内部の温度も上昇するため、室内環境が悪化するうえ、冷房などの電力エネルギーの消費増加が問題となっている。   In particular, in a concrete building, the internal temperature also rises, so that the indoor environment is deteriorated and the consumption of electric power energy such as cooling is a problem.

このような建物の温度上昇問題の対策としては、様々な対策が提案され、反射率の高い塗料で塗装することにより、太陽熱を反射させる方法、水の気化熱で建築物を冷却する方法などである。このうち、塗料による方法では、熱線の入射量を減らす効果はあるが太陽熱により温まった物体を冷ます効果はない。   Various countermeasures have been proposed as countermeasures against the temperature rise problem of such buildings, such as a method of reflecting solar heat by painting with a highly reflective paint, a method of cooling buildings with the heat of vaporization of water, etc. is there. Of these methods, the paint method has the effect of reducing the amount of incident heat, but does not cool the object warmed by solar heat.

また、水の気化熱で建築物を冷却する方法には、打ち水をする方法、保水性のある材料を設ける方法、あるいは緑化する方法などがある。   Moreover, as a method of cooling a building with the heat of vaporization of water, there are a method of watering, a method of providing a material having water retention, a method of greening, and the like.

このうち、打ち水をする方法は効果が高いとして試みられているが、与えた水が流れ去るため、多量の水を必要とする上効果が持続しない。   Of these, the water spraying method has been tried because it is highly effective, but since the supplied water flows away, the effect of requiring a large amount of water is not sustained.

緑化する方法では、屋上緑化の施工に際しては、屋上のモルタル面にコンクリートによる植裁基盤を設け、躯体面から植裁基盤を完全に分離して、土壌を敷き詰めることが行われている。コンクリートには、ポルトランドセメントと単粒度の粗骨材で形成される連続空隙を備えたポーラス・コンクリートを用いることが一般的であり、植裁基盤とすべき法面打設後、保水性充填材として空隙部表面側にピートモス等の天然有機系材料を土とともに充填する。   In the method of revegetation, when planting rooftops, a concrete planting base is provided on the mortar surface of the roof, and the soil is spread by completely separating the planting base from the frame surface. For concrete, it is common to use porous concrete with continuous voids formed of Portland cement and single-grain coarse aggregate. As described above, a natural organic material such as peat moss is filled with the soil on the surface side of the gap.

保水性のある材料を設ける方法も種々提案されているが、下記特許文献1は、屋上を緑化した場合と同様な冷却・断熱効果を奏する透水性、保水性が優れた軽量なコンクリート舗装方法および保水性・透水性コンクリート・ブロックであり、強度を補う添加剤を添加することなく、粒度3〜20mmの軽石11、50〜62重量%とポルトランドセメント50〜38重量%との配合物に、水40〜50重量%を散布した混練した状態の保水性・透水性コンクリートからなる生コンクリートを敷き詰める。
特開2005−97884号公報
Various methods for providing water-retaining materials have also been proposed. However, Patent Document 1 listed below is a lightweight concrete pavement method with excellent water permeability and water retention that provides the same cooling and heat insulation effects as when the rooftop is greened. It is a water-retaining and water-permeable concrete block, and without adding an additive that supplements the strength, water is added to a blend of 11 to 50% pumice with a particle size of 3 to 20 mm and 50 to 38% by weight of Portland cement. Spread ready-mixed concrete made of water-retaining and water-permeable concrete in a kneaded state with 40-50% by weight dispersed.
JP-A-2005-97884

特許文献1では、保水性・透水性コンクリートを打設する際に、多数の小穴をあけた合成樹脂製のパイプを埋設しておき、乾燥したときに、このパイプに水を注入することにより、保水性・透水性コンクリートに水を含浸させる。使用する水として、貯水槽に貯えた雨水などを使用すればよいとされる。   In Patent Document 1, when placing water-retaining and water-permeable concrete, a synthetic resin pipe having a large number of small holes is buried, and when it is dried, water is poured into this pipe, Impregnate water retaining and water permeable concrete with water. It is said that rain water stored in a water tank may be used as water to be used.

下記特許文献2は、特に屋上保冷に好適であり、軽量でかつ遮光性と保冷性などを有した素材により形成され、コストの低減化やメンテナンスフリー化に優れた屋上保冷に最適な保水・保冷・断熱用パネルとして提案されたものである。
特開2009−57811号公報
The following Patent Document 2 is particularly suitable for rooftop cooling, and is formed of a material that is lightweight and has light-shielding properties and cooling properties, and is ideal for rooftop cooling that is excellent in cost reduction and maintenance-free.・ It has been proposed as a thermal insulation panel.
JP 2009-57811 A

この特許文献2は、太陽光を反射させる素材を主成分として形成される遮光層と、保水性と保冷性と断熱性とを兼ね備えた素材を主成分とすると共に、保水性・保冷性・断熱性・強度性を兼ね備えた補強助剤を混入して低蓄熱性固化で固化した保水冷却断熱層とよりなり、かつ吸水性・通気性・放湿性を備える対流促進機能を有する積層体と、また、有孔あるいは穿孔された木質板あるいは吸放湿性のある竹メッシュなどである底板とを備える積層体、また、景観性、強度補強性、遮光性、放湿冷却性、芳香性のある人工植物を備える積層体である。   This Patent Document 2 is mainly composed of a light-shielding layer formed mainly of a material that reflects sunlight, and a material that has both water retention, cold insulation, and heat insulation, as well as water retention, cold insulation, and heat insulation. A laminated body having a convection-promoting function having water absorption, breathability, and moisture release properties, and a water retention / cooling heat insulation layer that is solidified by solidification by low heat storage solidification by mixing a reinforcing aid that has both strength and strength. , A laminated body comprising a perforated or perforated wood board or a bottom board such as a bamboo mesh with moisture absorption / release properties, and also an artificial plant with landscape, strength reinforcement, light shielding properties, moisture release cooling properties, and aromaticity It is a laminated body provided with.

なお、貝殻で、真珠の養殖に使ったアコヤ貝、ホタテやカキなどの中身を収穫した残りの貝殻は、有効な再利用手段が極めて限られ、その大部分は産業廃棄物として処理コストを費やし処分されているのが実情である。   The remaining shells harvested from pearl oysters, scallops, oysters, etc. used for pearl cultivation are extremely limited in terms of effective reuse, and most of them are treated as industrial waste. The fact is that it has been disposed of.

下記特許文献3には、このような貝殻の有効利用を図るものとして、アスファルトコンクリート舗装及びセメント舗装において、蠣等の貝殻を適度な大きさに粉砕し、高温処理を施して砂利、砕石、砂等の骨材の代わりとして用いるものが提案されている。
特開昭47−24139号公報
In Patent Document 3 below, in order to effectively use such shells, shells such as firewood are pulverized to an appropriate size in asphalt concrete pavement and cement pavement, and subjected to high temperature treatment to produce gravel, crushed stone, sand The thing used as a substitute of aggregates, such as these, is proposed.
JP 47-24139 A

前記従来の屋上の高温化防止方法では、遮熱・反射系塗料などの塗装による方法を除けば、屋上緑化のように保水を前提とした根保持基盤、また、ポーラス状の吸水・保水する材料を屋上や屋根に設置し、保水層による遮熱効果を利用して高温化防止する仕組みが一般的になっている。   In the conventional rooftop high temperature prevention method, except for methods such as heat-shielding / reflective coating, a root-holding base that assumes water retention like rooftop greening, and a porous water-absorbing / water-retaining material Is installed on the rooftop and roof, and a mechanism to prevent high temperatures by using the heat shielding effect of the water retaining layer has become common.

これらの保水層は、水分保持のために一定の厚さが必要で、また、水分保持の必要上、重量が自ずと増加する傾向がある。ところが一般に建築物の天井部・屋上部に過重な重量物を設置することは好ましくなく、かといって重量を制限しようとすると水分保持量が減り、遮熱効果が低下するという問題が生ずる。そして最大の問題は、水分はいずれ蒸発して遮熱効果が低下する為、水の供給が常時必要で、その装置の設置、維持管理が必要となり経費もかかる。   These water retaining layers need a certain thickness for retaining moisture, and the weight tends to increase due to the necessity of retaining moisture. However, in general, it is not preferable to install an excessively heavy object on the ceiling or roof of a building. However, if the weight is to be limited, the amount of moisture retained decreases and the heat shielding effect decreases. And the biggest problem is that moisture will eventually evaporate and the heat shielding effect will decrease, so water supply will always be required, and installation and maintenance of the equipment will be required, which will be expensive.

さらに保水を行う問題点は、晴天が継続すると、保水層に残った水分が熱蓄積を起こし、保水層全体が高温化し、その高温が屋上床面に伝導してしまい、かえって遮熱効果が低下することである。   The problem with water retention is that if the weather continues, moisture remaining in the water retention layer will accumulate heat, the entire water retention layer will become hot, and the high temperature will be conducted to the rooftop floor surface, which in turn will reduce the heat shielding effect. It is to be.

これに加えて、ポーラス状の吸水・保水する材料としては、ポーラス・コンクリートが一般であるが、ポーラス・コンクリートは、セメントと砕石などの天然骨材を使用しているので重量が重く材料の運搬、取り扱い、施工が不便である。   In addition, porous concrete is generally used for porous water absorption / retention, but porous concrete is made of natural aggregate such as cement and crushed stone. , Handling and construction are inconvenient.

前記特許文献1のポルトランドセメントは、強アルカリ性で植物の種子の発芽を妨げたり、充填した植物繊維や種子などが雨水で流失しやすい。   The Portland cement of Patent Document 1 is strongly alkaline and prevents the germination of plant seeds, or the plant fibers and seeds filled are easily washed away by rainwater.

また、屋上の緑化に際しては屋上に対する荷重や排水を特に考慮する必要があるが、現実問題として既存のビルの屋上緑化においては、建築基準法等の規制により屋上に設置できる重量に一定の制限が課せられ、過度の積載は不可能である。また、ビル等の屋上部は、空調設備やビル外壁清掃用のレール等により十分なスペースが無く、排水等の設備設置には不都合であることが多い。   In addition, it is necessary to take into consideration the load and drainage on the rooftop when greening the rooftop, but as a matter of fact, in the case of rooftop greening of existing buildings, there is a certain limit on the weight that can be installed on the roof due to regulations such as the Building Standard Law. Imposed and overloading is impossible. In addition, the rooftop of a building or the like does not have sufficient space due to air conditioning equipment, rails for cleaning the outer wall of the building, etc., and is often inconvenient for installation of equipment such as drainage.

そのために、このような場所を緑化する際には、可能な限り荷重を制限し、排水等の設備も最小限に抑える必要がある。   Therefore, when greening such a place, it is necessary to limit the load as much as possible and to minimize facilities such as drainage.

また、植裁のためには土壌の水分の排出経路を確保する必要があり、植裁を囲む壁の下部に、適宜排水口を設け、土壌の流出を防ぐために網で排水口を覆うなどの手段を設けている。   In addition, it is necessary to secure a drainage route for soil for vegetation, and an appropriate drainage port is provided in the lower part of the wall surrounding the planting, and the drainage port is covered with a net to prevent the outflow of soil. Means are provided.

しかし、このような方法では排水効率が悪く、排水口を網で覆っているとはいえ土壌からの塵埃をすべて遮断することは不可能であり、屋上に設けたドレインの詰まりを頻発させるという問題があった。   However, with such a method, drainage efficiency is poor, and even though the drain outlet is covered with a net, it is impossible to block all dust from the soil, and the drain on the roof is frequently clogged. was there.

水の供給設備を必要とする場合、水貯留による屋上への静荷重増加が問題となることもあり、散水装置を有しない雨水貯留タイプは、雨水供給が途絶し半乾燥状態となると、粒状物による層内の水蒸気により、熱蓄積が発生し、かえって冷却作用が阻害される欠点もある。   When water supply facilities are required, an increase in static load on the roof due to water storage may become a problem.For rainwater storage types that do not have a sprinkler, rainwater supply is interrupted and the product becomes semi-dry. Due to the water vapor in the layer, heat accumulation occurs and the cooling action is hindered.

なお、特許文献3の貝殻を利用した舗装道路構築法は、貝殻を骨材として使用することで有効利用を図ろうとするものであり、冷却・断熱効果を期待するものとは全く無関係である。   In addition, the paved road construction method using the shell of Patent Document 3 is intended to be effectively used by using the shell as an aggregate, and is completely unrelated to the expectation of the cooling and heat insulation effect.

本発明の目的は前記従来例の不都合を解消し、太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位に用いる反射及び断熱構造体であって、メンテナンスが殆ど不要で、ランニングコストも掛らず、耐久性に富む太陽光の反射及び断熱構造体を提供することにある。   The object of the present invention is a reflection and heat insulation structure used for a part of a building or the like that eliminates the disadvantages of the conventional example and needs to improve the reflection and heat insulation effect of irradiation heat by sunlight, and requires almost no maintenance. Thus, it is an object to provide a sunlight reflecting and heat insulating structure having high durability without running costs.

請求項1および2記載の本発明は前記目的を達成するため、太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位に用いる反射及び断熱構造体であって、照射熱を受ける部位に、真珠層を有する貝殻を、その真珠層を太陽光による照射熱の反射面となるように、かつ層構造状に敷設したこと、太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位が、建築物の屋上・表面、室外空調機の表面もしくは周辺のいずれかであることを要旨とするものである。   In order to achieve the above object, the present invention according to claims 1 and 2 is a reflection and heat insulation structure used for a part of a building or the like that needs to improve the reflection and heat insulation effect of irradiation heat by sunlight. The shell that has a pearl layer at the part that receives heat is laid in a layered structure so that the pearl layer becomes a reflection surface of the irradiation heat by sunlight, the reflection of the irradiation heat by sunlight and the heat insulation effect The gist is that the part of the building or the like that needs to be improved is either the roof / surface of the building, the surface of the outdoor air conditioner, or the surrounding area.

請求項1および2記載の本発明によれば、
(1)貝殻の比重が比較的軽い(概ね1.5〜2程度)ため、照射熱を受ける建築物等の部位(例えば屋上、屋根)等に敷設しても重量増加が軽微であり、構造物に与える構造的負荷は事実上無視し得る範囲に留まる。
(2)概ね白色を基調とする色調を有する貝殻の真珠層が照射熱を高い効率で反射することで反射・断熱効果が向上する。
(3)層構造状に敷設する貝殻相互の接触が点接触状態となり、層構造の上層・下層間の貝殻を媒体とする熱伝導が妨げられ、貝殻が覆う部位の温度上昇を抑制できる。また、下層の貝殻と建築物等の部位が直に接する状態も点接触となり、水分の滞留が生じにくく、腐食等の建築物等へのダメージが防止できる。
(4)貝殻の層構造間の空気層が、以下の理由から、夏期には屋上、屋根等に対する冷却層として、冬期には保温層として作用する。夏期には、貝殻層の表層側が照射熱で温められ、貝殻層の下層側(屋上、屋根等の側)から上層側に向かう上昇気流が発生する。この上昇気流は、下層側に新鮮な外気(酷暑季でも概ね35℃以下)を常に送り込むことにより空冷作用を生じ、貝殻層の下層側に接する構造物表面の温度上昇を抑制できる。
一方、冬期には、貝殻の層構造間の空気層が断熱層として作用すると共に、冷気が屋上、屋根等に直接接触して生ずる冷却作用を阻害することで、構造物表面からの熱放散が抑止され、温度低下が生じにくいという効果を生ずる。
According to the present invention as set forth in claims 1 and 2,
(1) Since the specific gravity of the shell is relatively light (approximately 1.5 to 2), the weight increase is slight even if it is laid on a part of the building (such as the rooftop or roof) that receives irradiation heat. The structural load on the object remains practically negligible.
(2) The reflection and heat insulation effect is improved by the nacreous layer of the shell having a color tone based on white in general reflecting the irradiation heat with high efficiency.
(3) The mutual contact between the shells laid in the layer structure becomes a point contact state, the heat conduction using the shell between the upper layer and the lower layer of the layer structure as a medium is hindered, and the temperature rise at the portion covered by the shell can be suppressed. In addition, a state where the lower shell and the part such as a building are in direct contact also becomes a point contact, and it is difficult for moisture to stay and damage to the building such as corrosion can be prevented.
(4) The air layer between the layer structures of the shells acts as a cooling layer for rooftops, roofs, etc. in summer and as a heat insulation layer in winter for the following reasons. In the summer, the surface layer side of the shell layer is heated by irradiation heat, and an upward airflow is generated from the lower layer side (the roof, roof, etc.) to the upper layer side. This updraft causes air cooling by constantly sending fresh outside air (generally 35 ° C. or less even in extreme heat) to the lower layer side, and can suppress the temperature rise of the structure surface in contact with the lower layer side of the shell layer.
On the other hand, in the winter season, the air layer between the shell structure acts as a heat insulation layer, and the cooling effect caused by the direct contact of cold air with the rooftop, roof, etc. prevents heat dissipation from the surface of the structure. It is restrained and produces an effect that the temperature is hardly lowered.

請求項3記載の本発明は、真珠層を有する貝殻は、その断面形状が略板状または凹状であることを要旨とするものである。   The gist of the present invention described in claim 3 is that the shell having a pearl layer has a substantially plate-like or concave cross-sectional shape.

請求項3記載の本発明によれば、断面が略板状または凹状の形状を有する貝殻を用いることにより、建築物等の部位に対する効率的な被覆が可能となり、照射熱に対する反射効果が向上する。   According to the third aspect of the present invention, by using a shell having a substantially plate-like or concave cross-section, it is possible to efficiently cover a part such as a building, and the reflection effect on irradiation heat is improved. .

請求項4記載の本発明は、貝殻が形成する層構造は、排水・通風手段を有する保持体で、該層構造を維持するように囲まれることを要旨とするものである。   The gist of the present invention described in claim 4 is that the layer structure formed by the shell is surrounded by a holding body having drainage / ventilating means so as to maintain the layer structure.

請求項4記載の本発明によれば、排水・通風手段を有する保持体で、貝の層構造を保持することにより、風圧や雨水流下の外力、カラス等の鳥類による貝の持ち去り等による、層構造の破壊が防止できる。   According to the fourth aspect of the present invention, by holding the shell layer structure with the holding body having drainage / ventilation means, by wind pressure, external force under the rainwater flow, taking away the shell by birds such as crows, etc., The destruction of the layer structure can be prevented.

請求項5記載の本発明は、貝殻は、その表面から裏面に貫通する孔部が設けられることを要旨とするものである。   The gist of the present invention described in claim 5 is that the shell is provided with a hole penetrating from the front surface to the back surface.

請求項5記載の本発明によれば、貝殻に表面から裏面に貫通する孔部が設けることにより、貝殻の凹部に滞留する水分の排水が促され反射機能の低下が防止できると共に、孔部に気流が通過することで貝殻の層構造に気流通過が生じる。これにより、夏期における屋上・屋根等の建築物からの部位からの水分蒸発がもたらす潜熱を効果的に発散できることから、潜熱滞留による屋上、屋根等の温度上昇を防止できる。   According to the fifth aspect of the present invention, by providing a hole penetrating from the front surface to the back surface in the shell, drainage of water staying in the concave portion of the shell can be promoted, and a reduction in the reflection function can be prevented, and the hole The passage of the air current causes the passage of the air current in the layer structure of the shell. Thereby, since the latent heat which the water | moisture content evaporates from parts from buildings, such as a rooftop and a roof, in summer can be effectively dissipated, the temperature rise of a rooftop, a roof, etc. by latent heat retention can be prevented.

請求項6記載の本発明は、層構造を維持する保持体と連続する線材が、貝殻の表面から裏面に貫通する孔部に挿通されることを要旨とするものである。   The gist of the present invention described in claim 6 is that the wire that is continuous with the holding body that maintains the layer structure is inserted into a hole that penetrates from the front surface of the shell to the back surface.

請求項6記載の本発明によれば、貝殻の層構造を維持する保持体に連続する線材が、貝殻の表面から裏面に貫通する孔部に挿通されることにより、保持体による貝殻の層構造への拘束効果が高まり、層構造内での貝殻の偏り発生等の不具合を解消でき、層構造の一層確実な保持が実現できる。   According to the sixth aspect of the present invention, the wire layer continuous to the holding body that maintains the layer structure of the shell is inserted into the hole that penetrates from the front surface to the back surface of the shell, so that the layer structure of the shell by the holding body is achieved. The effect of restraining to the height can be enhanced, problems such as the occurrence of shell bias in the layer structure can be solved, and the layer structure can be more reliably maintained.

以上述べたように本発明の太陽光の反射及び断熱構造は、メンテナンスが殆ど不要で、ランニングコストも掛らず、耐久性に富むもので、太陽光の反射及び断熱構造を実現できることから空調に要される電力量を削減でき、Co削減に資するものである。 As described above, the sunlight reflection and heat insulation structure of the present invention requires almost no maintenance, has no running cost, has high durability, and can realize the sunlight reflection and heat insulation structure for air conditioning. The amount of electric power required can be reduced, which contributes to CO 2 reduction.

また、現在、日本国内で発生し、膨大な手間とコストを費やし産業廃棄物として処理されている貝殻の有効な活用を図ることが出来るものである。   In addition, it is possible to effectively utilize the shells that are currently generated in Japan and are processed as industrial waste by spending enormous labor and cost.

以下、図面について本発明の実施の形態を詳細に説明する。図1は、本発明の太陽光の反射及び断熱構造体の1実施形態を示す縦断側面図で、図中1は、太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位としての屋上床で、これにはコンクリート面やシート防水等が多い。5は天井部、6は室内である。   Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a longitudinal side view showing an embodiment of the sunlight reflection and heat insulation structure of the present invention. In the figure, reference numeral 1 denotes a building or the like that needs to improve the reflection and heat insulation effect of irradiation heat by sunlight. This is a rooftop floor as a part of the floor, and there are many concrete surfaces and waterproof sheets. 5 is a ceiling part, and 6 is a room.

本発明は、真珠層2aを上面(太陽光の入射方向)に向けた貝殻敷設層、一例としてホタテの貝殻2を2層以上の層状にしたものを、照射熱を受ける部位である屋上床1上に敷設した。   In the present invention, a shell laying layer in which the pearl layer 2a is directed to the upper surface (incoming direction of sunlight), for example, a scallop shell 2 formed into two or more layers, a roof floor 1 that is a part that receives irradiation heat 1 Laid on top.

貝殻2は、貝殻内側に真珠層2aを持ち、比重1.5程度で、本発明では図2に示すように直径5〜20cmの平板・皿状物を使用する。   The shell 2 has a pearl layer 2a inside the shell, has a specific gravity of about 1.5, and in the present invention, a flat plate or dish having a diameter of 5 to 20 cm is used as shown in FIG.

真珠層2aは、別名真珠母(しんじゅぼ)とも称され、貝類の内側に付いており、貝殻の外套膜から分泌する炭酸カルシウムを主成分とする、無機質と有機質とからなる光沢物質である。   The pearl layer 2a is also called a pearl mother, and is attached to the inside of the shellfish, and is a glossy substance composed of inorganic and organic substances mainly composed of calcium carbonate secreted from the shell membrane of the shell. .

本発明における真珠層2aを有する貝殻2は、二枚貝であれば特に限定されないが、建築物等の部位を覆うことから、ホタテ・カキ・ヒオウギ・アコヤ・イタヤ・ホッキ・アワビ、等の比較的広い平面形状を有する貝殻が好適である。   The shell 2 having the pearl layer 2a in the present invention is not particularly limited as long as it is a bivalve, but covers a part of a building or the like, so that it is relatively wide such as scallops, oysters, higi, Akoya, Itaya, hokkiki, abalone, etc. A shell having a planar shape is preferred.

さらに、この貝殻2の平板・皿状物の中央部分に排水・通風用の貫通孔3を形成し、排水・通風手段を有するものとした。   Furthermore, a through-hole 3 for drainage / ventilation is formed in the central portion of the flat plate / dish of the shell 2, and drainage / ventilation means are provided.

該貫通孔3の形成は、貝殻2の断面形状が略板状の場合はその略中央部分、断面形状が凹状の場合はその底部部分が好ましい。   The through-hole 3 is preferably formed at a substantially central portion when the cross-sectional shape of the shell 2 is substantially plate-shaped and at a bottom portion when the cross-sectional shape is concave.

また、層構造の貝殻2の上面は、貝殻の層構造維持と飛散防止のために飛散防止ネット4で覆う。この飛散防止ネット4としては、フェンス用等の合成樹脂製ネット(ポリエステル等)や漁網、カラス等の鳥避け網等が利用できる。   Further, the upper surface of the layered shell 2 is covered with a scattering prevention net 4 for maintaining the layer structure of the shell and preventing scattering. As the scattering prevention net 4, a synthetic resin net (such as polyester) for a fence, a fishing net, a bird avoidance net such as a crow, or the like can be used.

図3に示すように、層構造の貝殻2を固定枠12内に収め、この固定枠12の上面開口を飛散防止ネット4で閉塞してもよい。固定枠12には脚12aをつけ、固定枠と屋上床等の間隔を保持して、排水と通気を行う。   As shown in FIG. 3, the shell 2 having a layer structure may be housed in a fixed frame 12, and the upper surface opening of the fixed frame 12 may be closed with a scattering prevention net 4. Legs 12a are attached to the fixed frame 12, and the space between the fixed frame and the rooftop is maintained to drain and vent.

さらに、図4に示すように、貝殻2に施した孔13を用いて貝殻2を結束紐7で連結し一体物として、それを積層にし、固定することにより、前記飛散防止ネット4なしに、貝殻の層構造維持を図り、かつ、飛散防止を図ることもできる。結束紐7には針金、ワイヤー、布紐、耐久性に富む合成樹脂性(ポリエステル等)のロープ等が利用できる。   Further, as shown in FIG. 4, the shell 2 is connected with a binding string 7 using a hole 13 provided in the shell 2, and is laminated and fixed, thereby eliminating the scattering prevention net 4. It is possible to maintain the layer structure of the shell and prevent scattering. For the binding string 7, a wire, a wire, a cloth string, a durable synthetic resin (polyester or the like) rope, or the like can be used.

また、他の実施形態として図5に示すように、貝殻2を積層した状態でネット袋8に収容し、そのネット袋8を敷設し、並べたネット袋8同士を結束具14で結束して連結し、全体を一体物とする。   As another embodiment, as shown in FIG. 5, the shell 2 is housed in a net bag 8 in a stacked state, the net bag 8 is laid, and the net bags 8 arranged side by side are bound by a binding tool 14. Connect them together to make the whole one.

このようにして貝殻2による平板・皿状物の貝殻敷設層は、図1に示すように、上層αを遮熱層、中層βを熱伝導阻害層、そして積層空間をなす空気層γとして構成する。   As shown in FIG. 1, the shell laying layer of the flat plate / dish-like material by the shell 2 is configured as an upper layer α as a heat shielding layer, an intermediate layer β as a heat conduction inhibiting layer, and an air layer γ forming a laminated space. To do.

層状での各貝殻相互の接触面は点もしくは断続した線で構成され、各貝殻の外面70%以上が非接触面で空気に直接触れる構造となっている。   The contact surface between the shells in the form of layers is composed of dots or intermittent lines, and more than 70% of the outer surface of each shell is in direct contact with the air on the non-contact surface.

次に使用方法および作用について説明する。貝殻敷設層を構成する各貝殻の接触点では、上層αである遮熱層において太陽の直射を受ける表面の熱(40〜45℃)は、その伝導が次層の中層βとの接触部位である点部分もしくは断続した線部分に集中するが、その面積が小さいため、伝導熱量が低減して温度が低下(35〜40℃)する。また貝殻2の孔を通じて空気中に熱が放出される。   Next, the method of use and operation will be described. At the contact point of each shell constituting the shell laying layer, the heat (40-45 ° C) of the surface that receives direct sunlight from the heat shielding layer, which is the upper layer α, is conducted at the contact point with the middle layer β of the next layer. Although it concentrates on a certain point part or the intermittent line part, since the area is small, the amount of conduction heat reduces and temperature falls (35-40 degreeC). Further, heat is released into the air through the hole of the shell 2.

上層α自体は高温となることにより貝殻敷設層内に上昇気流が生じ、上層αより上空へ放熱され、その空気の流れによって熱伝導阻害層をなす中層β、積層空間をなす空気層γの低温空気(35℃以下)が貝殻敷設層内を下方から上方に向けて通過し、冷却効果が起きる。   As the upper layer α itself becomes hot, an upward air flow is generated in the shell laying layer, and heat is dissipated from the upper layer α to the sky, and the low temperature of the middle layer β forming the heat conduction inhibition layer and the air layer γ forming the laminated space by the air flow. Air (35 ° C. or lower) passes through the shell laying layer from the bottom to the top, and a cooling effect occurs.

屋上床1、もしくは屋根面への貝殻の接触も、貝殻同士と同様、点もしくは不連続の線で構成され、屋上床面の70%以上が空気に直接触れる構造となっている。   Like the shells, the shells contact the rooftop 1 or the roof surface with dots or discontinuous lines, and 70% or more of the rooftop floor is in direct contact with the air.

熱伝導阻害層をなす中層βは、遮熱層をなす上層αを支持するので上層αからの熱伝導を受けるが、接触面が小さいことで、屋上床1もしくは構造物表面への熱伝導を低減させ温度を低下(35℃以下)させる役目を持つ。   The middle layer β that forms the heat conduction inhibiting layer receives the heat conduction from the upper layer α because it supports the upper layer α that forms the heat shielding layer. However, since the contact surface is small, the heat conduction to the rooftop floor 1 or the surface of the structure is achieved. It has the role of reducing and lowering the temperature (below 35 ° C.).

中層βをなす熱伝道阻害層及び貝殻積層空間の下層にある空気層γには太陽光の直射がなく常時日陰状態となる。この層は低温(酷暑期でも概ね35℃以下)となり、その空気は高温となる上層αが発生する上昇気流により吸引され上層αの遮熱層へ達し放出される。これにより、新鮮で比較的低温の空気(35℃以下)の通過が貝殻敷設層内の下方から上方に向けて継続して発生する。   The heat conduction inhibition layer forming the middle layer β and the air layer γ in the lower layer of the shell laminated space are not directly exposed to sunlight and are always in a shaded state. This layer is at a low temperature (generally 35 ° C. or less even in the heat wave), and the air is sucked by the rising air flow generated by the upper layer α that reaches a high temperature, reaches the heat shield layer of the upper layer α, and is released. Thereby, passage of fresh and relatively low temperature air (35 ° C. or lower) continuously occurs from the lower side to the upper side in the shell laying layer.

このような敷設層による構造機能によって屋上床1または構造物表面に流入する空気の温度は、最高で40℃で貝殻積層構造内の日陰部分に入ると35℃以下となる。この35℃以下の空気温度によって屋上床1または構造物表面は、35℃以上にならず、それ以下の天井部5はより低温化が起こり、室内への熱伝導は小さくなる。   The temperature of the air flowing into the rooftop floor 1 or the surface of the structure by the structural function by the laying layer is 40 ° C. at the maximum, and 35 ° C. or less when entering the shaded portion in the shell laminated structure. Due to the air temperature of 35 ° C. or lower, the rooftop floor 1 or the surface of the structure does not become 35 ° C. or higher, and the ceiling portion 5 below that temperature is lowered, and heat conduction into the room is reduced.

図6および下記表1に各部位の温度の測定結果を示すが、●は屋上床1の温度、■は天井部5の温度、□は室内6の温度である(図1参照)

Figure 2012012769
6 and Table 1 below show the measurement results of the temperature of each part, where ● is the temperature of the rooftop floor 1, ■ is the temperature of the ceiling 5 and □ is the temperature of the room 6 (see FIG. 1).
Figure 2012012769

この様に、前記貝殻2による平板・皿状物の層がない場合には、各部位の最高温度は、屋上床1の表面温度は約60℃、天井部5の温度約42℃、室内6の温度は約40℃となる。   Thus, in the case where there is no flat plate or dish-like layer made of the shell 2, the maximum temperature of each part is about 60 ° C on the surface of the rooftop floor 1, about 42 ° C on the ceiling 5, and 6 indoors. The temperature is about 40 ° C.

これに対し、平板・皿状物の貝殻2による貝殻敷設層がある場合、遮熱層をなす上層αの温度は40〜45℃であり、熱伝導阻害層をなす中層βの温度は概ね35℃、下層をなす空気層γの温度は35℃からそれ以下で、屋上床1の内部温度は平均約35℃以下、天井部5の温度は約30℃以下、室内6の温度は約28℃以下となる。   On the other hand, in the case where there is a shell laying layer made of flat and dish-shaped shells 2, the temperature of the upper layer α forming the heat shielding layer is 40 to 45 ° C., and the temperature of the middle layer β forming the heat conduction inhibiting layer is approximately 35. The temperature of the lower air layer γ is 35 ° C. or less, the inside temperature of the rooftop floor 1 is about 35 ° C. or less on average, the temperature of the ceiling 5 is about 30 ° C. or less, and the temperature of the room 6 is about 28 ° C. It becomes as follows.

また、外気に一定の風速がある場合は、貝殻敷設層内の空隙に、通過風が進入し、熱伝導阻害層をなす中層β、低層部をなす空気層γの冷却作用が生ずる。   Further, when the outside air has a constant wind speed, the passing air enters the voids in the shell laying layer, and the cooling action of the middle layer β forming the heat conduction inhibiting layer and the air layer γ forming the lower layer portion occurs.

この場合、風上部分の貝殻敷設層内部は気温に近い温度を呈するが、風下部分のそれは貝殻敷設層内を通過して熱を吸収した空気によって、風上部分より2〜3℃高熱となる。このため、貝殻敷設層を全体に敷き詰めることをせず、2〜4m程度間隔に貝殻敷設層から空気を逃がす隙間を設けてもよい。   In this case, the inside of the shell laying layer in the leeward part exhibits a temperature close to the air temperature, but that in the leeward part becomes 2 to 3 ° C higher than the windward part by the air that has absorbed the heat through the shell laying layer. . For this reason, you may provide the clearance gap which escapes air from a shell laying layer at intervals of about 2-4 m, without laying down the shell laying layer in the whole.

一方、冬期の低温時には、敷設層表面が断熱層として作用し下層部をなす空気層γの外気による温度低下が抑制でき、また建物内部での暖房熱の放射が妨げられることから、図7および下記表2に示すように貝殻敷設層がない部分の屋上床1に対し、貝殻敷設層を有する屋上床1は夜間から午前中の時間帯において+5℃の高温をつくる。

Figure 2012012769
On the other hand, at low temperatures in winter, the laying layer surface acts as a heat insulating layer, and the temperature drop due to the outside air of the air layer γ forming the lower layer can be suppressed, and radiation of heating heat inside the building is hindered. As shown in Table 2 below, the rooftop floor 1 having a shell laying layer produces a high temperature of + 5 ° C. in the time zone from night to morning in contrast to the rooftop floor 1 having no shell laying layer.
Figure 2012012769

屋上床1もしくは構造物表面の保水を要しない本発明は、流入する雨水をそのまま排水することが出来るので、降雨時以外は略乾燥状態が保たれ、貝殻敷設層内に水蒸気による潜熱が蓄積されない。また貝殻の略中央に設けた貫通孔は雨水の排水、外気の通気用として有効である。   The present invention that does not require water retention on the rooftop 1 or the surface of the structure can drain the inflowing rainwater as it is, so that it remains substantially dry except during rainfall, and no latent heat due to water vapor is accumulated in the shell laying layer. . The through hole provided at the approximate center of the shell is effective for draining rainwater and venting outside air.

図8は本発明の他の実施形態を示すもので、前記図5と同じく、平板・皿状物の貝殻2の積層構造を維持し、且つ貝殻敷設層の排水・通風手段を有する拘束体としてメッシュネットによるネット袋8を用いた。このメッシュネットによるネット袋8内で貝殻敷設層をつくり、かつ屋上や屋根等にフトン状にして敷き込み、これらのネット袋を相互に結束し一体的に固定すれば飛散防止ネットは必要ない。図中16は折半屋根を示すが、本実施例においては貝殻敷設層をフトン状にして敷き込むことができるので、接触する屋上床面等の構造物の形状に追従して、この様な凹凸部のある屋根部表面も効果的に被覆できる。   FIG. 8 shows another embodiment of the present invention. As in FIG. 5, as a restraint body that maintains the laminated structure of the flat shell plate / dish-like shell 2 and has drainage / ventilating means for the shell laying layer. A net bag 8 made of mesh net was used. If a shell laying layer is formed in the net bag 8 made of this mesh net and is laid in a futon shape on the rooftop or roof, and these net bags are tied together and fixed together, a scattering prevention net is not necessary. In the figure, reference numeral 16 denotes a folded roof, but in this embodiment, the shell laying layer can be laid in a futon shape, so that such unevenness follows the shape of the structure such as the rooftop surface that comes into contact. The surface of the roof part with a part can also be effectively covered.

図9は屋上床1もしくは構造物表面への本発明の貝殻2の平板・皿状物の層構造を敷設し、さらに、その上に空調室外機15を設置した場合である。貝殻2を設けない場合との比較を温度数値によって示した。   FIG. 9 shows a case where a flat plate / dish-like layer structure of the shell 2 of the present invention is laid on the rooftop floor 1 or the surface of the structure, and an air conditioner outdoor unit 15 is further installed thereon. The comparison with the case where the shell 2 is not provided is shown by the temperature value.

なお、図示は省略するが本発明におけるビルなどの屋上部とは空調室外機の上を言い、空調室外機上もしくは周辺に本発明の貝殻の平板・皿状物の層構造を敷設することも出来る。   Although not shown in the drawings, the rooftop of a building or the like in the present invention refers to the top of the air conditioner outdoor unit, and the layer structure of the shell flat plate or dish of the present invention may be laid on or around the air conditioner outdoor unit. I can do it.

このように本発明の太陽光の反射及び断熱構造体が適用する太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位は、建築物の屋上・表面、屋根面、室外空調機の表面もしくは周辺のいずれかであればよく、それに準じた部位でもよい。   Thus, the parts of the building and the like that need to improve the reflection and heat insulation effect of the irradiation heat by sunlight applied by the sunlight reflection and heat insulation structure of the present invention are the rooftop / surface of the building, the roof surface, It may be either on the surface or the periphery of the outdoor air conditioner, and may be a part according to it.

本発明の太陽光の反射及び断熱構造体の第1実施形態を示す縦断側面図である。It is a vertical side view which shows 1st Embodiment of the reflection and heat insulation structure of sunlight of this invention. 本発明の太陽光の反射及び断熱構造体で使用する貝殻の説明図である。It is explanatory drawing of the shell used in the reflection and heat insulation structure of sunlight of this invention. 本発明の太陽光の反射及び断熱構造体の1実施形態を示す斜視図である。It is a perspective view which shows one Embodiment of the reflection and heat insulation structure of sunlight of this invention. 本発明の太陽光の反射及び断熱構造体で使用する貝殻の連結結束状況を示す説明図である。It is explanatory drawing which shows the connection bundling condition of the shell used in the reflection of sunlight and heat insulation structure of this invention. 本発明の太陽光の反射及び断熱構造体で使用するネット袋とその結束状況を示す斜視図である。It is a perspective view which shows the net bag used with the reflection and heat insulation structure of sunlight of this invention, and its bundling condition. 夏期温度測定結果を示すグラフである。It is a graph which shows a summer temperature measurement result. 冬期温度測定結果を示すグラフである。It is a graph which shows a winter temperature measurement result. 本発明の太陽光の反射及び断熱構造体の他の実施形態を示す斜視図である。It is a perspective view which shows other embodiment of the reflection of sunlight and heat insulation structure of this invention. 本発明の太陽光の反射及び断熱構造体の他の設置例を示す説明図である。It is explanatory drawing which shows the other example of installation of the sunlight reflection and heat insulation structure of this invention.

1 屋上床 2 貝殻
2a 真珠層
3 貫通孔 4 飛散防止ネット
5 天井部 6 室内
7 結束紐 8 ネット袋
11 軽石 12 固定枠
12a 脚 13 孔
14 結束具 15 空調室外機
16 折半屋根
DESCRIPTION OF SYMBOLS 1 Rooftop 2 Seashell 2a Pearl layer 3 Through-hole 4 Spattering prevention net 5 Ceiling part 6 Indoor 7 Tying string 8 Net bag 11 Pumice 12 Fixed frame 12a Leg 13 Hole 14 Binding tool 15 Air-conditioning outdoor unit 16 Folding half roof

Claims (6)

太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位に用いる反射及び断熱構造体であって、照射熱を受ける部位に、真珠層を有する貝殻を、その真珠層を太陽光による照射熱の反射面となるように、かつ層構造状に敷設したことを特徴とする太陽光の反射及び断熱構造体。   Reflection and heat insulation structure used in parts of buildings and the like that need to improve the reflection and heat insulation effect of irradiation heat by sunlight, and a shell having a nacreous layer on the part that receives irradiation heat, A reflection and heat insulation structure for sunlight, which is laid in a layer structure so as to be a reflection surface for irradiation heat by sunlight. 太陽光による照射熱の反射及び断熱効果を向上する必要のある建築物等の部位が、建築物の屋上・表面、室外空調機の表面もしくは周辺のいずれかである請求項1記載の太陽光の反射及び断熱構造体。   The part of a building or the like that needs to improve the reflection of heat and the heat insulation effect by sunlight is either the roof / surface of a building, the surface of an outdoor air conditioner, or the periphery thereof. Reflective and thermal insulation structure. 真珠層を有する貝殻は、その断面形状が略板状または凹状である請求項1または請求項2記載の太陽光の反射及び断熱構造体。   The sunlight reflecting and heat insulating structure according to claim 1 or 2, wherein the shell having a nacreous layer has a substantially plate-like or concave cross-sectional shape. 貝殻が形成する層構造は、排水・通風手段を有する保持体で、該層構造を維持するように囲まれる請求項1ないし請求項3のいずれかに記載の太陽光の反射及び断熱構造体。   The solar light reflection and heat insulation structure according to any one of claims 1 to 3, wherein the layer structure formed by the shell is a holding body having drainage / ventilating means and is surrounded so as to maintain the layer structure. 貝殻は、その表面から裏面に貫通する孔部が設けられる請求項1ないし請求項4のいずれかに記載の太陽光の反射及び断熱構造体。   The solar shell reflection and heat insulation structure according to any one of claims 1 to 4, wherein the shell is provided with a hole penetrating from the front surface to the back surface. 層構造を維持する保持体と連続する線材が、貝殻の表面から裏面に貫通する孔部に挿通される請求項1ないし請求項5のいずれかに記載の太陽光の反射及び断熱構造体。   The solar light reflecting and heat insulating structure according to any one of claims 1 to 5, wherein a wire that is continuous with the holder that maintains the layer structure is inserted into a hole that penetrates from the front surface of the shell to the back surface.
JP2010147288A 2010-06-29 2010-06-29 Sunlight reflection and thermal insulation structure Expired - Fee Related JP5588239B2 (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
TWI732382B (en) * 2019-12-13 2021-07-01 遠東科技大學 Method for constructing heat-insulating wall surface by using oyster shells

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH05340072A (en) * 1992-06-13 1993-12-21 Tatsuhiko Hasegawa Decorative material using sheel
JP2009057811A (en) * 2007-08-30 2009-03-19 Sukeshiro Hori Water retentive, cold reserving and heat insulating panel optimal for heat reservation on rooftop

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPH05340072A (en) * 1992-06-13 1993-12-21 Tatsuhiko Hasegawa Decorative material using sheel
JP2009057811A (en) * 2007-08-30 2009-03-19 Sukeshiro Hori Water retentive, cold reserving and heat insulating panel optimal for heat reservation on rooftop

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
TWI732382B (en) * 2019-12-13 2021-07-01 遠東科技大學 Method for constructing heat-insulating wall surface by using oyster shells

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