JP3601986B2 - Waterproofing material for heat-insulating waterproofing tank and heat-insulating waterproofing panel using the waterproofing material - Google Patents

Description

【０００８】
本発明の防水材では、ポリウレタンの架橋密度ＣＤが０．２以上４以下の範囲であるので、ポリウレタンが網目状に形成され、適度な伸縮性があり、下地の樹脂発泡体への密着性が向上する。
【０００９】
本発明の断熱防水槽用の断熱防水パネルは、樹脂発泡体を有する断熱パネルの少なくとも一方の面に上記防水材を含有する防水材層を設けたことを特徴とする。この構成により、現場での防水材の塗工作業を行うことなく、単にパネルの間の目地部分を施工するのみで断熱防水槽を構築することができ、しかも、防水材層の剥離は生じない。
【００１０】
また、上記の断熱防水パネルに於いて、前記断熱パネルの少なくとも前記一方の面とは異なる面に導水路を形成するための凹溝を設けたことを特徴とする。この構成により、断熱防水槽の外側の水を排することができ、防水材層に背圧が生ずるのを防止することができる。
【００１１】
更に、上記断熱防水パネルの構成に於いて、前記凹溝以外の部分の凸部に導水路を形成するための透水性基布を設けた構成とすることができる。この構成により、特に透水性基布を設置するための作業を必要とすることなく、単に断熱防水パネルを設置するだけで、導水路を形成することができる。
【００１２】
【発明の実施の形態】
本発明の防水材は、断熱防水槽の断熱材層を構成する樹脂発泡体に塗工して使用される防水材であって、下記の有機ポリイソシアネートと活性水素基含有化合物とを反応させて得られ２液反応型のポリウレタン組成物を含有している。上記有機ポリイソシアネートは１種又は２種以上の成分からなり、活性水素基含有化合物も１種又は２種以上の成分からなる。ここで、有機ポリイソシアネートの平均分子量をＭｗ_１、平均イソシアネート基数Ｆ_１とし、該有機ポリイソシアネートをＷ_１重量部使用するものとし、同様に、活性水素基含有化合物の平均分子量をＭｗ_２、平均活性水素基数をＦ_２とし、該活性水素基含有化合物をＷ_２重量部使用するものとした場合、Ｆ_１≧２及びＦ_２≧２であって、上記数２で表されるポリウレタン架橋密度ＣＤが、０．２以上４以下の範囲のポリウレタンが使用される。
【００１３】
ここで、有機ポリイソシアネートが２種以上の成分の混合物である場合、各成分の分子量をＭｗ_１（１）、Ｍｗ_１（２）…、それぞれのイソシアネート基数をＦ_１（１）、Ｆ_１（２）…とし、各成分をＷ_１（１）、Ｗ_１（２）…ずつ使用するとすれば、平均分子量Ｍｗ_１は以下の数３によって、平均イソシアネート基数Ｆ_１は数４によって求めることができる。
【００１４】
【数３】

【００１５】
【数４】

【００１６】
また、活性水素基含有化合物が２種以上の成分の混合物である場合、各成分の分子量をＭｗ_２（１）、Ｍｗ_２（２）…、それぞれの活性水素基数をＦ_２（１）、Ｆ_２（２）…とし、各成分をＷ_２（１）、Ｗ_２（２）…づつ使用するとすれば、平均分子量Ｍｗ_２は以下の数５によって、平均活性水素基数Ｆ_２は数６によって求めることができる。
【００１７】
【数５】

【００１８】
【数６】

【００１９】
本発明の防水材に使用されるＦ_１≧２の有機イソシアネートとしては、例えば、トリレンジイソシアネート、ジフェニルメタンジイソシアネート、ポリメチレンポリフェニルポリイソシアネート（化１）、キシリレンジイソシアネート、ヘキサメチレンイソシアネート、水添トリレンジイソシアネート、水添ジシクロヘキシルメタンジイソシアネート、水添キシリレンジイソシアネート、イソホロンジイソシアネート及びこれらの変性物並びにこれらの混合物を挙げることができる。これらの有機ポリイソシアネートのうち、化１で表されるポリイソシアネートが、活性水素基含有化合物との反応性が高く、しかも蒸気圧が低いために作業上取り扱いやすいという利点があるので好ましい。
【００２０】
【化１】

【００２１】
本発明の防水材に使用されるＦ_２≧２の活性水素基含有化合物としては、例えば、ポリテトラメチレングリコール，ポリオキシエチレンポリオール，ポリオキシプロピレンポリオール，ポリオキシエチレンポリオキシプロピレンポリオール等のポリエーテルポリオール、ポリシエチレンアジペート，ポリブチレンアジペート，ポリヘキサメチレンアジペート，ポリカプロラクトンポリオール，ヒマシ油等のポリエステルポリオール、ポリブタジエンポリオール等のポリオレフィンポリオール、多価アルコール、多価アミン及びこれらの混合物を挙げることができる。
【００２２】
本発明では、上記以外の成分の他、通常使用される溶剤、触媒、水分吸着剤、無機充填剤、顔料、消泡剤、平滑剤等を添加することができる。
【００２３】
本発明の防水材は、上記有機イソシアネートと上記活性水素基含有化合物とを反応させて得られるポリウレタンであって、上記数２の式で表されるポリウレタン架橋密度ＣＤが０．２以上４以下の範囲である２液反応型のポリウレタン組成物を含有している。このポリウレタン架橋密度ＣＤは分子量１０００当たりの架橋本数を表し、このＣＤが０．２より小さいと、得られる防水材層が柔らかくなり、耐水性及び耐アルカリ性が低くなるので好ましくない。また、ＣＤが４より大きいと、得られる防水材層が硬くなり過ぎてクラックが生じ易くなるので好ましくない。
【００２４】
本発明の防水材は、樹脂発泡体に塗工されて防水材層を形成するが、その際の塗工方法には、ワンショット法とプレポリマー法とがある。ワンショット法は、有機ポリイソシアネートをＢ液、活性水素基含有化合物をＡ液とし、使用時に所定量だけ混合して塗工するものである。プレポリマー法では、予め有機ポリイソシアネート活性水素基含有化合物とにより末端イソシアネート基含有ウレタンプレポリマーを合成しておいてこれをＢ液とし、活性水素基含有化合物をＡ液として使用時に所定量だけ混合して塗工するものである。本発明の防水材は、ワンショット法とプレポリマー法の何れにも使用することができる。
【００２５】
本発明の防水材を用いた防水材層の形成は、上記Ａ液及びＢ液を混合した液を、例えばスクイジー、刷毛、コテ等を用いて塗工することにより、又はナイフコート、ロールコート、２液混合スプレー機によるスプレー等により行うことができる。
【００２６】
本発明の断熱防水パネルは、樹脂発泡体製の断熱パネルの少なくとも一方の面に上記防水材を含有する防水材層を設けたものである。樹脂発泡体としては、例えばポリスチレン、ポリウレタン、ポリプロピレン、ポリエチレン等の発泡体が使用される。樹脂発泡体製の断熱パネルへの塗工は、上記と同様の方法により行うことができる。本発明の断熱防水パネルは、所定の位置に隙間なく固定され、その外側にコンクリートが打設された後、各パネル間に目地材が施工されて断熱防水槽を構築するものである。本発明の断熱防水パネルを使用すると、現場での防水材の塗工が不要となるとともに、防水材層が樹脂発泡体からなる断熱材層に十分に密着し、しかもクラックの発生が見られない。
【００２７】
また、本発明の断熱防水パネルは、防水材層を設けた前記一方の面とは異なる面に導水路を形成するための凹溝が設けられている。この凹溝は、断熱防水槽の背面に入り込んだ水を排出する機能を果たすものである。図１は凹溝を設けた断熱防水パネルの一例を示す斜視図である。同図の断熱防水パネルは、発泡ポリスチレン等からなる断熱材層１の表面に防水材層２が塗工されて形成されている。断熱材層１の裏面には、断熱材層１と一体的に形成された凸部４が設けられ、この凸部４の間に凹溝３が形成されている。凹溝３は上述のように型枠固定してその外側にコンクリートを打設するに際し、コンクリートと断熱防水パネルとの間に介在する不織布等の透水性基布により凹溝３内へのコンクリートの侵入を防止して導水路を形成するものである。このような凹溝３を設けることにより、効率的に断熱防水槽の背面に入り込んだ水を排出することができる。
【００２８】
更に、上記構成に於いて、図２に示すように、前記凹溝３以外の部分の凸部４に導水路を形成するための透水性基布５を設けることもできる。これにより、断熱防水パネルの設置と同時に透水性基布５の設置を行うことができ、断熱防水槽の構築作業に要する手間を省くことができる。
【００２９】
【実施例】
本発明を実施例及び比較例に基づいて説明するが、本発明はここに記載した実施例に限定されるものではない。
【００３０】
表１に示す組成で以下の実施例１〜３及び比較例の防水材を調製し、後述する密着性試験を行った。
【００３１】
（実施例１）
ヒマシ油（活性水素基数Ｆ_２＝２．７、平均分子量Ｍｗ_２＝１０００）５０重量部と、ポリオキシプロピレンポリオール（活性水素基数Ｆ_２＝２．０、平均分子量Ｍｗ_２＝７００）５０重量部との混合物に、炭酸カルシウム５０重量部、水分吸着剤としてゼオライト１０重量部を混合してＡ液とした。
【００３２】
これとは別に、ポリメチレンポリフェニルポリイソシアネート（イソシアネート基数Ｆ_１＝２．４、平均分子量Ｍｗ_１＝３３０）３９．５重量部をＢ液とした。イソシアネート基数／活性水素基数の等量比＝１．０５／１、ポリウレタン架橋密度ＣＤ＝０．６０である。
【００３３】
（実施例２及び実施例３）
表１に示す組成で、実施例１と同様にして、実施例２及び実施例３のＡ液及びＢ液を調製した。イソシアネート基数／活性水素基数の等量比とポリウレタン架橋密度ＣＤは、表１に示すとおりである。
【００３４】
（比較例）
表１に示す組成で、実施例１と同様にして、比較例のＡ液及びＢ液を調製した。イソシアネート基数／活性水素基数の等量比とポリウレタン架橋密度ＣＤは、表１に示すとおりである。
【００３５】
【表１】

【００３６】
（密着性試験）
実施例１〜３及び比較例のＡ液及びＢ液を混合して防水材を調製し、これを、縦９００ｍｍ×横９００ｍｍ×厚さ５０ｍｍの発泡ポリスチレン製の断熱パネルにスクイジーを用いて２ｍｍの厚さに塗工し、各実施例及び比較例の断熱防水パネルを得た。
【００３７】
これらの断熱防水パネルを固定し、その外側にコンクリートを打設して、９００ｍｍ×９００ｍｍ×９００ｍｍの容積の模擬の断熱防水槽を作製した。各パネルの継ぎ目には各パネルの防水材層の形成に用いたものと同じ防水材を目地材として使用し、厚さ３ｍｍで塗工した。
【００３８】
硬化養生後、各実施例及び比較例の断熱防水槽に水道水を満たし、ヒーターを用いて６０℃に保ち、この温度で１８０日間放置した。その後、水道水を抜き、各断熱防水パネルの防水材層の外観及び密着性を調べた。外観は目視により行い、密着性試験は９０度引張り剥離試験により行った。同様の試験を５℃の水道水についても行った。その結果を表２に示す。
【００３９】
【表２】

【００４０】
表２に示すように、実施例１〜３の断熱防水パネルは塗膜外観及び密着性ともに優れ、断熱防水槽に使用した場合に十分に使用に耐えることが分かる。これに対して、比較例の断熱防水パネルは防水材層の剥離及び膨潤が見られ、断熱防水槽に使用した場合に問題があることが分かる。
【００４１】
【発明の効果】
本発明の防水材は、ポリウレタンの架橋密度ＣＤが０．２以上４以下の範囲なので、ポリウレタンが網目状に形成され、従って適度な伸縮性があり、下地の樹脂発泡体への密着性が向上する。
【００４２】
本発明の断熱防水パネルは、樹脂発泡体製の断熱パネルの少なくとも一方の面に上記防水材を含有する防水材層を設けたものである。本発明の断熱防水パネルを使用すると、現場での防水材の塗工が不要となるとともに、防水材層が樹脂発泡体からなる断熱材層に十分に密着し、しかもクラックの発生が見られない。
【００４３】
また、本発明の断熱防水パネルは、防水材層を設けた前記一方の面とは異なる面に導水路を形成するための凹溝が設けられているので、効率的に断熱防水槽の背面に入り込んだ水を排出することができる。
【００４４】
上記断熱防水パネルの構成に於いて、前記凹溝以外の部分の凸部に導水路を形成するための透水性基布を設けた構成とすることにより、特に透水性基布を設置するための作業が不要となり、断熱防水槽の構築作業に要する手間を省くことができる。
【図面の簡単な説明】
【図１】凹溝を設けた断熱防水パネルの一例を示す斜視図である。
【図２】図１の断熱防水パネルに透水性基布を設けた場合を示す断面図である。
【符号の説明】
１ 断熱材層
２ 防水材層
３ 凹溝
４ 凸部
５ 透水性基布[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a waterproofing material for a heat-insulating waterproofing tank and a heat-insulating waterproofing panel using the waterproofing material, and more particularly to a waterproofing material for a heat-insulating waterproofing tank that does not easily peel off when applied to a resin foam. And a heat-insulating waterproof panel using the waterproof material.
[0002]
[Prior art]
Conventionally, warm water heated to a predetermined temperature or cold water cooled to a predetermined temperature has been used for cooling and heating of buildings and the like. From the viewpoint of energy saving, these hot and cold waters are usually stored and used in a heat-insulating waterproof tank generally having a heat insulating property and a waterproof property, which is generally called a heat storage tank. Such a heat insulating and waterproofing tank is constructed by attaching a heat insulating material such as expanded polystyrene to the inside of a reinforced concrete water tank by some method, and applying a waterproofing material to the surface thereof. This waterproof material layer is formed, for example, by attaching a rubber sheet to the inside of the heat insulating panel.
[0003]
[Problems to be solved by the invention]
However, when the rubber sheet is attached, the rubber sheet is not bonded to the heat insulating material layer, so that there is a problem in that the rubber sheet is peeled off when pressure is applied to its rear surface. In order to solve this problem, a technique of forming a waterproof material layer by applying resin mortar, epoxy resin, or the like has been developed. In addition, a technique of forming a waterproof material layer by applying an acrylic resin or an existing urethane waterproof material has been developed.
[0004]
However, when a waterproof material layer is formed by applying a resin mortar, an epoxy resin, or the like, a new problem that cracks easily occur in the waterproof material layer occurs. In addition, when a waterproof material layer is formed by applying an acrylic resin or an existing urethane waterproof material, the adhesiveness between the acrylic resin or the existing urethane waterproof material and the resin foam that is a base heat insulating material layer is low, There is a new problem that the waterproof material layer is easily peeled off.
[0005]
The present invention is to solve such problems of the prior art, and an object of the present invention is to provide a heat insulating material layer that has high adhesion to a resin foam used as a heat insulating material layer and is less likely to crack. It is an object of the present invention to provide a waterproof material for a heat-insulating waterproof tank that can be formed. Another object of the present invention is to provide a heat-insulating waterproof panel using the waterproof material.
[0006]
[Means for Solving the Problems]
The waterproofing material for the heat-insulating waterproofing tank of the present invention is a waterproofing material applied to a resin foam and used, having an average molecular weight Mw ₁ and an average number of isocyanate groups F ₁ ≧ 2, and one or more types. ₁ part by weight of an organic polyisocyanate composed of the above component and ₂ parts by weight of an active hydrogen group-containing compound having an average molecular weight Mw ₂ and an average number of active hydrogen groups F ₂ ≧ 2 and composed of one or more types of components. And a two-component reaction type polyurethane composition having a polyurethane crosslink density CD of 0.2 or more and 4 or less represented by the following equation (2).
[0007]
(Equation 2)

[0008]
In the waterproofing material of the present invention, since the crosslinking density CD of the polyurethane is in the range of 0.2 or more and 4 or less, the polyurethane is formed in a mesh shape, has an appropriate elasticity, and has an adhesion to the underlying resin foam. improves.
[0009]
The heat-insulating waterproof panel for a heat-insulating waterproof tank according to the present invention is characterized in that a waterproof material layer containing the waterproof material is provided on at least one surface of a heat-insulating panel having a resin foam. With this configuration, it is possible to construct a heat-insulating waterproof tank simply by installing joints between panels without performing a waterproof material coating operation on site, and furthermore, the waterproof material layer does not peel off. .
[0010]
In the above-mentioned heat-insulating waterproof panel, the heat-insulating panel is characterized in that at least a surface different from the one surface is provided with a concave groove for forming a water conduit. With this configuration, water outside the heat-insulating waterproof tank can be drained, and back pressure can be prevented from being generated in the waterproof material layer.
[0011]
Further, in the configuration of the heat-insulating waterproof panel, a configuration may be adopted in which a water-permeable base fabric for forming a water guide channel is provided in a convex portion other than the concave groove. With this configuration, it is possible to form the headrace channel simply by installing the heat-insulating and waterproofing panel, without requiring any operation for installing the water-permeable base fabric.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
The waterproofing material of the present invention is a waterproofing material which is used by applying to a resin foam constituting a heat insulating material layer of a heat insulating and waterproofing tank, by reacting the following organic polyisocyanate with an active hydrogen group-containing compound. The obtained two-pack reaction type polyurethane composition is contained. The organic polyisocyanate comprises one or more components, and the active hydrogen group-containing compound also comprises one or more components. Here, the average molecular weight of the organic polyisocyanate Mw _1, the average number of isocyanate groups F _1, the organic polyisocyanate shall use W ₁ part by weight, likewise, the average molecular weight of the active hydrogen group-containing compound Mw _2, average When the number of active hydrogen groups is F ₂ and the compound containing active hydrogen groups is used in an amount of ₂ parts by weight of W, F ₁ ≧ 2 and F ₂ ≧ 2, and the polyurethane crosslink density CD represented by the above equation 2 However, polyurethane in the range of 0.2 or more and 4 or less is used.
[0013]
Here, when the organic polyisocyanate is a mixture of two or more components, the molecular weight of each component is Mw ₁ (1), Mw ₁ (2)..., And the number of isocyanate groups is F ₁ (1), F ₁ ( Assuming that each component is W ₁ (1), W ₁ (2), and so on, the average molecular weight Mw ₁ can be obtained by the following formula 3, and the average number of isocyanate groups F ₁ can be obtained by the formula 4. .
[0014]
(Equation 3)

[0015]
(Equation 4)

[0016]
When the active hydrogen group-containing compound is a mixture of two or more components, the molecular weight of each component is Mw ₂ (1), Mw ₂ (2)..., And the number of each active hydrogen group is F ₂ (1), F _{2 If} each component is used as W ₂ (1), W ₂ (2)..., The average molecular weight Mw ₂ is obtained by the following Equation 5, and the average number of active hydrogen groups F ₂ is obtained by the following Equation 6. be able to.
[0017]
(Equation 5)

[0018]
(Equation 6)

[0019]
Examples of the organic isocyanate of F ₁ ≧ 2 used in the waterproofing material of the present invention include, for example, tolylene diisocyanate, diphenylmethane diisocyanate, polymethylene polyphenyl polyisocyanate (formula 1), xylylene diisocyanate, hexamethylene isocyanate, hydrogenated triisocyanate. Examples thereof include diisocyanate, hydrogenated dicyclohexylmethane diisocyanate, hydrogenated xylylene diisocyanate, isophorone diisocyanate, modified products thereof, and mixtures thereof. Among these organic polyisocyanates, the polyisocyanate represented by Chemical formula 1 is preferred because it has a high reactivity with the active hydrogen group-containing compound and has an advantage that it has a low vapor pressure and is easy to handle in operation.
[0020]
Embedded image

[0021]
Examples of the compound having an active hydrogen group of F ₂ ≧ 2 used in the waterproofing material of the present invention include polyethers such as polytetramethylene glycol, polyoxyethylene polyol, polyoxypropylene polyol, and polyoxyethylene polyoxypropylene polyol. Polyols such as polyols, polyethylene adipates, polybutylene adipates, polyhexamethylene adipates, polycaprolactone polyols, castor oil, polyolefin polyols such as polybutadiene polyols, polyhydric alcohols, polyamines, and mixtures thereof.
[0022]
In the present invention, in addition to the components other than those described above, commonly used solvents, catalysts, moisture adsorbents, inorganic fillers, pigments, defoamers, leveling agents, and the like can be added.
[0023]
The waterproofing material of the present invention is a polyurethane obtained by reacting the organic isocyanate with the active hydrogen group-containing compound, wherein the polyurethane crosslink density CD represented by the above formula 2 is 0.2 or more and 4 or less. The composition contains a two-component reaction type polyurethane composition. The polyurethane crosslink density CD represents the number of crosslinks per 1000 molecular weight. If the CD is smaller than 0.2, the obtained waterproof material layer becomes soft and the water resistance and alkali resistance are undesirably lowered. On the other hand, if the CD is larger than 4, the obtained waterproof material layer becomes too hard, and cracks are likely to occur.
[0024]
The waterproofing material of the present invention is applied to a resin foam to form a waterproofing material layer. In this case, a coating method includes a one-shot method and a prepolymer method. In the one-shot method, an organic polyisocyanate is used as a solution B and an active hydrogen group-containing compound is used as a solution A, and a predetermined amount of the mixture is used for application when used. In the prepolymer method, a urethane prepolymer containing a terminal isocyanate group is synthesized in advance with an organic polyisocyanate active hydrogen group-containing compound, and this is used as a liquid B, and the active hydrogen group-containing compound is used as a liquid A and mixed in a predetermined amount when used. And apply it. The waterproofing material of the present invention can be used for either the one-shot method or the prepolymer method.
[0025]
The formation of the waterproofing material layer using the waterproofing material of the present invention is performed by applying a liquid obtained by mixing the above-mentioned liquid A and liquid B using, for example, a squeegee, a brush, a trowel, or a knife coat, a roll coat, It can be performed by spraying with a two-liquid mixing sprayer or the like.
[0026]
The heat-insulating waterproof panel of the present invention is obtained by providing a waterproof material layer containing the above-described waterproof material on at least one surface of a heat-insulating panel made of a resin foam. As the resin foam, for example, a foam such as polystyrene, polyurethane, polypropylene, and polyethylene is used. The coating on the heat insulating panel made of resin foam can be performed by the same method as described above. The heat-insulating waterproof panel of the present invention is fixed at a predetermined position without any gap, and after concrete is cast on the outside thereof, a joint material is applied between the panels to construct a heat-insulating waterproof tank. The use of the heat-insulating waterproof panel of the present invention makes it unnecessary to apply a waterproof material on site, and the waterproof material layer adheres sufficiently to the heat-insulating material layer made of a resin foam, and no cracks are observed. .
[0027]
In the heat-insulating waterproof panel of the present invention, a concave groove for forming a headrace is provided on a surface different from the one surface provided with the waterproof material layer. The groove serves to discharge water that has entered the back of the heat-insulating waterproof tank. FIG. 1 is a perspective view showing an example of a heat-insulating waterproof panel provided with a groove. The heat-insulating waterproof panel shown in FIG. 1 is formed by applying a waterproof material layer 2 to the surface of a heat-insulating material layer 1 made of expanded polystyrene or the like. On the back surface of the heat insulating material layer 1, there are provided convex portions 4 integrally formed with the heat insulating material layer 1, and concave grooves 3 are formed between the convex portions 4. When the concrete groove is fixed to the formwork and the concrete is poured outside the concave groove 3 as described above, the concrete is introduced into the concave groove 3 by a water-permeable base cloth such as a nonwoven fabric interposed between the concrete and the heat insulating and waterproofing panel. The headrace is formed to prevent intrusion. By providing such a groove 3, it is possible to efficiently discharge water that has entered the rear surface of the heat-insulating waterproof tank.
[0028]
Further, in the above configuration, as shown in FIG. 2, a water-permeable base cloth 5 for forming a water guide channel may be provided on the convex portion 4 other than the concave groove 3. Thereby, the installation of the water-permeable base cloth 5 can be performed simultaneously with the installation of the heat-insulating waterproof panel, and the labor required for the construction work of the heat-insulating waterproof tank can be saved.
[0029]
【Example】
The present invention will be described based on examples and comparative examples, but the present invention is not limited to the examples described here.
[0030]
The waterproof materials of the following Examples 1 to 3 and Comparative Examples were prepared with the compositions shown in Table 1, and the adhesion test described below was performed.
[0031]
(Example 1)
50 parts by weight of castor oil (number of active hydrogen groups F ₂ = 2.7, average molecular weight Mw ₂ = 1000) and 50 parts by weight of polyoxypropylene polyol (number of active hydrogen groups F ₂ = 2.0, average molecular weight Mw ₂ = 700) Was mixed with 50 parts by weight of calcium carbonate and 10 parts by weight of zeolite as a moisture adsorbent to obtain a liquid A.
[0032]
Separately, 39.5 parts by weight of polymethylene polyphenyl polyisocyanate (number of isocyanate groups F ₁ = 2.4, average molecular weight Mw ₁ = 330) was used as liquid B. The equivalent ratio of the number of isocyanate groups / the number of active hydrogen groups = 1.05 / 1, and the polyurethane crosslink density CD = 0.60.
[0033]
(Examples 2 and 3)
With the compositions shown in Table 1, in the same manner as in Example 1, the liquids A and B of Examples 2 and 3 were prepared. The equivalent ratio of the number of isocyanate groups / the number of active hydrogen groups and the polyurethane crosslink density CD are as shown in Table 1.
[0034]
(Comparative example)
With the compositions shown in Table 1, in the same manner as in Example 1, the liquid A and the liquid B of the comparative example were prepared. The equivalent ratio of the number of isocyanate groups / the number of active hydrogen groups and the polyurethane crosslink density CD are as shown in Table 1.
[0035]
[Table 1]

[0036]
(Adhesion test)
A liquid and a liquid B of Examples 1 to 3 and Comparative Example were mixed to prepare a waterproof material, and this was applied to a heat insulating panel made of expanded polystyrene having a length of 900 mm × width 900 mm × thickness of 50 mm using a squeegee to form a waterproof material of 2 mm. Coating was performed to a thickness to obtain a heat-insulated waterproof panel of each of Examples and Comparative Examples.
[0037]
These heat-insulated waterproof panels were fixed, and concrete was cast on the outside thereof to produce a simulated heat-insulated waterproof tank having a volume of 900 mm × 900 mm × 900 mm. The same waterproofing material as that used for forming the waterproofing material layer of each panel was used as a joint material at the joint of each panel, and was applied with a thickness of 3 mm.
[0038]
After curing and curing, the insulated waterproof tanks of the examples and comparative examples were filled with tap water, kept at 60 ° C. using a heater, and left at this temperature for 180 days. Thereafter, tap water was drained, and the appearance and adhesion of the waterproof material layer of each heat-insulating waterproof panel were examined. The appearance was visually inspected, and the adhesion test was conducted by a 90-degree tensile peel test. A similar test was performed for tap water at 5 ° C. Table 2 shows the results.
[0039]
[Table 2]

[0040]
As shown in Table 2, it can be seen that the heat-insulated waterproof panels of Examples 1 to 3 are excellent in both the appearance of the coating film and the adhesiveness, and can sufficiently withstand use when used in a heat-insulated waterproof tank. On the other hand, in the heat-insulated waterproof panel of the comparative example, the waterproof material layer was peeled and swelled, and it was found that there was a problem when used in the heat-insulated waterproof tank.
[0041]
【The invention's effect】
In the waterproofing material of the present invention, since the crosslink density CD of the polyurethane is in the range of 0.2 or more and 4 or less, the polyurethane is formed in a mesh shape, and therefore has an appropriate elasticity, and the adhesion to the underlying resin foam is improved. I do.
[0042]
The heat-insulating waterproof panel of the present invention is obtained by providing a waterproof material layer containing the above-mentioned waterproof material on at least one surface of a heat-insulating panel made of a resin foam. The use of the heat-insulating waterproof panel of the present invention makes it unnecessary to apply a waterproof material on site, and the waterproof material layer adheres sufficiently to the heat-insulating material layer made of a resin foam, and no cracks are observed. .
[0043]
Further, the heat-insulated waterproof panel of the present invention is provided with a concave groove for forming a water conduit on a surface different from the one surface provided with the waterproof material layer, so that the heat-insulated waterproof tank is efficiently provided on the back surface. Water that has entered can be discharged.
[0044]
In the configuration of the heat-insulating waterproof panel, by providing a water-permeable base fabric for forming a water guide channel in a convex portion other than the concave groove, particularly for installing a water-permeable base fabric The work becomes unnecessary, and the labor required for the construction work of the heat insulating and waterproofing tank can be saved.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an example of a heat-insulating waterproof panel provided with a groove.
FIG. 2 is a cross-sectional view showing a case where a water-permeable base fabric is provided on the heat-insulating waterproof panel of FIG.
[Explanation of symbols]
REFERENCE SIGNS LIST 1 heat insulating material layer 2 waterproof material layer 3 concave groove 4 convex portion 5 water-permeable base cloth

Claims (4)

A waterproof material used by coating on a resin foam,
₁ part by weight of an organic polyisocyanate having an average molecular weight Mw ₁ and an average number of isocyanate groups F ₁ ≧ 2 and comprising one or more components,
An active hydrogen group-containing compound having an average molecular weight Mw ₂ and an average number of active hydrogen groups F ₂ ≧ 2 and comprising one or more components is obtained by reacting with ₂ parts by weight of W. A waterproofing material for a heat-insulating waterproofing tank, which is a two-pack reaction type polyurethane composition having a polyurethane crosslink density CD represented by the formula of 0.2 to 4 inclusive.

A heat-insulating waterproof panel for a heat-insulating waterproof tank, wherein a waterproof material layer containing the waterproof material according to claim 1 is provided on at least one surface of the heat-insulating panel having a resin foam. The heat insulating and waterproofing panel for a heat insulating and waterproofing tank according to claim 2, wherein a concave groove for forming a water conduit is provided on at least a surface of the heat insulating panel different from the one surface. The heat-insulating waterproof panel for a heat-insulating waterproof tank according to claim 3, wherein a water-permeable base fabric for forming a water passage is provided in a convex portion other than the concave groove.

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