JP2005350879A - Fiber sheet for reinforcing concrete structure, and reinforcing method - Google Patents

Fiber sheet for reinforcing concrete structure, and reinforcing method Download PDF

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JP2005350879A
JP2005350879A JP2004170015A JP2004170015A JP2005350879A JP 2005350879 A JP2005350879 A JP 2005350879A JP 2004170015 A JP2004170015 A JP 2004170015A JP 2004170015 A JP2004170015 A JP 2004170015A JP 2005350879 A JP2005350879 A JP 2005350879A
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fiber sheet
reinforcing
concrete structure
warp
weft
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JP4610936B2 (en
Inventor
Naoyuki Yaguchi
直幸 矢口
Minoru Suzuki
実 鈴木
Junya Ide
潤也 井出
Yoshiyuki Kojima
芳之 小島
Kenichi Kuribayashi
健一 栗林
Tomokazu Ise
智一 伊勢
Jun Aramaki
潤 荒牧
Seiji Fujima
誠司 藤間
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Denka Co Ltd
Railway Technical Research Institute
Kuraray Co Ltd
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Railway Technical Research Institute
Kuraray Co Ltd
Denki Kagaku Kogyo KK
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a fiber sheet for reinforcing a concrete structure, and a reinforcing method for obtaining sufficient reinforcing performance at a low cost by using a synthetic fiber sheet having specific physical property and structure. <P>SOLUTION: The fiber sheet for reinforcing the concrete structure is formed of the synthetic fiber sheet meeting following conditions of (a) a strength of 400-1,000 N/cm in both weft and warp, (b) a rupture elongation of 5-10% in both weft and warp, (c) a cover factor of 40-100%, and (d) a styrene monomer suction length of 12 cm or more at 20°C in thirty minutes. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

本発明は、鉄道トンネルなどの補修、補強に用いられるコンクリート構造物補強用繊維シート及び補強方法に関するものである。さらに詳しくは、コンクリート構造物の劣化に伴ってひび割れが生じた際のコンクリート塊の落下を防止するための補強用繊維シートならびにその補強方法に関する。   The present invention relates to a fiber sheet for reinforcing a concrete structure used for repairing and reinforcing a railway tunnel and a reinforcing method. More specifically, the present invention relates to a reinforcing fiber sheet for preventing a concrete lump from falling when a crack is generated due to deterioration of a concrete structure and a reinforcing method thereof.

コンクリート構造物の補強は一般に、劣化コンクリートの除去、ひび割れ補強剤の注入、覆工コンクリートの打設といった手順が取られるが、高所での重作業が多く、簡便な方法が求められている。   Reinforcement of concrete structures generally involves procedures such as removal of deteriorated concrete, injection of crack reinforcement, and placement of lining concrete, but there are many heavy work in high places and a simple method is required.

これに対して、合成繊維製の織物や編物、不織布などを補強部に貼り、その上から樹脂を塗布・硬化させる、いわゆるFRP(fiber reinforced plastic)を形成する補強方法が提案されている。   On the other hand, there has been proposed a reinforcing method for forming a so-called fiber reinforced plastic (FRP) in which a woven fabric, a knitted fabric, a nonwoven fabric or the like made of a synthetic fiber is attached to a reinforcing portion, and a resin is applied and cured thereon.

特に、トンネル覆工に地圧や水圧等の外力が作用すると、過大な軸力が発生する。それにより、覆工中の層間にひび割れが発生し、覆工耐力が急激に低下する現象が生じる。そこで、その覆工の補修を行う必要がある。   In particular, when an external force such as earth pressure or water pressure acts on the tunnel lining, an excessive axial force is generated. As a result, a crack occurs between the layers during lining, and a phenomenon occurs in which the lining strength is drastically reduced. Therefore, it is necessary to repair the lining.

その補修を繊維シートで行う場合には、従来は、アラミド系繊維、炭素繊維が用いられている。
特開平7−34784号公報 特開平11−107687号公報 特開平11−148233号公報 特開2002−256707号公報 特許第2691848号公報
In the case where the repair is performed with a fiber sheet, aramid fibers and carbon fibers are conventionally used.
Japanese Patent Laid-Open No. 7-34784 JP-A-11-107687 Japanese Patent Laid-Open No. 11-148233 JP 2002-256707 A Japanese Patent No. 2691848

しかしながら、上記した従来の方法では繊維シート内部への硬化樹脂の含浸が悪く気泡が生じたり、樹脂と繊維の破断伸度の差が大きいために十分な補強性能が得られなかったり、施工時の繊維シートへの樹脂の染み込みに時間がかかる、等の問題を有していた。   However, in the conventional method described above, the impregnation of the cured resin into the fiber sheet is poor and air bubbles are generated, or because the difference between the elongation at break of the resin and the fiber is large, sufficient reinforcement performance cannot be obtained, or at the time of construction There was a problem that it took time for the resin to soak into the fiber sheet.

本発明は、上記状況に鑑みて、特定の物性と構造を持つ合成繊維シートを用いることにより、低いコストで、十分な補強性能を得ることができるコンクリート構造物補強用繊維シート及び補強方法を提供することを目的とする。   In view of the above circumstances, the present invention provides a fiber sheet for reinforcing a concrete structure and a reinforcing method capable of obtaining sufficient reinforcement performance at low cost by using a synthetic fiber sheet having specific physical properties and structure. The purpose is to do.

本発明は、上記目的を達成するために、
〔1〕以下の条件を満足する合成繊維シートからなるコンクリート構造物補強用繊維シート。
(a)強度が緯糸、経糸とも400〜1000N/cm
(b)破断伸度が緯糸、経糸とも5〜10%
(c)カバーファクターが40〜100%
(d)20℃、30分間でのスチレンモノマー吸い上げ長が12cm以上
〔2〕上記〔1〕記載のコンクリート構造物補強用繊維シートにおいて、前記合成繊維シートがポリビニルアルコール系繊維からなることを特徴とする。
In order to achieve the above object, the present invention provides
[1] A fiber sheet for reinforcing a concrete structure comprising a synthetic fiber sheet that satisfies the following conditions.
(A) Strength is 400 to 1000 N / cm for both weft and warp
(B) The breaking elongation is 5 to 10% for both the weft and the warp
(C) Cover factor is 40-100%
(D) Styrene monomer wicking length at 20 ° C. for 30 minutes is 12 cm or more. [2] In the fiber sheet for reinforcing a concrete structure according to the above [1], the synthetic fiber sheet is made of polyvinyl alcohol fiber. To do.

〔3〕上記〔1〕記載のコンクリート構造物補強用繊維シートにおいて、前記経糸、緯糸に撚りがかかっていることを特徴とする。   [3] The fiber sheet for reinforcing a concrete structure according to [1], wherein the warps and wefts are twisted.

〔4〕コンクリート構造物の補強方法であって、上記〔1〕、〔2〕又は〔3〕記載のコンクリート構造物補強用繊維シートに常温硬化型樹脂を含浸させることを特徴とする。   [4] A method for reinforcing a concrete structure, wherein the fiber sheet for reinforcing a concrete structure according to the above [1], [2] or [3] is impregnated with a room temperature curable resin.

〔5〕コンクリート構造物の補強方法であって、上記〔1〕、〔2〕又は〔3〕記載のコンクリート構造物補強用繊維シートに光硬化型樹脂を含浸させることを特徴とする。   [5] A method for reinforcing a concrete structure, wherein the fiber sheet for reinforcing a concrete structure according to the above [1], [2] or [3] is impregnated with a photocurable resin.

本発明によれば、以下のような効果を奏することができる。   According to the present invention, the following effects can be achieved.

(1)特定の物性と構造を持つ合成繊維シートを用いることにより、低いコストで、十分な補強性能を得ることができる。   (1) By using a synthetic fiber sheet having specific physical properties and structure, sufficient reinforcing performance can be obtained at low cost.

(2)樹脂の含浸性が高い。   (2) High resin impregnation.

(3)強度が大きい。   (3) High strength.

(4)ポリビニルアルコール系繊維を用いる場合には、適度な剛性と伸びを示す一方でエポキシやアクリル等の常温硬化型樹脂に対する親和性に優れている。   (4) When polyvinyl alcohol fiber is used, it exhibits excellent rigidity and room temperature curable resin such as epoxy and acrylic while exhibiting appropriate rigidity and elongation.

(5)本発明の合成繊維シートの価格は、従来のアラミド系繊維の価格に比べて廉価である(表1参照)。   (5) The price of the synthetic fiber sheet of the present invention is lower than that of conventional aramid fibers (see Table 1).

本発明のコンクリート構造物補強用繊維シートは、
(a)強度が緯糸、経糸とも400〜1000N/cm
(b)破断伸度が緯糸、経糸とも5〜10%
(c)カバーファクターが40〜100%
(d)20℃、30分間でのスチレンモノマー吸い上げ長が12cm以上
の条件を満足する合成繊維シートからなる。
The fiber sheet for reinforcing a concrete structure of the present invention,
(A) Strength is 400 to 1000 N / cm for both weft and warp
(B) The breaking elongation is 5 to 10% for both the weft and the warp
(C) Cover factor is 40-100%
(D) A synthetic fiber sheet satisfying the condition that the styrene monomer siphoning length at 20 ° C. for 30 minutes is 12 cm or more.

また、繊維シートの緯糸または経糸もしくはその両方の糸に撚りをかけ、繊維シートの目合いを広くすることで、補強コンクリート表面と接着剤との接触面積を広くすることができる。   Further, the contact area between the surface of the reinforced concrete and the adhesive can be widened by twisting the weft and / or the warp of the fiber sheet to widen the mesh of the fiber sheet.

以下、本発明の実施の形態について詳細に説明する。   Hereinafter, embodiments of the present invention will be described in detail.

本発明の繊維シートは、強度が緯糸、経糸とも400〜1000N/cm以上、破断伸度が5〜10%、カバーファクターが40〜100%であり、20℃、30分間でのスチレンモノマー吸い上げ長が12cm以上のコンクリート構造物の補強用合成繊維シートである。   The fiber sheet of the present invention has a strength of 400 to 1000 N / cm or more for both the weft and the warp, a break elongation of 5 to 10%, a cover factor of 40 to 100%, and a styrene monomer uptake length at 20 ° C. for 30 minutes. Is a synthetic fiber sheet for reinforcing concrete structures of 12 cm or more.

ここで、繊維シートは強度が緯糸、経糸ともに、400〜1000N/cmである必要がある。これは、400N/cm以下であるとコンクリート構造物の補強性能が不足し、1000N/cm以上にすると繊維シートが厚くなり、樹脂の含浸性が低下するためである。   Here, the fiber sheet needs to have a strength of 400 to 1000 N / cm for both the weft and the warp. This is because if the strength is 400 N / cm or less, the reinforcing performance of the concrete structure is insufficient, and if it is 1000 N / cm or more, the fiber sheet becomes thick and the impregnation property of the resin decreases.

また、繊維シートの破断伸度は5〜10%であることが必要である。これは、5%以下であると繊維が樹脂の伸びに追随せずに破断する恐れがあり、10%以上であると十分な補強効果が得られないためである。   Further, the breaking elongation of the fiber sheet needs to be 5 to 10%. This is because if it is 5% or less, the fiber may break without following the elongation of the resin, and if it is 10% or more, a sufficient reinforcing effect cannot be obtained.

繊維シートのカバーファクターは、40〜100%である必要がある。これは、40%以下では施工中に繊維の乱れが生じやすく、繊維が乱れると十分な補強効果が得られないためである。   The cover factor of the fiber sheet needs to be 40 to 100%. This is because if the amount is 40% or less, fiber disturbance is likely to occur during construction, and if the fiber is disturbed, a sufficient reinforcing effect cannot be obtained.

さらに、本発明の繊維シートは、20℃、30分間でのスチレンモノマー吸い上げ長が12cm以上である必要がある。スチレンモノマーの吸い上げ性は補強に用いられるエポキシやアクリルといった樹脂の含浸性の指標であり、これが12cm以下であると樹脂含浸が不十分となり、施工後に樹脂と繊維シートの間に亀裂が生じる恐れがあるためである。   Furthermore, the fiber sheet of the present invention needs to have a styrene monomer uptake length of 12 cm or more at 20 ° C. for 30 minutes. The uptake of styrene monomer is an index of the impregnation property of resins such as epoxy and acrylic used for reinforcement, and if it is 12 cm or less, the resin impregnation becomes insufficient, and there is a risk that cracks will occur between the resin and the fiber sheet after construction. Because there is.

ここで、繊維シートを構成する素材としてはポリビニルアルコール系ポリマーを用いることが好ましい。ポリビニルアルコール系繊維は、適度な剛性と伸びを示す一方でエポキシやアクリル等の常温硬化型樹脂に対する親和性に優れるためである。   Here, it is preferable to use a polyvinyl alcohol-based polymer as a material constituting the fiber sheet. This is because the polyvinyl alcohol-based fiber exhibits moderate rigidity and elongation, and is excellent in affinity to room temperature curable resins such as epoxy and acrylic.

図1は本発明の実施例を示す繊維シートの平面模式図であり、図1(a)はFVH−100(1m2 当たり100g)のポリビニルアルコール系繊維によって編まれた繊維シート、図1(b)はFVH−250(1m2 当たり250g)のポリビニルアルコール系繊維によって編まれた繊維シート、図1(c)はポリビニルアルコール系繊維の繊維束がばらけた状態(素材としてのポリビニルアルコール系ポリマーの繊維束がばらけて、カバーファクターが高い%にある状態)で編まれた繊維シートをそれぞれ示している。図1において、1,11,21は緯糸(1,11は繊維束)、2,12,22は経糸(2,12は繊維束)を示している。 FIG. 1 is a schematic plan view of a fiber sheet showing an embodiment of the present invention, and FIG. 1 (a) is a fiber sheet knitted with FVH-100 (100 g per m 2 ) polyvinyl alcohol fiber, FIG. ) Is a fiber sheet knitted with FVH-250 (250 g per m 2 ) polyvinyl alcohol fiber, and FIG. 1 (c) is a state in which the fiber bundle of polyvinyl alcohol fiber is scattered (fibers of polyvinyl alcohol polymer as a material) Each of the fiber sheets is knitted in a state in which the bundles are separated and the cover factor is high. In FIG. 1, 1, 11 and 21 are wefts (1, 11 are fiber bundles), and 2, 12, and 22 are warp yarns (2, 12 are fiber bundles).

図2は本発明にかかる繊維シートに織物を用いる場合において、緯糸及び経糸に撚りをかけた状態の繊維シートを示す平面模式図である。   FIG. 2 is a schematic plan view showing a fiber sheet in a state where wefts and warps are twisted when a woven fabric is used for the fiber sheet according to the present invention.

図2において、31は撚りをかけた緯糸、32は撚りをかけた経糸である。   In FIG. 2, 31 is a twisted weft and 32 is a twisted warp.

このように、繊維シートに織物を用いる場合、緯糸及び経糸の撚り係数は3.0以下であることが望ましい。これは、撚り係数が3.0より大きいと糸の内部に樹脂が含浸しにくくなり、樹脂含浸後の補強性能が低下するためである。   Thus, when using a woven fabric for the fiber sheet, it is desirable that the twist coefficient of the weft and the warp is 3.0 or less. This is because if the twist coefficient is larger than 3.0, the yarn is less likely to be impregnated with the resin, and the reinforcement performance after the resin impregnation is lowered.

ここで撚り係数とは、糸の撚り回数T〔回/2.54cm〕、糸の繊度N〔英式綿番手〕に対し、k=T/√Nで表される係数である。   Here, the twist coefficient is a coefficient represented by k = T / √N with respect to the number of twists T [twice / 2.54 cm] and the fineness N [English cotton count] of the yarn.

さらに、繊維シートが織物の場合、目止め処理(緯糸と経糸との交点を糊剤により固定する)は施されていないことが好ましい。目止め処理が施されていると、目止めに用いた糊剤が繊維束の表面に付着しているため、その分、樹脂の含浸性が低下し、補強性能が低下する恐れがあるためである。   Further, when the fiber sheet is a woven fabric, it is preferable that the sealing treatment (fixing the intersection of the weft and the warp with a glue) is not performed. When the sealing treatment is applied, the adhesive used for the sealing adheres to the surface of the fiber bundle, so that the impregnation property of the resin is lowered and the reinforcing performance may be reduced accordingly. is there.

次に、補強に用いる樹脂について説明する。   Next, the resin used for reinforcement will be described.

繊維シートの補強には、常温硬化型樹脂を用いる。この常温硬化型樹脂は特に限定されないが、エポキシ系樹脂、アクリル系樹脂、ウレタン系樹脂などを用いる。これらの樹脂は施工時に常温で反応するものであればよい。   A room temperature curable resin is used to reinforce the fiber sheet. The room temperature curable resin is not particularly limited, and an epoxy resin, an acrylic resin, a urethane resin, or the like is used. These resins should just react at normal temperature at the time of construction.

また、常温硬化型樹脂に代えて、光硬化型樹脂を用いても構わない。   Further, instead of the room temperature curable resin, a photo curable resin may be used.

以下、本発明の具体例を説明するが、本発明は、これらに限定されるものではない。   Hereinafter, specific examples of the present invention will be described, but the present invention is not limited thereto.

ここで、繊維シートの物性測定方法は、JIS L1096「一般織物試験方法」に準じた。   Here, the physical property measuring method of the fiber sheet conformed to JIS L1096 “General Textile Testing Method”.

(A)カバーファクターの測定方法
繊維シートを平面に置き、シート面に垂直な方向から写真を撮影する。得られた写真を拡大し、一定の繊維シート面積に占める繊維の面積(シート面積から空隙の面積を引いたもの)を算出する。写真撮影の代わりに繊維シートに黒い紙を貼り付け、繊維が乱れないように注意して複写機にて複写画像を取り、その面積から、単位シート面積における繊維分の面積を%表示で算出しても良い。この時、面積の算出は、複写画像を繊維分と空隙分に分けて切り抜き、それぞれの合計重量を求めて算出する。
(A) Cover factor measurement method A fiber sheet is placed on a flat surface, and a photograph is taken from a direction perpendicular to the sheet surface. The obtained photograph is enlarged, and the area of the fiber occupying a certain fiber sheet area (sheet area minus the void area) is calculated. Paste black paper on the fiber sheet instead of taking a photo, take a copy image with a copier, taking care not to disturb the fiber, and calculate the area of the fiber in the unit sheet area in% display from the area. May be. At this time, the area is calculated by dividing the copy image into a fiber part and a gap part, and calculating the total weight of each.

(B)スチレンモノマー吸い上げ長の測定方法
繊維シートから緯糸又は経糸を30cm取り出し、20℃、65%RH(相対湿度)の環境下で24時間放置した。この糸の一端を把持して垂直に垂らし、下端を20℃のスチレンモノマーに1cm漬けた。このまま、30分間おいた後のスチレンモノマー液の吸い上がった上端から液面までの距離を定規で測定し吸い上げ長(cm)とする。
(B) Measuring method of styrene monomer uptake length 30 cm of weft or warp was taken out from the fiber sheet and left for 24 hours in an environment of 20 ° C. and 65% RH (relative humidity). One end of this yarn was gripped and hung vertically, and the lower end was immersed in 1 cm of styrene monomer at 20 ° C. As it is, the distance from the upper end of the styrene monomer liquid sucked up after 30 minutes to the liquid surface is measured with a ruler to obtain the sucked length (cm).

(C)押し抜き試験方法
図3は本発明にかかるかかる押し抜き試験方法に用いる供試体の作製工程図である。
(C) Punch Test Method FIG. 3 is a production process diagram of a specimen used for the punch test method according to the present invention.

(1)まず、図3(a)に示すように、繊維シートの被着体としてコンクリート製U型ふた(JIS A5334 400×600×50mm)41を用意した。   (1) First, as shown in FIG. 3A, a concrete U-shaped lid (JIS A5334 400 × 600 × 50 mm) 41 was prepared as an adherend of a fiber sheet.

(2)次に、図3(b)に示すように、コンクリート製U型ふた41の中央部をφ100mmでコア抜き42(円柱状にくり抜き)を行った。   (2) Next, as shown in FIG. 3 (b), the core portion 42 was hollowed out (in a cylindrical shape) at a central portion of the concrete U-shaped lid 41 with a diameter of 100 mm.

(3)次いで、図3(c)に示すように、そのコア抜き42されたコンクリート製U型ふた41にアクリル樹脂系プライマー(デンカ ハードロックIIプライマー)43を塗布し、24時間、気中(20℃)で養生を行った。   (3) Next, as shown in FIG. 3 (c), an acrylic resin-based primer (Denka Hard Rock II primer) 43 was applied to the concrete U-shaped lid 41 that was cored 42, and in the air for 24 hours ( (20 ° C).

(4)その後、図3(d)に示すように、アクリル系樹脂(デンカ ハードロックII)44を500g/m2 を下塗りした。 (4) Thereafter, as shown in FIG. 3 (d), an acrylic resin (Denka Hard Rock II) 44 was undercoated with 500 g / m 2 .

(5)次に、図3(e)に示すように、アクリル系樹脂44上に合成繊維シート45を貼付した。   (5) Next, as shown in FIG. 3 (e), a synthetic fiber sheet 45 was pasted on the acrylic resin 44.

(6)次に、図3(f)に示すように、さらに同じアクリル系樹脂46を500g/m2 上塗りし、24時間、気中(20℃)で養生して供試体47とした。 (6) Next, as shown in FIG. 3 (f), the same acrylic resin 46 was further overcoated with 500 g / m 2 and cured in the air (20 ° C.) for 24 hours to obtain a specimen 47.

図4は本発明にかかる供試体の押し抜き試験機の模式図である。   FIG. 4 is a schematic view of a punch tester for a specimen according to the present invention.

上記したようにして得られた供試体47を、材料試験機51にセットして中央のコア部を1mm/minで載荷し、500N毎の剥離周長〔剥離先端の円周長さ(mm)〕を記録した。試験後、押し抜き荷重を剥離周長に対してプロットし、その直線近似の傾きから単位剥離強さ(N/mm)を測定した。   The specimen 47 obtained as described above is set on the material testing machine 51, and the central core portion is loaded at 1 mm / min, and the peeling peripheral length [the circumferential length of the peeling tip (mm) at every 500 N]. ] Was recorded. After the test, the punching load was plotted against the peel circumference, and the unit peel strength (N / mm) was measured from the slope of the linear approximation.

なお、本発明の繊維シートにおいては、さらに、繊維シートの縦糸または横糸もしくはその両方に一定間隔でフィラメント(繊維)数、またはデニール(径)数を大きくすることにより、径の大きなストランドを組み入れた繊維シートにより、繊維シートの付着力を向上させることができる。   In the fiber sheet of the present invention, strands having a large diameter are incorporated by increasing the number of filaments (fibers) or the number of deniers (diameters) at regular intervals in the warp and / or weft of the fiber sheet. The fiber sheet can improve the adhesion of the fiber sheet.

また、繊維シート貼付前にメッシュの大きなネットまたはグリッドを敷設し、繊維シートとコンクリート面(プライマー層)間に接着剤を十分に介在させ、繊維シートの付着力を向上させる。
(実施例1)
2000dtex(デシテックス)のポリビニルアルコール繊維(クラレ製品番5516−1)に100回/m(撚り係数1.5)の撚りをかけたものを緯糸と経糸に用い、緯糸、経糸とも54本/15cmの密度で平織りの織物を作製し、コンクリート補強性能を測定した。
Further, a net or grid having a large mesh is laid before sticking the fiber sheet, and an adhesive is sufficiently interposed between the fiber sheet and the concrete surface (primer layer) to improve the adhesion of the fiber sheet.
Example 1
2000 dtex (decitex) polyvinyl alcohol fiber (Kuraray product number 5516-1) twisted 100 times / m (twisting factor 1.5) is used for weft and warp, and both weft and warp are 54/15 cm. A plain weave fabric was prepared at a density and the concrete reinforcement performance was measured.

繊維シートの物性とコンクリート補強性能測定結果を表1に示す。   Table 1 shows the physical properties of the fiber sheet and the measurement results of the concrete reinforcement performance.

この織物の重量は150g/m2 、引張強度は緯糸560N/cm、経糸540N/cm、破断伸度は緯糸7.2%、経糸7.2%で、カバーファクターは56%、スチレンモノマー吸上げ性は17cmであった。次に、この繊維シートを用いてコンクリート補強性を押し抜き試験法にて測定したところ、単位剥離強さは4.2N/mmで十分な補強性を示し、樹脂中の気泡も少なく、長期耐久性も問題のないものであった。
(実施例2)
ポリビニルアルコール繊維の打ち込み密度を70本/15cmとした以外は実施例1と同様にして織物を作製し、コンクリート補強性能を測定した。繊維シートの物性とコンクリート補強性能測定結果を表1に示す。実施例1と同様、気泡の少ない補強体が形成され、十分なコンクリート補強性能を示した。
(実施例3)
繊維束をばらけさせ、カバーファクターを100%とした以外は、実施例1と同様にして織物を作製し、コンクリート補強性能を測定した。繊維シートの物性とコンクリート補強性能測定結果を表1に示す。実施例1と同様に気泡の少ない補強体が形成され、十分なコンクリート補強性能を示した。
(比較例1)
ポリビニルアルコール繊維の打ち込み密度を39本/15cmとした以外は、実施例1と同様にして織物を作製し、コンクリート補強性能を測定した。
This fabric has a weight of 150 g / m 2 , a tensile strength of 560 N / cm for the weft, 540 N / cm for the warp, 7.2% for the weft and 7.2% for the warp, 56% for the cover factor, and styrene monomer uptake. The sex was 17 cm. Next, using this fiber sheet, the concrete reinforcement was measured by a punching test method. The unit peel strength was 4.2 N / mm, indicating sufficient reinforcement, and there were few bubbles in the resin, resulting in long-term durability. There was no problem with sex.
(Example 2)
A woven fabric was prepared in the same manner as in Example 1 except that the polyvinyl alcohol fiber driving density was set to 70/15 cm, and the concrete reinforcing performance was measured. Table 1 shows the physical properties of the fiber sheet and the measurement results of the concrete reinforcement performance. Similar to Example 1, a reinforcing body with few bubbles was formed, and sufficient concrete reinforcing performance was exhibited.
(Example 3)
A woven fabric was produced in the same manner as in Example 1 except that the fiber bundles were separated and the cover factor was 100%, and the concrete reinforcing performance was measured. Table 1 shows the physical properties of the fiber sheet and the measurement results of the concrete reinforcement performance. As in Example 1, a reinforcing body with few bubbles was formed, and sufficient concrete reinforcing performance was exhibited.
(Comparative Example 1)
A woven fabric was prepared in the same manner as in Example 1 except that the polyvinyl alcohol fiber driving density was set to 39/15 cm, and the concrete reinforcing performance was measured.

繊維シートの物性とコンクリート補強性能測定結果を表1に示す。カバーファクター及び繊維シートの強度が低く、コンクリート補強性能も十分ではなかった。
(比較例2)
ポリビニルアルコール繊維を高伸度タイプ(クラレ製品番1225−7、繊度1100dtex)とし、製織前の撚糸で2本合糸して2200dtexとした以外は実施例2と同様にして織物を作製し、コンクリート補強性能を測定した。繊維シートの物性とコンクリート補強性能測定結果を表1に示す。繊維シートの破断伸度が大きかったために十分なコンクリート補強性能が得られなかった。また、スチレンモノマー吸い上げ性も低く、成型後の樹脂中に気泡が多く見られ、長期間耐久性に問題を残した。
(比較例3)
織物を構成する繊維を1670dtexのアラミド繊維(東レデュポン・ケブラー社製ケブラー29)とし、打ち込み密度を41本/15cmとした以外は、実施例1と同様にして織物を作製し、コンクリート補強性能を測定した。
Table 1 shows the physical properties of the fiber sheet and the measurement results of the concrete reinforcement performance. The cover factor and the strength of the fiber sheet were low, and the concrete reinforcement performance was not sufficient.
(Comparative Example 2)
A woven fabric was prepared in the same manner as in Example 2 except that the polyvinyl alcohol fiber was a high elongation type (Kuraray product number 1225-7, fineness 1100 dtex), and two yarns were combined with a twisted yarn before weaving to give 2200 dtex. Reinforcing performance was measured. Table 1 shows the physical properties of the fiber sheet and the measurement results of the concrete reinforcement performance. Since the breaking elongation of the fiber sheet was large, sufficient concrete reinforcement performance could not be obtained. Further, the styrene monomer absorbability was low, and many bubbles were observed in the resin after molding, leaving a problem in durability for a long time.
(Comparative Example 3)
Fabrics were produced in the same manner as in Example 1 except that the fibers constituting the fabrics were aramid fibers of 1670 dtex (Kevlar 29 manufactured by Toray DuPont Kevlar Co., Ltd.) and the driving density was 41 fibers / 15 cm. It was measured.

繊維シートの物性とコンクリート補強性能測定結果を表1に示す。単位剥離強さは高かったが、樹脂中に気泡が多く見られ、長期間での耐久性に問題が残った。また、材料価格は、実施例1〜2、比較例1〜2に比べて5割程度高いものとなった。   Table 1 shows the physical properties of the fiber sheet and the measurement results of the concrete reinforcement performance. Although the unit peel strength was high, many bubbles were observed in the resin, and there was a problem in durability over a long period of time. Moreover, the material price was about 50% higher than Examples 1-2 and Comparative Examples 1-2.

Figure 2005350879
Figure 2005350879

また、繊維シートの緯糸または経糸もしくはその両方の糸に一定間隔で結び目を設けるようにしてもよい。かかる場合には、繊維シートとコンクリート面(プライマー層)間に樹脂を十分に介在させ、繊維シートの付着力を向上させることができる。   Further, knots may be provided at regular intervals on the weft and / or warp of the fiber sheet. In such a case, the resin can be sufficiently interposed between the fiber sheet and the concrete surface (primer layer) to improve the adhesion of the fiber sheet.

なお、本発明は上記実施例に限定されるものではなく、本発明の趣旨に基づいて種々の変形が可能であり、これらを本発明の範囲から排除するものではない。   In addition, this invention is not limited to the said Example, A various deformation | transformation is possible based on the meaning of this invention, and these are not excluded from the scope of the present invention.

本発明のコンクリート構造物補強用繊維シート及び補強方法は、鉄道トンネル覆工の補修・補強をはじめ、トンネルの変状抑制、橋脚の耐震補強などの対策に利用可能である。   INDUSTRIAL APPLICABILITY The fiber sheet for reinforcing a concrete structure and the reinforcing method according to the present invention can be used for countermeasures such as repair and reinforcement of railway tunnel lining, suppression of tunnel deformation, and seismic reinforcement of bridge piers.

本発明の実施例を示す繊維シートの平面模式図である。It is a plane schematic diagram of the fiber sheet which shows the Example of this invention. 本発明にかかる繊維シートに織物を用いる場合において、緯糸及び経糸に撚りをかけた状態の繊維シートを示す平面模式図である。When using a textile fabric for the fiber sheet concerning this invention, it is a plane schematic diagram which shows the fiber sheet of the state which applied | twisted the weft and the warp. 本発明にかかる押し抜き試験方法に用いる供試体の作製工程図である。It is a manufacturing-process figure of the test body used for the punching-out test method concerning this invention. 本発明にかかる供試体の押し抜き試験機の模式図である。It is a schematic diagram of the punch tester of the specimen concerning this invention.

符号の説明Explanation of symbols

1,11,21 緯糸
2,12,22 経糸
31 撚りをかけた緯糸
32 撚りをかけた経糸
41 コンクリート製U型ふた
42 コア抜き
43 アクリル樹脂系プライマー
44,46 アクリル系樹脂
45 合成繊維シート
47 供試体
51 材料試験機
1,11,21 Weft 2,12,22 Warp 31 Twisted weft 32 Twisted warp 41 Concrete U-shaped lid 42 Core removal 43 Acrylic resin primer 44, 46 Acrylic resin 45 Synthetic fiber sheet 47 Specimen 51 Material testing machine

Claims (5)

以下の条件を満足する合成繊維シートからなるコンクリート構造物補強用繊維シート。
(a)強度が緯糸、経糸ともに400〜1000N/cm
(b)破断伸度が緯糸、経糸ともに5〜10%
(c)カバーファクターが40〜100%
(d)20℃、30分間でのスチレンモノマー吸い上げ長が12cm以上
A fiber sheet for reinforcing a concrete structure comprising a synthetic fiber sheet that satisfies the following conditions.
(A) Strength is 400 to 1000 N / cm for both weft and warp
(B) 5-10% breaking elongation for both weft and warp
(C) Cover factor is 40-100%
(D) Styrene monomer uptake length of 12 cm or more at 20 ° C. for 30 minutes
請求項1記載のコンクリート構造物補強用繊維シートにおいて、前記合成繊維シートがポリビニルアルコール系繊維からなることを特徴とするコンクリート構造物補強用繊維シート。 2. The fiber sheet for reinforcing a concrete structure according to claim 1, wherein the synthetic fiber sheet is made of polyvinyl alcohol fiber. 請求項1記載のコンクリート構造物補強用繊維シートにおいて、前記経糸、緯糸に撚りがかかっていることを特徴とするコンクリート構造物補強用繊維シート。 2. The fiber sheet for reinforcing a concrete structure according to claim 1, wherein the warp and the weft are twisted. 請求項1、2又は3記載のコンクリート構造物補強用繊維シートに常温硬化型樹脂を含浸させることを特徴とするコンクリート構造物の補強方法。 A method for reinforcing a concrete structure, comprising impregnating the fiber sheet for reinforcing a concrete structure according to claim 1, 2 or 3 with a room temperature curable resin. 請求項1、2又は3記載のコンクリート構造物補強用繊維シートに光硬化型樹脂を含浸させることを特徴とするコンクリート構造物の補強方法。 A method for reinforcing a concrete structure, comprising impregnating the fiber sheet for reinforcing a concrete structure according to claim 1, 2 or 3 with a photocurable resin.
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Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2691848B2 (en) * 1993-04-26 1997-12-17 昭和高分子株式会社 Concrete lining material and lining method
JP2002029867A (en) * 1996-04-26 2002-01-29 Nippon Nsc Ltd Method for reinforcing concrete structure and radical- polymerizable primer and radical-polymerized hardened resin-forming composition, for use in the same
JP2003013612A (en) * 2001-07-03 2003-01-15 Toray Ind Inc Method for reinforcing concrete structure

Patent Citations (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2691848B2 (en) * 1993-04-26 1997-12-17 昭和高分子株式会社 Concrete lining material and lining method
JP2002029867A (en) * 1996-04-26 2002-01-29 Nippon Nsc Ltd Method for reinforcing concrete structure and radical- polymerizable primer and radical-polymerized hardened resin-forming composition, for use in the same
JP2003013612A (en) * 2001-07-03 2003-01-15 Toray Ind Inc Method for reinforcing concrete structure

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2016191170A (en) * 2015-03-31 2016-11-10 セーレン株式会社 Cover material

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