201209238 六、發明說明: 【發明所屬之技術領域】 本發明是有關於一種工業用織物’特別是指一種被覆 在土工場合的工業用織物。 【先前技術】 近年來,地工織布在土木水利,尤其是在災後擔:修工 程中的大量應用及其成效,.引起了廣大工程技術人員的高 度重視。由於地工織布的工作環境惡劣,报多情況下是舖 設於濕度很大的土中,所以必須具.有良好的抗水解性能、 濕態機械性能,及良好的透水性。 參閱圖1、圖2,以目前常見的土木工程織布i為例, 主要包含有數經紗11與數緯紗12。編織時’是採用平紋織 法(Plain Weave)以二根經紗u及二根緯紗12完成一個循環 ,及以一條緯、紗12 -上一下交織於該等經紗u之間。利用 此法編織而成的土木工程織布丨強度高且牢固,為最常使 用的織法。 .,由於土木工程織布1必需滿足強度與透水性的 因此’每-條紗線的單絲數量、或強度、或氣隙, =決疋前述土木卫程織布i是否能夠使水分順利通過而 擋砂土顆粒流失的關鍵,前述以平織法正交編織的經紗 與緯、v 12會因為受限於、織法及單絲數量沒有最佳化的影 ’而面臨密度過高導致透水性不佳,或密度過低導致強 ::的蒼境,有強度與透水性無法兼顧,而不能滿足使 鸪求的缺失。 201209238 參閱圖3 _ 4,另以—種裂絲土^•織布2為例,主要 包含有採用平紋織法或斜紋織法(twillweave)以經向、緯向 交錯織造的數裂絲紗線2卜每一裂絲紗線21是由一膜片切 割形成彼此不斷開的數模裂單絲211,再經過掩紗處理而成 〇 。。惟,由於每-模裂單、絲2n呈爲平狀,強度較圖丄所示 的單絲低,而要投入更多的原料,才能達到需求的強度, 因此,在同樣強度的要求下’裂絲土工織彳2的重量明顯 較重,且成本高,施工時的人力需求也較高。 【發明内容】 因此’本發明之㈣,即在提供一種能夠兼顧強度與 透水性的工業用織物 於疋’本發明的工業用織物,包含數條紗線。該等紗線 採用斜紋織法以經向、緯向交錯織造,使料.紗線經向、緯 向至夕其中一方向的任一斷面’每英吋包含有·心麵條的 單絲纖維,且每一條單絲纖維的細度界於5〇丹尼〜5〇〇丹尼 〇 本發明的有益效果在於:利用斜紋織法配合高單位數 的單絲纖維及其間存在的間隙,在具有足夠強度的情形下 ’仍然保有良好的透水性質。 【實施方式】 有關本發明之前述及其他技術内容、特點與功效,在 以下配合參考圖式之數較佳實施例的詳細說明中,將可清 楚的呈現。 201209238 參閱圖5、圖6’及圖7’本發明工業用織物3的一第 一較佳實施例包含數紗線,且該等紗線區分有數條複絲紗 線31,及數條單絲紗線32。 該等複絲紗線31與該等數單絲紗線32在本較佳實施 例分別是一種高分子聚合物,如聚丙烯(p〇lypr〇pylene,pp) 、I 對本一曱酸乙二醇 g旨(p〇lyethyie,ne terephthalate,PET.) 、聚乙烯(Polyethylene,PE)。每一條複絲紗線3丨是由數條 單絲纖維311集結成束,每一條單絲纖維3丨丨的細度界於 50丹尼〜500丹尼。每一條單絲紗線32為一條單絲纖維, 細度界於501丹尼〜2〇〇〇丹尼。 編織時,該等複絲紗線3丨與該等單絲紗線32採用斜 紋織法(twillweave)以經向、緯向交錯織造,紋路可以左斜 或右斜,而斜紋織法可以是n/1斜紋〜n/7斜紋其中一種,前 述 η 值界於 2〜7,如 2/2、3/2、4/2、5/1、6/1、3/7 ·等等 以2/1斜紋為例,即表示有二根經向的紗線(複絲紗線31 或單絲紗、線32)在上 '一根緯向的紗線(複絲紗線3】或單絲 紗線32)在下梭織而成。重要的是,依循經向、緯向其中: ^向的任―斷面’每英料含有赛2_條的單絲纖維 1 ’或5-60條的單絲紗線32。 藉此,使該等複絲紗線31與單絲紗線32包含有下 七種變化: 列…示’該工某用織物3由分別沿經 、u ’早絲紗線32與沿緯向排列的該等複絲紗線3 用2/1斜紋織法交錯織造而成。 201209238 如圖8〜圆10所示,該工業用 、 排列的該等複絲紗線31 ,, ^別沿緯向 絲紗線32,採用2/一:“]/。緯向、經向㈣的該等單 用2/1斜紋織法交錯織造而成。 排綱如等圖單==’該工業用織物3由分別沿缚向 採用-斜紋織法交錯織造=排列的該等複絲紗線31 ’ 排列的=/4〜圖Μ所示’該工業用織物3由分別沿經向 絲紗線31與分別沿緯向、經向排列的該等單 ,、“線32,採用2/1斜紋織法交錯織造而成。 Μ广如二17〜圖19所示’該工業用織物3由分別沿緯向 歹I的該等單絲紗、線32與分別沿緯向、經向排列的該等複 絲紗線31,採用2/1斜紋織法交錯織造而成。 6、如圖20〜圖22所示’該工業用織物3由分別沿經向 排列的該等單絲紗線32與分別沿緯向、經向排列的該等複 絲紗線31 ’採用2/1斜紋織法交錯織造而成。 7、如圖23〜圖25所示,該工業用織物3由分別沿經向 、緯向排列的該等複絲紗線3丨與分別沿緯向、經向排列的 該等單絲紗線32,採用2/1斜紋織法交錯織造而成。 藉此’由於該工業用織物3採用斜紋織法,交織使用 了大量的複絲紗線31或單絲紗線32,而每一條複絲紗線 31是由高單位數的單絲纖維3丨丨集結成束,因此,不但可 以彌補斜紋織法不及平織法牢固的不足,而使該工業用織 物3的布面強度達到約S0KN/M,且該等纖維311間存在的 大量間隙,可以使該工業用織物3的透水性達到900公升 201209238 /Μ2,相較於一般25KN工業用織物的透水性U1公升/M2, 或一般45KN工業用織物的透水性270公升/Μ2,其透水性 明顯提南了 330%〜800%。 參閱圖26、圖27,及圖28,是本發明一第二較佳實施 例,其與該第一較佳實施例大致相同’不同處在於: 該工業用織物3包含採用2/1斜紋織法以經向、緯向交 錯織造的數複絲紗線31。每一複絲紗線3丨同樣包含有數條 單絲纖維311。每一條單絲纖維311的細度界於5〇丹尼〜5〇〇 丹尼。且重要的是,依循經向、緯向其中一方向延伸的任一 斷面’每英吋包含有2〇〇_2〇〇〇條的單絲纖維。 其同樣可以利用斜紋織法配合高單位數的單絲纖維叫 及其間存在的間隙’在具有足夠強度的情形下,仍然保有良 好的透水性質。 參閱圖29、圖30 ,該工業用織物3由分別沿緯向、經 向排列的該等複絲紗線31,採用3/1斜紋織法交錯織造而 成。 據上所述可知,本發明之工業用織物具有下列優點及 功效: 本發明採用斜紋織法,並限定每英时包含有細-厕 條的單絲纖維3U,或5_6〇條的單絲紗線%,不作能夠獲 得所需的布面強度’及以該等單絲纖維311間存在的大量間 隙’保有良好的透水性質,在兼具強度與透水性的情形下 ’滿足使用需求’ it而能夠提升使用上的方便性與實用性 201209238 惟以上所述者,僅為本發明之較佳實施例而已, 能以此限;t本發明實施之範圍’即大凡依本發明: 範圍及發明說明内容所作之簡單的等效變化與修飾1 屬本發明專利涵蓋之範圍内。 【圖式簡單說明】 圖1是一平面圖,說明一般以平織法編織而成的土太 工程織布; + 圖2是前述土木工程織布的一剖視圖; 圖3是一平面圖’說明-般的裂絲土工織布; 圓4是前述裂絲土工織布的一剖視圖; 圖5是一平面圖,說明本發明一工業用織物的一第— 較佳實施例的第一種實施態樣; 圖6是沿圖5剖線6·6的一剖視圖; 圖7是沿圖5剖線7_7的一剖視圖; 圖8疋丨面圖,說明該第_較佳實施例的第二種實 施態樣; 圖9是沿圖8剖線9-9的一剖視圖; 圖10是沿圖8剖線ΐ〇·1〇的一剖視圖; 圖11是-平面圖,說明該第一較佳實施例的第三種實 施態樣; 圖12是沿圖11剖線12_12的一剖視圖; 圖13是沿圖11剖線13·13的一剖視圖; 圖14疋平面圖,說明該第一較佳實施例的第四種實 施態樣;. 8 201209238 圖15是沿圖14剖線15-15的一剖視圖; 圖16是沿圖14剖線16-16的一剖視圖; 圖17是一平面圖,說明該第一較佳實施例的第五種實 施態樣; 圖18是沿圖17剖線18-18的一剖視圖; 圖19是沿圖17剖線19-19的一剖視圖; 圖20是一平面圖,說明該第一較佳實施例的第六種.實 施態樣; 圖21是沿圖20剖線21-21的一剖視圖; 圖22是沿圖20剖線22-22的一剖視圖; 圖23是一平面圖,說明該第一較佳實施例的第二種實 施態樣; 圖24是沿圖23剖線24-24的一剖視圖; .圖25是沿圖23剖線25-25的一剖視圖; 圖26是一平面圖,說明本發明一工業用織物的一第二 較佳實施例的第一種實施態樣; 圖27是沿圖26剖線27-27的一剖視圖; 圖28是沿圖26剖線28-28的一剖視圖; 圖29是一平面圖,說明該第二較佳實施例的第二種實 施態樣;及 圖30是沿圖29剖線30-30的一剖視圖。 201209238 【主要元件符號說明】 3 ..........工業用織物 311 .......單絲纖維 31.........複絲紗線 32.........單絲紗線 10201209238 VI. Description of the Invention: [Technical Field of the Invention] The present invention relates to an industrial fabric', particularly to an industrial fabric coated in a geotechnical setting. [Prior Art] In recent years, geotextiles have been widely used in civil engineering, especially in the aftermath of the disaster: the large number of applications and their effects in the repair process have attracted the attention of engineers and technicians. Due to the harsh working environment of geotextile weaving, it is often placed in soil with high humidity, so it must have good hydrolysis resistance, wet mechanical properties, and good water permeability. Referring to FIG. 1 and FIG. 2, taking the common civil engineering weaving i as an example, a plurality of warp yarns 11 and a number of weft yarns 12 are mainly included. In the weaving process, a single warp yarn u and two weft yarns 12 are used to complete one cycle by a plain weave, and a weft yarn 12 is wound up between the warp yarns u. The civil engineering weave woven by this method is strong and strong, and is the most commonly used weave. Since the civil engineering weaving fabric 1 must meet the strength and water permeability, the number, or the strength, or the air gap of each yarn, = whether the above-mentioned civil engineering weaving fabric i can pass the water smoothly. The key to the loss of sand-repellent particles, the warp yarns and wefts, which are orthogonally woven by the plain weave method, will be exposed to water due to the lack of optimum density due to the limitation of the weave and the number of filaments. Poor, or too low density leads to strong:: the celestial environment, the strength and water permeability can not be balanced, but can not satisfy the lack of pleading. 201209238 Refer to Figure 3 _ 4, and take the example of a kind of cracked silk ^• woven fabric 2, which mainly includes several split yarns which are weaved in the warp and weft directions by plain weave or twill weave. 2, each of the split yarns 21 is cut by a film to form a number of split-mold filaments 211 which are not broken from each other, and then subjected to masking treatment to form a crucible. . However, since each mold split and the wire 2n are flat, the strength is lower than that of the monofilament shown in Fig. 而, and more raw materials are required to achieve the required strength, and therefore, under the same strength requirement' The weight of the cracked geotextile woven fabric 2 is obviously heavy, and the cost is high, and the manpower requirement during construction is also high. SUMMARY OF THE INVENTION Therefore, (4) of the present invention provides an industrial fabric which can achieve both strength and water permeability. The industrial fabric of the present invention comprises a plurality of yarns. These yarns are weft-woven in the warp and weft directions by twill weave, so that any cross section of the yarn in the warp direction, the weft direction and the eve of the yarn is included in each thread. And the fineness of each monofilament fiber is limited to 5 〇 Danny 〇〇 5 〇〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 〇 In the case of sufficient strength, 'has still maintained good water permeability. The above and other technical contents, features, and advantages of the present invention will be apparent from the following detailed description of the preferred embodiments. 201209238 Referring to Figures 5, 6' and 7', a first preferred embodiment of the industrial fabric 3 of the present invention comprises a plurality of yarns, and the yarns are divided into a plurality of multifilament yarns 31, and a plurality of monofilaments. Yarn 32. The multifilament yarns 31 and the equal number of monofilament yarns 32 are respectively a high molecular polymer in the preferred embodiment, such as polypropylene (p〇lypr〇pylene, pp), I. Alcohol g (p〇lyethyie, ne terephthalate, PET.), polyethylene (Polyethylene, PE). Each of the multifilament yarns 3 is composed of a plurality of monofilament fibers 311, and the fineness of each of the monofilament fibers is limited to 50 denier to 500 denier. Each monofilament yarn 32 is a monofilament fiber with a fineness of 501 Danny ~ 2 〇〇〇 Danny. When weaving, the multifilament yarns 3丨 and the monofilament yarns 32 are weft-woven in the warp and weft directions by twill weave, and the weaves may be left-slanted or right-slanted, and the twill weave may be n. One of the /1 twill ~n/7 twill, the aforementioned η value is bounded by 2 to 7, such as 2/2, 3/2, 4/2, 5/1, 6/1, 3/7, etc. to 2/ 1 twill as an example, that is, there are two warp yarns (multifilament yarn 31 or monofilament yarn, thread 32) on top of a weft yarn (multifilament yarn 3) or monofilament yarn Line 32) is woven underneath. It is important to follow the warp and weft directions: where the ^-direction is a cross-section of each of the monofilament fibers 1' or 5-60 of the monofilament yarns 32. Thereby, the multifilament yarns 31 and the monofilament yarns 32 are comprised of the following seven variations: Columns ... show that the fabric 3 is made of the warp yarns and the weft yarns The aligned multifilament yarns 3 are interwoven in a 2/1 twill weave. 201209238 As shown in FIG. 8 to circle 10, the industrial, arranged multifilament yarns 31, and the weft yarns 32 are 2/one: "]/. Weft, warp (4) These sheets are interwoven by 2/1 twill weave. The row is as shown in the figure == 'The industrial fabric 3 is made of the multifilament yarns which are interlaced by the twill weaves respectively. The line 31' is arranged in the form of =/4~Fig. 'The industrial fabric 3 is made up of the warp yarns 31 along the warp yarns, respectively, in the weft direction, the warp direction, and the line 32, using 2/ 1 Twill weave is interwoven. Μ广如二17~19, 'the industrial fabric 3 is composed of the monofilament yarns, the thread 32, and the multifilament yarns 31 arranged in the weft direction and the warp direction, respectively. Interwoven with 2/1 twill weave. 6. As shown in Fig. 20 to Fig. 22, the industrial fabric 3 is made of the monofilament yarns 32 arranged in the warp direction and the multifilament yarns 31' arranged in the weft direction and the warp direction, respectively. /1 Twill weave is interwoven. 7. As shown in FIG. 23 to FIG. 25, the industrial fabric 3 is composed of the multifilament yarns 3 分别 arranged in the warp direction and the weft direction, and the monofilament yarns respectively arranged in the weft direction and the warp direction. 32, interwoven with 2/1 twill weave. Thus, since the industrial fabric 3 is twill weave, a large number of multifilament yarns 31 or monofilament yarns 32 are used for interlacing, and each multifilament yarn 31 is made of a high number of monofilament fibers. The bundles are bundled together, so that not only can the twill weave be less than the firmness of the plain weave, but the fabric strength of the industrial fabric 3 reaches about S0KN/M, and a large amount of gaps between the fibers 311 can be made. The industrial fabric 3 has a water permeability of 900 liters 201209238 / Μ 2, compared with the water permeability U1 liter / M2 of the general 25KN industrial fabric, or the water permeability of the general 45KN industrial fabric is 270 liter / Μ 2, the water permeability is significantly improved South is 330%~800%. Referring to Figures 26, 27, and 28, there is shown a second preferred embodiment of the present invention which is substantially identical to the first preferred embodiment. The difference is that the industrial fabric 3 comprises a 2/1 twill weave. The method is a plurality of multifilament yarns 31 which are woven in the warp direction and the weft direction. Each multifilament yarn 3丨 also contains a plurality of monofilament fibers 311. The fineness of each monofilament fiber 311 is limited to 5 〇 Danny ~ 5 丹 Danny. It is also important that any section extending in one of the warp direction and the weft direction contains 2 〇〇 2 〇〇〇 of monofilament fibers per inch. It is also possible to use twill weave in combination with a high unit number of monofilament fibers and the gaps present between them to maintain good water permeability properties with sufficient strength. Referring to Figures 29 and 30, the industrial fabric 3 is formed by interlacing the multifilament yarns 31 arranged in the weft direction and the warp direction by a 3/1 twill weave. As can be seen from the above, the industrial fabric of the present invention has the following advantages and effects: The present invention adopts a twill weave method and defines a monofilament yarn of 3 U, or 5_6 purlin, which contains a fine-toilet strip per inch. Line %, which does not have the required cloth strength 'and a large amount of gaps between the monofilament fibers 311', retains good water permeability, and satisfies the use demand in the case of both strength and water permeability. The convenience and practicability of the use can be improved. 201209238 However, the above description is only a preferred embodiment of the present invention, and can be limited thereto; t the scope of the present invention is the invention according to the invention: scope and invention description The simple equivalent changes and modifications made by the content are within the scope of the invention. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a plan view showing a geotextile woven fabric generally woven by a plain weave; + Fig. 2 is a cross-sectional view of the aforementioned civil engineering woven fabric; Fig. 3 is a plan view illustrating A split-wire geotextile weave; a circle 4 is a cross-sectional view of the aforementioned split-wire geotextile; and Figure 5 is a plan view showing a first embodiment of a first preferred embodiment of an industrial fabric of the present invention; Figure 7 is a cross-sectional view taken along line 7-7 of Figure 5; Figure 7 is a cross-sectional view taken along line 7-7 of Figure 5; Figure 8 is a plan view showing a second embodiment of the first preferred embodiment; 9 is a cross-sectional view taken along line 9-9 of FIG. 8; FIG. 10 is a cross-sectional view taken along line 图·1 of FIG. 8; and FIG. 11 is a plan view showing the third embodiment of the first preferred embodiment. Figure 12 is a cross-sectional view taken along line 12-12 of Figure 11; Figure 13 is a cross-sectional view taken along line 13-13 of Figure 11; Figure 14 is a plan view showing a fourth embodiment of the first preferred embodiment 8 201209238 FIG. 15 is a cross-sectional view taken along line 15-15 of FIG. 14; FIG. 16 is a cross-sectional view taken along line 16-16 of FIG. 14; Fig. 18 is a cross-sectional view taken along line 18-18 of Fig. 17; Fig. 19 is a cross-sectional view taken along line 19-19 of Fig. 17; Fig. 20 is a plan view showing a fifth embodiment of the first preferred embodiment; Figure 21 is a plan view showing a sixth embodiment of the first preferred embodiment; Figure 21 is a cross-sectional view taken along line 21-21 of Figure 20; Figure 22 is a cross-sectional view taken along line 22-22 of Figure 20; Figure 23 is a plan view showing a second embodiment of the first preferred embodiment; Figure 24 is a cross-sectional view taken along line 24-24 of Figure 23; Figure 25 is a line 25-25 along Figure 23. Figure 26 is a plan view showing a first embodiment of a second preferred embodiment of an industrial fabric of the present invention; Figure 27 is a cross-sectional view taken along line 27-27 of Figure 26; Figure 29 is a plan view showing a second embodiment of the second preferred embodiment; and Figure 30 is a cross-sectional view taken along line 30-30 of Figure 29; . 201209238 [Explanation of main component symbols] 3 ..........Industrial fabric 311 .......monofilament fiber 31......multifilament yarn 32... ...monofilament yarn 10