五、新型說明: .【新型所屬之技術領域】 本創作係有關於一種陣列多角錐形立體網,尤指一種應用於 過濾水或空氣中雜質,或地工植生的之網體結構。 【先前技術】 按一般習知水或空氣濾網,有不織布濾網與編織濾網。不織布 濾網係由多層堆疊所構成,其壓差高,結構強度不佳,容易損壞,且 依不同過濾物質環境造成不可回收再利用。至於,目前所知的習用 編織濾網,雖具有壓差低的特性,但因其為纖維簡單編織的結構, 結構強度仍不佳,受力面積小,相對地單位面積受力極大,容易損 I而且粒子攔戴效能低。因此,實有改良之必要。 再者,由於土壤容易被雨水沖刷而流失,為了避免此種情形發 生,乃有所謂的植生網應運而生。亦即植生網主要是應用在水土的 保持,例如邊坡、草種植生等相關環境保育的工程,藉以防止土壤 直接被雨水沖刷而流失,使水滲透保留土壤養分。目前已有許多的 習知植生網被研究或開發,例如台灣公告第484629號、第576452 號、第 M287042 號、第 M249977 號、第 M410754 號及第 M406349 號等專利案。其中第牝牝29號、第576452號、第M287042號等 等前案,主要係為夾層式的網毯結構即在上、下網層之間設置一 密集的椰纖、不織布或棉質物構成的纖維層,使網毯具有足夠的 厚度和緩衝作用,藉以阻止雨水對土壤沖刷,而產生水土保持和綠 化植生的效果。然而,夾層網毯本身並不具有容納泥土的有效空 間,主要利用其加大的厚度來阻擒泥土流失,因而在其厚度大而孔 M427394 • * 隙小的情形下,並不利於植物的根部依附及生長,而且將上下方泥 土做大間距間隔,會有顯著的斷層現象。前述第M249977號專利 案,其係複層疊置的格網經熱熔合為一體,並且使其中一層格網 形成凹凸起伏或排列的波浪狀立體結構。為了保持立體波浪結構, 其係選擇較硬的材料製成,例如塑膠材料,因此比較沒有彈性,造 成捲收運送的不便。第M41_號專利案,係為一種立體格柵式植 生網包括上層織物、下層織物,及位於上、下層織物間的立體格 籲栅。該上、下層織物具有多數網目單元係由兩條以上的縱向環線 及橫向環線連續式上下交錯層織呈立體格柵結構。然而,該前案技 術為格柵結構,只能做周圍的框圍,並不能彼覆做上下層土壞的水 土保持,位於底部的泥土仍會由下方流失,效果不彰。第M4〇6349 號,為一種立體環絨狀植生網毯結構,係以線材加工織造呈上下層 之交又雙環環扣之立體結構,然而該前案技術結構鬆散,結構強度 不佳,水土保持效果不彰。綜合上述各種習知技藝,大致有后述幾 點缺失:結構鬆散,強度不佳,容易損壞;而且,無法兼具有效抓住 鲁泥土,良好排水性,及空氣流通性等功效。 有鑑於上述習知水、空氣濾網及植生網所產生之缺失,本創作 人乃積極努力研究,終不斷試驗及實作,終有本創作之成果產出。 【新型内容】 本創作之第一目的,在提供一種結構強度佳,不易變形或損壞, 易於捲收裝運,適用水、空氣過濾,及應用於各種坡形土壤使用,供 舖置於泥土中,以做水土保持之地工工程使用的陣列多角錐形立 體網。達成此目的之技術手段,係由縱向纖維及橫向纖維所編織而 4 M427394 成之網體,網體的正、反面分別形成有複數個陣列分佈的多邊面錐 形網槽,每-個多邊面錐形網槽的内徑自其底部到其開口呈逐漸 擴大狀。 本創作之第二目的,在提供一種提高水土保持功效的陣列多 角錐形立體,達錢目的之技射段,係轉峨的最大深度與 最大寬度的比值至少為〇. 3。 本創作之第三目的,在提供一種可大幅提高結構強度的陣列 #多角錐形立體網。達成此目的之技術手段,係該多邊錐形槽為八面 錐形網槽,每-該錐形網槽的環壁包括有依序交錯環佈四個單纖 區及四個交織區,該四個單纖區兩兩相對,兩相對該單纖區分別由 複數條該縱向纖維自網槽頂部至底部並行排列所形成,且另兩相 對該單纖區分別由複數條該橫向纖維自_頂部至底部並行排列 所形成;每-交織區介於兩相鄰單纖區之間,每一交織區由複數條 縱向纖維及複數條横向纖維交織而成。再者,交織區之每一縱向 纖維與至少三條橫向纖維交織接觸,且每一橫向纖維與至少三條 ® 縱向纖維交織接觸。 本創作之帛四目的,在倾—種提S結翻度且兼具增進水 土保持功效的陣列多角錐形立體網。達成此目的之技術手段係由 複數條縱向齡並行分佈呈波浪狀複數條橫峨軸行分佈呈 波浪狀,再由縱向纖維與橫向纖維編織成網體,使網體的正、反面 分另丨形成有複數個陣列分佈的多邊面錐形網槽,錐形網槽的最大 深度與兩相對單纖區的最大寬度的比值至少為〇· 5。 本創作之第五目的,在提供一種兼具結構強度佳、高泥土容 5 M42.7394 量、增加雨水疏通性及空氣與溫度等調控性能的陣列多角錐形立 體網。達成此目的之技術手段,係於網體之正面的一個多邊面錐形 網槽之兩相隣交赌與其反__隣多邊面錐形網槽之一交織 區為共有,且正面之兩蝴多邊面錐形浦之單纖區與其反面之 相對應的兩娜多邊面錐形峨之單麵圍成—腔室,腔室可阻 隔大部份的泥土落人其内,形成親財的通道,*且具有調控空 氣及溫度的功能。 本創作之®六目的,在提供-種提增粒子峨W效能的陣 列多角錐形立體網。達成此目的之技術+段係由縱向纖維及橫向 纖維所編_紅哺,麵触、反自細軸有概個陣列分 佈的多邊面錐形網槽,網槽内部跨接交織有複數條細纖維,細纖維 的線徑小於縱向纖維及横向纖維。 【實施方式】 I ·本創作達成第一、二目的的具體實施例 請參看圖1、3至5所示,達成本創作第一目的之一種具體實施 例,以提高結構強度,本創作之陣列多角錐形立體網,係由縱向纖 維10及橫向纖維20所編織而成之網體30結構,其網體30可供水或 空氣的過濾,或供舖置於泥土中(請配合參看圖1〇至12所示),以做 水土保持之用,留置有養份的泥土以利植物生長。縱向纖維10或橫 向纖維20可為單絲纖維,或由複絲捻合而成的纖維,本創作較佳實 施例+,其縱向纖維10及橫向纖維2〇的線徑為5〇〇〇丹〜looooo丹 (0· 5mm〜10mm)織成的網體為單纖織物(織物高度〇. 5mm〜1〇〇mm)。其 編織的模式,使得網體30的正、反面分別形成有複數個陣列分佈的 M427394 多邊面錐形網槽40,每一多邊面錐形網槽4〇内經自& 土 口呈逐漸擴大狀。多邊面錐形網槽40相互緊隣依靠且正 、開 多邊面錐形網槽40緊妓錯,形成結構強度佳的蜂_構== 有效提升結構強度。再者,為了達成本創作第二目的,以提升本創 作網體30的泥土容納,本創作-種具體實施例,係多邊面雜形網 槽40的最大深度與最大寬度的比值至少為〇.3。而且藉由織物結構 型成摺景過献果,可增加磁面積。制深層贼健損高過V. New description: . [New technical field] This creation is about an array of polygonal pyramidal meshes, especially a mesh structure used to filter impurities in water or air, or in the field. [Prior Art] According to the conventional water or air filter, there are a non-woven filter screen and a woven filter screen. Non-woven fabrics are made up of multi-layer stacks with high pressure difference, poor structural strength, easy damage, and non-recyclable recycling depending on the environment of different filter materials. As for the conventionally known woven filter screen, although it has the characteristics of low pressure difference, since it is a structure in which the fiber is simply woven, the structural strength is still poor, the force-receiving area is small, and the relative unit area is greatly stressed, and is easily damaged. I also have low particle blocking performance. Therefore, there is a need for improvement. Furthermore, since the soil is easily washed away by rain, in order to avoid this, there is a so-called phytosanitary network. That is to say, the vegetative net is mainly used for the maintenance of water and soil, such as slopes, grass planting and other related environmental conservation projects, in order to prevent the soil from being directly washed away by rain, so that the water penetrates and retains the soil nutrients. At present, many well-known phytosanitary networks have been researched or developed, such as Taiwan Patent Nos. 484629, 576452, M287042, M249977, M410754 and M406349. Among them, No. 29, No. 576452, No. M287042, etc., mainly consist of a sandwich type carpet structure, that is, a dense coconut fiber, non-woven fabric or cotton material is arranged between the upper and lower mesh layers. The fiber layer enables the mesh blanket to have sufficient thickness and cushioning effect to prevent the rainwater from scouring the soil, thereby producing soil and water conservation and greening and planting effects. However, the sandwiched mesh carpet itself does not have an effective space for accommodating the soil, and mainly uses its increased thickness to resist soil erosion, so that it is not conducive to the root of the plant in the case of a large thickness and a small gap of the hole M427394 • * Dependent and growing, and the upper and lower soils are spaced apart at large intervals, there will be significant faults. In the aforementioned Patent No. M249977, the laminated grids are integrally fused by heat, and one of the grids is formed into a wavy three-dimensional structure which is undulated or arranged. In order to maintain the three-dimensional wavy structure, it is made of a harder material, such as a plastic material, so that it is less elastic and causes inconvenience in carrying and transporting. The M41_ patent is a three-dimensional grid type vegetable net comprising an upper layer fabric, a lower layer fabric, and a three-dimensional lattice grid between the upper and lower layers of fabric. The upper and lower fabrics have a plurality of mesh units which are woven into a three-dimensional grid structure by two or more longitudinal loops and transverse loops. However, the former case technology is a grille structure, which can only be used as a surrounding frame, and can not be used to maintain the soil and water in the upper and lower layers. The soil at the bottom will still be lost from the bottom, and the effect is not good. No. M4〇6349 is a three-dimensional ring-shaped vegetative mesh carpet structure, which is processed by wire processing and weaving the three-dimensional structure of the upper and lower layers and the double-ring buckle. However, the technical structure of the former case is loose, the structural strength is not good, and the soil and water conservation The effect is not good. In combination with the above-mentioned various conventional techniques, there are a few missing points which are described later: the structure is loose, the strength is not good, and it is easy to be damaged; moreover, it is impossible to combine the effects of the mud, the good drainage, and the air circulation. In view of the above-mentioned lack of water, air filter and phytosanitary network, the creator is actively researching and continually experimenting and implementing, and finally produces the results of this creation. [New content] The first purpose of this creation is to provide a structural strength, which is not easily deformed or damaged, easy to be retracted and shipped, suitable for water and air filtration, and used in various slope-shaped soils for laying in soil. An array of polygonal pyramidal meshes used for geotechnical engineering of soil and water conservation. The technical means for achieving this purpose is a mesh body of 4 M427394 woven by longitudinal fibers and transverse fibers. The front and back sides of the net body are respectively formed with a plurality of polygonal pyramidal mesh grooves distributed in an array, each of which is a polygonal surface. The inner diameter of the tapered mesh groove gradually enlarges from the bottom to the opening thereof. The second object of the present invention is to provide an array of polygonal pyramidal solids for improving the soil and water conservation effect, and the ratio of the maximum depth to the maximum width of the transition is at least 〇. The third object of the present invention is to provide an array #polygonal pyramidal three-dimensional network which can greatly improve the structural strength. The technical means for achieving the object is that the polygonal tapered groove is an eight-sided tapered mesh groove, and the ring wall of each of the tapered mesh grooves comprises four single fiber regions and four interwoven regions arranged in a staggered manner. The four single fiber regions are opposite to each other, and the two single fiber regions are respectively formed by a plurality of the longitudinal fibers arranged in parallel from the top to the bottom of the mesh groove, and the other two of the single fiber regions are respectively composed of a plurality of the transverse fibers from the _ The top to the bottom are formed in parallel; each interlaced region is interposed between two adjacent single fiber regions, and each interlaced region is interwoven by a plurality of longitudinal fibers and a plurality of transverse fibers. Further, each of the longitudinal fibers of the interwoven region is interwoven with at least three transverse fibers, and each of the transverse fibers is interwoven with at least three of the longitudinal fibers. The four purposes of this creation are to provide an array of polygonal pyramidal nets that enhance the soil and water conservation efficiency. The technical means for achieving this purpose is that the plurality of longitudinal lengths are distributed in parallel and the wavy shape is distributed in a wavy shape, and the longitudinal fibers and the transverse fibers are woven into a mesh body, so that the front and back sides of the net body are separated. A plurality of polygonal pyramidal mesh grooves are formed, and the ratio of the maximum depth of the tapered mesh grooves to the maximum width of the two opposing single fiber regions is at least 〇·5. The fifth objective of the present invention is to provide an array of polygonal pyramidal nets having both structural strength, high clay content of 5 M42.7394, increased rainwater dredging, and air and temperature regulation. The technical means for achieving this goal is that the two adjacent gambling gamuts of a polygonal faceted mesh groove on the front side of the net body are shared with one of the opposite __ adjacent polygonal faceted mesh grooves, and the two faces of the front face are shared. The single-fibre area of the polygonal surface of the polygonal surface and the opposite side of the two-sided polygonal surface are surrounded by a single chamber, and the chamber can block most of the soil from falling into the body, forming a channel for pro-funding. , * and has the function of regulating air and temperature. The six purposes of this creation are to provide an array of polygonal pyramidal nets that enhance the effectiveness of particle 峨W. The technology + segment for achieving this purpose is composed of longitudinal fibers and transverse fibers. The red-faced mesh groove has a series of arrays distributed on the surface and the anti-spinning axis. The inner groove of the mesh groove is interwoven with a plurality of thin lines. The fiber and fine fiber have a smaller wire diameter than the longitudinal fiber and the transverse fiber. [Embodiment] I. The specific embodiment of the present invention achieves the first and second purposes. Referring to Figures 1, 3 to 5, a specific embodiment of the first object of the present invention is achieved to improve the structural strength. The polygonal conical three-dimensional net is a net body 30 structure woven from longitudinal fibers 10 and transverse fibers 20, and the net body 30 can be filtered by water or air, or placed in the soil (please refer to FIG. To 12), for soil and water conservation, retaining nutrients for plant growth. The longitudinal fiber 10 or the transverse fiber 20 may be a monofilament fiber or a fiber obtained by twisting a multifilament. In the preferred embodiment of the present invention, the longitudinal fiber 10 and the transverse fiber 2〇 have a wire diameter of 5 〇〇〇 ~looooo Dan (0·5mm~10mm) woven into a mesh fabric of single fiber fabric (fabric height 〇. 5mm~1〇〇mm). The weaving mode is such that the front and back sides of the net body 30 are respectively formed with a plurality of arrays of M427394 multi-faceted conical mesh grooves 40, and each of the polygonal conical mesh grooves 4 is gradually formed by the self- & Expanded. The polygonal conical mesh grooves 40 are adjacent to each other and the positive and open polygonal conical mesh grooves 40 are close to each other, forming a bee structure with good structural strength == effectively improving the structural strength. Furthermore, in order to achieve the second purpose of the present creation, in order to enhance the soil accommodation of the creation mesh body 30, the specific embodiment, the ratio of the maximum depth to the maximum width of the polygonal surface mesh groove 40 is at least 〇. 3. Moreover, the magnetic area can be increased by the fact that the fabric structure is made into a bokeh. Deep thief has higher damage
據效果。 Π ·本創作達成第三、四目的的具體實施例 請參看圖卜3至5所示,為了達成本創作第三、四目的在網 槽底部形成較密的面狀交織結構以提高結構強度及增進水土保持 功效,並增加速過濾承載能力,藉由織密大小不一形成本創作之陣 列多角錐形立體網。其一種具體實施例,係由縱向纖維10及橫向纖 維20所編織而成之網體3〇結構,編織的模式,係複數條縱向纖維1〇 並行分佈呈三角鋸齒形波浪狀(配合參看圖6所示)或梯形鋸齒形 波浪狀(配合參看圖7所示),複數條橫向纖維2〇並行分佈呈三角形 錄齒形波浪狀(配合參看圖6所示)或梯形鋸齒形波浪狀(配合參看 圖7所示),縱向纖維10與該橫向纖維20相互垂直,且二者波浪高度 相同,進而在交疊的區域相互交織,使二者波浪凹部圍成多邊面錐 形網槽40。本實施例中,多邊面錐形網槽4〇為八面錐形網槽41(配 合參看圖2所示之模型),不僅增加受力面積以減少壓力,以提升耐 用性,且可增進粒子累疊的速度與效率(配合參看圖9所示)。亦即, 每一個八面錐形網槽41的環壁包括有依序交錯環佈的四個單纖區 7 M427394 » * 42及四個交織區43,四個單纖區42兩兩相對兩相對單纖區犯分別 由複數條縱向纖維10自網槽41頂部至底部並行排列所形成,且另 兩相對單纖區42分別由複數條橫向纖維2〇自網槽41頂部至底部並 行排列所形成。每一交織區43介於兩相鄰單纖區42之間,每一交織 區43由複數條縱向纖維10及複數條橫向纖維2〇交織而成。其中,兩 相對的交織區43對稱於網槽41的中心軸線,兩相對的單織區仙對 稱於網槽41的中心軸線。再者,正面或反面的兩相鄰網槽4〇之間以 ^ 一條縱向纖維10或橫向纖維20相鄰接。 請配合參看圖3、4及附件-所示,本創作提高結構強度的一種 具體實施例,係交織區43之每一縱向纖維1〇與至少三條連續相鄰 的橫向纖維20以依序-上-下交錯的方式而交織接觸(亦即,圖示 例中,交織區43分佈有至少七排的交織點,每一排有三個呈直線排 列的交織點),且每一橫向纖維20與至少三條連續相鄰的縱向纖維 10以依序一上一下交錯的方式而交織接觸(亦即,圖示例中,交織 區43分佈有至少七排的交織點,每一排有三個呈直線排列的交織 籲點),而且交織區43的最大寬度與纖維線徑之比例小於4。基於此一 具體實施例,本創作另一種較佳實施例,八面錐形網槽41的最大深 度與兩相對單纖區42的最大寬度的比值至少為〇·3(最佳至少 0.5) 〇 請配合參看圖5及附件二所示,本創作提高結構強度的一種具 體實施例,係交織區43之每一縱向纖維1〇與至少五條連續相鄰的 橫向纖維依序-上-下交錯的对而交麟觸(亦即,圖示例 中,交織區43分佈有至少七排的交織點,每一排有五個呈直線排列 8 的交織點),且每_橫向_2G與至少五條連續相獅縱向纖維1〇 、,序上一下交錯的方式而交織接觸(亦即,圖示例中交織區 43刀佈有至少七排的交_,每—排有五個呈直線排列的交織 點)。 ΠΙ ·本創作達成第五目的的具體實施例 清參看圖卜3、4及8所示,為了達成本創作第五目的,以兼具 結構強度佳、两泥土容量、增加雨水疏通性及空氣與溫度等調控 性能,本創作之陣列多角錐形立體網的一種具體實施例,係由縱向 纖維10及橫向纖維2〇所編織而成之網體3〇結構,編織的模式,係複 數條縱向_1〇並行分饰呈三角蘇齒形波浪狀(配合參看圖6所示) 或梯形鑛齒形波浪狀(配合參看圖7所示),複數紐向纖維2〇並行 分佈呈二角鑛齒形波浪狀合參看削所示)或梯形織形波浪 狀(配合參看圖7所示),縱向纖維1()與該橫向纖維2()相互垂直且 二者波浪高度相同,進而在交叠的區域相互交織使三者波浪凹部 圍成多邊面錐形網槽40,本實施例巾纟赠30之it©的-個八面錐 形網槽41之兩相鱗交織區43與其反面的兩相隣八面錐形網槽心之 -交織區43為共有,且其正面之兩相p粦人面錐形網槽41之單纖區 42與其反面之相對應的兩相隣八面錐形網槽μ之單纖區42圍成一 腔室44。 IV ·本創作達成第六目的的具體實施例 請參看圖13所π,為了達成本創作第六目的以兼具結構強度 佳、增加雨水疏通性及提增粒子攔截累疊效能的陣列多角錐形立 體網,本創作之陣列多角錐形立體網的一種具體實施例係由縱向 M427394 纖雉10及橫向細G所编織而成之網職網體3()的正、反面分別 形成有複數個_分佈的多邊面錐形網槽41,_41内部跨接交 織有複數條細_45,細纖祕的線則、於縱向纖_及橫向纖 維20。形成毛羽現象,兼具不織布相同效果,使初始過滤效率提高。 以上所述,僅為本創作之一可行實施例,並非用以限定本創 作之專利細,凡舉依據下财請專利細所述之内容、特徵以 及其精神*為之其他變化的等效實施,皆應包含於補作之專利 fe圍内本創作之方法及其機構,除上述優點外,並深具產業之 利用f生了有效改善習用所產生之缺失,而且所具體界定於申'請 專利範圍之特徵,未見於同類物品,故而具實用性與進步性,已 符合創作專利要件,爰依法具文提出申請,謹請鈞局依法核予 專利,以維護本申請人合法之權益。 【圖式簡單說明】 圖1係本創作之整體外觀示意圖。 圖2係本創作之單一網槽呈八角錐形的模型示意圖。 圖3係本創作之網體第一實施例的局部立體示意圖。 圖4係本創作之網體第一實施例的局部俯視示意圖。 圖5係本創作之網體第二實施例的局部立體示意圖。 圖6係本創作之縱向纖維或橫向纖維並行排列呈三角鋸齒形波浪 狀的簡單示意圖。 圖7係本創作之縱向纖維或橫向纖維並行排列呈梯形鋸齒形波浪 狀的簡單示意圖。 圖8係本創作之局部斷面示意圖。 圖部斷面暨麟贼水或空氣的示意圖 圖11敍名局部斷面暨用於水土保持的示意圖。 般山坡地做水 圖12係本創作用於i山坡地做水土保二 圖13係本創作於網槽内加設有細纖維之示意圖。 附件一:係本創作之網體第一實施例的實體局部照片。 附件二:係摘作之峨第二實酬的實體 【主要元件符號說明】 。"、、乃。 橫向纖維20 多邊面錐形網槽40 單纖區42 腔室44 縱向纖維10 網體30 八面錐形網槽41 交織區43 細纖維45According to the effect. Π · For the specific examples of the third and fourth objectives of this creation, please refer to Figures 3 to 5. In order to achieve the third and fourth purposes of this creation, a dense planar interlaced structure is formed at the bottom of the trough to improve the structural strength and Improve the efficiency of soil and water conservation, and increase the speed of filtration capacity, and form a polygonal pyramidal mesh of the creation by the different sizes of weaving. A specific embodiment is a mesh body structure woven by longitudinal fibers 10 and transverse fibers 20, and the knitting pattern is a plurality of longitudinal fibers 1 〇 parallel distributed in a triangular zigzag wave shape (refer to FIG. 6 (shown) or trapezoidal zigzag wavy (as shown in Figure 7), a plurality of transverse fibers 2〇 are distributed in parallel with a triangular-shaped wavy shape (as shown in Figure 6) or a trapezoidal zigzag wave (see As shown in Fig. 7, the longitudinal fibers 10 and the transverse fibers 20 are perpendicular to each other, and the wave heights of the two are the same, and are interlaced in the overlapping regions so that the wave recesses of the two enclose the polygonal pyramidal mesh grooves 40. In this embodiment, the polygonal conical mesh groove 4 is an octagonal tapered mesh groove 41 (with the model shown in FIG. 2), which not only increases the force area to reduce the pressure, but also improves the durability and improves the particles. The speed and efficiency of the stack (see Figure 9 for cooperation). That is, the ring wall of each of the octahedral mesh grooves 41 includes four single fiber regions 7 M427394 » * 42 and four interwoven regions 43 in a staggered loop, and the four single fiber regions 42 are opposite to each other. The relatively single fiber zone is formed by a plurality of longitudinal fibers 10 arranged in parallel from the top to the bottom of the mesh groove 41, and the other two relatively single fiber regions 42 are respectively arranged in parallel from the top to the bottom of the plurality of transverse fibers 2 from the mesh groove 41. form. Each of the interlaced regions 43 is interposed between two adjacent single fiber regions 42 each of which is formed by interlacing a plurality of longitudinal fibers 10 and a plurality of transverse fibers 2〇. Wherein, the two opposite interlaced regions 43 are symmetric with respect to the central axis of the trough 41, and the two opposite single weaves are symmetrically referred to as the central axis of the trough 41. Furthermore, a longitudinal fiber 10 or a transverse fiber 20 is adjacent between two adjacent mesh grooves 4 。 on the front or the back. Referring to Figures 3, 4 and the accompanying drawings, a specific embodiment of the present invention for increasing the structural strength is in the order of each longitudinal fiber 1 of the interwoven region 43 and at least three consecutive adjacent transverse fibers 20. - interlaced contact in a lower interleaved manner (i.e., in the illustrated example, the interlaced region 43 is distributed with at least seven rows of interlaced dots, each row having three interlaced dots arranged in a straight line), and each transverse fiber 20 and at least The three consecutive adjacent longitudinal fibers 10 are interlaced in a sequential manner. (ie, in the illustrated example, the interlaced regions 43 are distributed with at least seven rows of interlacing points, and each row has three linear rows. Interlaced, and the ratio of the maximum width of the interwoven region 43 to the fiber diameter is less than four. Based on this embodiment, another preferred embodiment of the present invention, the ratio of the maximum depth of the octagonal tapered mesh groove 41 to the maximum width of the two opposing single fiber regions 42 is at least 〇·3 (optimally at least 0.5) 〇 Referring to FIG. 5 and FIG. 2 together, a specific embodiment of the present invention for improving the structural strength is that each longitudinal fiber 1〇 of the interwoven region 43 is sequentially and vertically-interlaced with at least five consecutive adjacent transverse fibers. In contrast, in the example of the figure, the interlaced area 43 is distributed with at least seven rows of interlaced points, each row has five interlaced points arranged in a straight line 8 and each _ lateral _2G and at least five The continuous phase lion longitudinal fiber is 1 〇, and the interlaced contact is interleaved (that is, in the illustrated example, the woven fabric of the interlaced area 43 has at least seven rows of intersections, and each row has five interlaced lines arranged in a straight line. point). ΠΙ · The specific example of the fifth goal of this creation is as shown in Figures 3, 4 and 8. In order to achieve the fifth purpose of this creation, it has both structural strength, two soil capacity, increased rainwater dredging and air and Temperature and other regulation performance, a specific embodiment of the array of polygonal pyramidal mesh of the present invention is a three-dimensional structure of a mesh body woven by a longitudinal fiber 10 and a transverse fiber 2〇, a weaving mode, a plurality of longitudinal images _ 1〇 Parallel sub-decoration is triangular Sagittal wavy (as shown in Figure 6) or trapezoidal ore-shaped wavy (see Figure 7 for matching), and the multiple pairs of fibers 2〇 are distributed in parallel. The wavy shape is shown in the wavy shape or the trapezoidal wavy shape (as shown in Fig. 7), the longitudinal fiber 1 () and the transverse fiber 2 () are perpendicular to each other and the wave heights of the two are the same, and thus in the overlapping area. Interlaced with each other to form a three-dimensional wave recessed portion into a polygonal conical mesh groove 40. In this embodiment, the two-phase scale interlaced area 43 of the eight-faceted tapered mesh groove 41 of the 30-it is the two adjacent sides of the opposite side. The octagonal tapered mesh heart-interlacing area 43 is common and has a front side P lin al biphasic surface of the tapered region 41 of the monofilament mesh groove 42 corresponding thereto opposite directions of two adjacent tapered groove μ mesh of monofilaments enclose a region 42 of the chamber 44. IV. For the specific embodiment of the sixth objective of the present invention, please refer to Figure π, in order to achieve the sixth objective of the present invention, an array of polygonal pyramids having both structural strength, increased rainwater dredging, and enhanced particle interception efficiency. Stereoscopic mesh, a specific embodiment of the array of polygonal pyramidal meshes of the present invention is formed by a plurality of front and back sides of a mesh net body 3 () which is woven by a longitudinal M427394 fiber 10 and a transverse thin G, respectively. The _ distributed polygonal pyramidal mesh grooves 41, _41 are internally interlaced with a plurality of thin _45, and the fine fiber secret lines are in the longitudinal fiber _ and the transverse fiber 20. The phenomenon of hairiness is formed, which has the same effect as non-woven fabric, and the initial filtration efficiency is improved. The above is only one of the possible embodiments of this creation, and is not intended to limit the patents of this creation. The equivalent implementation of the contents, characteristics and other changes of the spirit of the patents. The methods and institutions for the creation of the patents that are included in the patents of the supplements, in addition to the above advantages, and the use of the industry, have produced a lack of effective improvement in the use of the application, and are specifically defined in the application of the patent The characteristics of the scope are not found in the same kind of articles, so they are practical and progressive. They have already met the requirements for the creation of patents. They have applied for the law according to law. I would like to ask the bureau to approve the patents in accordance with the law to protect the legitimate rights and interests of the applicant. [Simple description of the diagram] Figure 1 is a schematic diagram of the overall appearance of the creation. Fig. 2 is a schematic diagram of a model in which a single mesh groove of the present invention has an octagonal cone shape. 3 is a partial perspective view of the first embodiment of the mesh body of the present invention. 4 is a partial top plan view of the first embodiment of the mesh body of the present invention. FIG. 5 is a partial perspective view of a second embodiment of the mesh body of the present invention. Fig. 6 is a simplified schematic view of the longitudinal or transverse fibers of the present invention arranged in parallel in a triangular zigzag wave shape. Fig. 7 is a simplified schematic view showing the longitudinal fibers or the transverse fibers of the present invention arranged in parallel in a trapezoidal zigzag shape. Figure 8 is a partial cross-sectional view of the creation. Schematic diagram of the section of the picture and the water or air of the thief. Figure 11 shows the section of the section and the schematic diagram for soil and water conservation. Figure 1 is the creation of this hill for the soil and soil conservation. Figure 13 is a schematic diagram of the creation of fine fibers in the mesh. Annex I: A partial photo of the entity of the first embodiment of the web of the present invention. Annex II: Entity of the second actual remuneration [Explanation of main component symbols]. ",, is. Transverse fiber 20 Multi-faceted tapered mesh groove 40 Single fiber zone 42 Chamber 44 Longitudinal fiber 10 Net body 30 Octagonal tapered mesh groove 41 Interwoven zone 43 Fine fiber 45