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JP3784263B2 - Anchor plate for anchor method - Google Patents
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JP3784263B2 - Anchor plate for anchor method - Google Patents

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Publication number
JP3784263B2
JP3784263B2 JP2001021436A JP2001021436A JP3784263B2 JP 3784263 B2 JP3784263 B2 JP 3784263B2 JP 2001021436 A JP2001021436 A JP 2001021436A JP 2001021436 A JP2001021436 A JP 2001021436A JP 3784263 B2 JP3784263 B2 JP 3784263B2
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Japan
Prior art keywords
anchor
slope
support beam
plate portion
pressure receiving
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JP2002227211A (en
Inventor
幸一 久保
謙治 木挽
明 中野
修 栄藤
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Kubota Corp
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Kubota Corp
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Description

【0001】
【発明の属する技術分野】
本発明は、地山の地中に係止したアンカー部材を用い法面に圧接して、地滑りや法面崩壊を防止するように構成されているアンカー工法用受圧板に関し、より詳しくは、法面に接地自在に構成され且つ接地面に沿って四方に突出して十字形に形成された支持梁と、アンカー部材挿通用として前記支持梁に形成されたアンカー挿通部と、アンカー部材を係止するために前記アンカー挿通部に形成されたアンカー係止部と、前記支持梁の隣合う突出部間に連接され且つ前記法面に接地自在に構成される鍔状板部とを備え、地中に係止したアンカー部材を用いて前記法面を圧接可能に構成されているアンカー工法用受圧板に関するものである。
【0002】
【従来の技術】
従来、この種のアンカー工法用受圧板(以下、単に受圧板と略称する)としては、図6に示す如く、法面Fに接地自在に構成され且つ接地面3aに沿って四方に突出して十字形に形成された支持梁1には、その隣合う突出部7間に、その突出部7の先端の角を直線的に結ぶように鍔状板部2を連接して、全体として菱形形状をした、いわゆるセミスクエアタイプのものが用いられている。
かかるセミスクエアタイプの受圧板は、図6に示す如く、地山Bの地中に係止したアンカー部材8を用い法面Fに圧接して、地滑りや法面崩壊を防止するように構成されているのであるが、支持梁1及び鍔状板部2は夫々、次のような機能を有している。
つまり、前記支持梁1は、アンカー部材8挿通用としてのアンカー挿通部5と、アンカー部材8を係止するためのアンカー挿通部5に形成されたアンカー係止部6とを設けてあり、地中に係止したアンカー部材8に対して所定の緊張力で緊張固定することで、▲1▼その接地面3aにより法面Fを圧接する機能、及び、▲2▼アンカー緊張力により発生する地盤反力によって受圧板が変形や破壊等することのないよう支持補強する機能を、備えている。
一方、前記鍔状板部2は、支持梁1の突出部7間に連接され且つ法面に設置自在に設けてあることから、支持梁1の接地面3aが同一平面状に拡大され、支持梁1と共に法面Fを圧接すると共に、前記地盤反力を受ける受圧面積を増加させる機能を備えている。
このように、セミスクエアタイプの受圧板によれば、支持梁1及び鍔状板部2の夫々の特有の機能があいまって、例えば、より大きな面積で地山を圧接したり、地盤耐力(法面の土耐力)が小さいときでも受圧板の法面内への食い込みを防止したりすることができるなど、各種利点を備えている。
【0003】
【発明が解決しようとする課題】
ところが、上述のように構成されるセミスクエアタイプの受圧板の場合、法面に対して並設配置することで、法面の略全体が受圧板で覆われることとなり、法面に受圧板を設置した後には、あまり地山の露出した部分はなく、地山の傾斜面の美観が損なわれてしまうという不具合がある。
【0004】
つまり、例えば、受圧板の大きさはそのままで、地山に係止される複数のアンカー部材の間隔(アンカーピッチ)、すなわち地山に並設配置される受圧板の間隔を拡大させれば、それら複数の受圧板間に地山が露出した部分を増加させることは可能である。しかし、この場合には、増加された地山の露出部分に植栽するなどして斜面の景観の向上を図ることができるものの、受圧板の接地面の面積はそのままであり、受圧板の地滑りや法面崩壊を防止する能力はそのままであるため、増加された地山の露出部分が地滑りや法面崩壊を起こしてしまう虞もあり、受圧板の元来の地滑りや法面崩壊を防止するという目的が損なわれてしまうという問題がある。
一方、従来の受圧板の菱形形状を相似形のまま拡大させることにより、その地滑りや法面崩壊を防止する能力を向上させれば、アンカーピッチを拡大しても地滑りや法面崩壊を防止しすることはできるものの、この場合には、地山における露出部分を増加させることができず、地山の傾斜面の景観は損なわれてしまうという問題がある。
【0005】
本発明は、上記実情に鑑みてなされたものであって、その目的は、地山の地滑りや法面崩壊を防止しながらも、アンカーピッチを拡大して、地山の美観を向上させることができる受圧板を提供するところにある。
【0006】
【課題を解決するための手段】
請求項1記載の発明の特徴構成は、図1,2,4に例示するごとく、法面Fに接地自在に構成され且つ接地面3aに沿って四方に突出して十字形に形成された支持梁1と、アンカー部材8挿通用として前記支持梁1に形成されたアンカー挿通部5と、アンカー部材8を係止するために前記アンカー挿通部5に形成されたアンカー係止部6と、前記支持梁1の隣合う突出部7間に連接され且つ前記法面Fに接地自在に構成される鍔状板部2とを備え、地中に係止したアンカー部材8を用いて前記法面Fを圧接可能に構成されているアンカー工法用受圧板であって、
前記支持梁1は、上方に開口を備える凹みのある形状を持ち、且つ、その突出部7の先端が、前記鍔状板部2との連接箇所よりも接地面3aに沿った外方に向けて突設するようにしてあるところにある。
【0007】
〔作用効果〕
本発明に係るアンカー工法用受圧板(以下、単に受圧板と略称)は、支持梁及び支持梁に連接される鍔状板部を備えており、従来のセミスクエアタイプの構造の受圧板の支持梁及び鍔状板部の夫々の機能からの利点を引き継いだものである。
【0008】
しかも、かかる支持梁は、上方に開口を備える凹みのある形状を持ち、その突出部の先端が、鍔状板部との連接箇所よりも接地面に沿った外方に向けて突設させて構成してあるため、接地面の面積が拡大され、その接地面により法面を圧接する機能も向上させることとなる。
よって、仮に、地山の露出部分が増加するように、従来よりもアンカーピッチを拡大させて地山に並設配置しても、鍔状板部との連接箇所よりも突設された支持梁突出部の機能向上により、地滑りや法面崩壊が防止される。
一方、上記構成によれば、法面に設置した後、鍔状板部の端部側と、その鍔状板部との連接箇所よりも突設させた部分の突出部の周縁と、支持梁の先端(つまり突出部先端)の角を結ぶ直線とで囲まれる部分に、地山が露出されることとなり、地山の露出部分を増加させることが可能となる。
【0009】
従って、地山の地滑りや法面崩壊を防止しながらも、アンカーピッチを拡大して、地山の露出部分を増加し、地山の露出部分に植栽するなどして、斜面の景観の向上を図ることができるようになる。
尚、地山の露出する部分を植栽し緑化を図ることで、景観を向上できるばかりか、その植栽された草木の根が地山に伸長することで、地山の地滑りや法面崩壊が防止されるようにもなる。
【0010】
因みに、本構成の如く、突出部を、鍔状板部との連接箇所よりも突設させることで、支持梁自体は延設されるため、支持梁の受圧板を支持補強するという機能も勿論向上され、従来のセミスクエアタイプの受圧板に比べて、確実に受圧板の変形や破壊等がない強度を有する機能を備えている受圧板を提供できるようにもなった。
請求項2記載の発明の特徴構成は、図1,2,4に例示するごとく、法面Fに接地自在に構成され且つ接地面3aに沿って四方に突出して十字形に形成された支持梁1と、アンカー部材8挿通用として前記支持梁1に形成されたアンカー挿通部5と、アンカー部材8を係止するために前記アンカー挿通部5に形成されたアンカー係止部6と、前記支持梁1の隣合う突出部7間に連接され且つ前記法面Fに接地自在に構成される鍔状板部2とを備え、地中に係止したアンカー部材8を用いて前記法面Fを圧接可能に構成されているアンカー工法用受圧板であって、
前記支持梁1を構成するに、その突出部7の先端が、前記鍔状板部2との連接箇所よりも接地面3aに沿った外方に向けて突設し、且つ、前記鍔状板部2は、その厚みが前記連接箇所から先端に向けて薄くなる形状にしてあるところにある。
〔作用効果〕
支持梁を構成するに、その突出部の先端が、鍔状板部との連接箇所よりも接地面に沿った外方に向けて突設させて構成してあるため、上述した請求項1記載の発明と同様、地山の地滑りや法面崩壊を防止しながらも、アンカーピッチを拡大して、地山の露出部分を増加し、地山の露出部分に植栽するなどして、斜面の景観の向上を図ることができるようになる。
更に、鍔状板部は、その厚みが前記連接箇所から先端に向けて薄くなる形状にしてあるので、法面からの地盤反力による曲げモーメントが突出部の端部側ほど小さくなることに鑑み、負担すべき応力の大きさに対応することになり、必要最小限の部材によって構成することができ、受圧板の軽量化を図ることができる。
【0011】
請求項3記載の発明の特徴構成は、図1,2,4に例示するごとく、法面Fに接地自在に構成され且つ接地面3aに沿って四方に突出して十字形に形成された支持梁1と、アンカー部材8挿通用として前記支持梁1に形成されたアンカー挿通部5と、アンカー部材8を係止するために前記アンカー挿通部5に形成されたアンカー係止部6と、前記支持梁1の隣合う突出部7間に連接され且つ前記法面Fに接地自在に構成される鍔状板部2とを備え、地中に係止したアンカー部材8を用いて前記法面Fを圧接可能に構成されているアンカー工法用受圧板であって、
前記支持梁1は、接地底板部3とこの接地底板部3に立設された竪補強板部7A,7B,7Cを備えて上方に開口を備える凹みのある形状を持ち、且つ、その突出部7の先端が、前記鍔状板部2との連接箇所よりも接地面3aに沿った外方に向けて突設すると共に、前記接地底板部3と鍔状板部2にそれぞれ貫通孔21,22,23を設けてあるところにある。
【0012】
〔作用効果〕
支持梁は、接地底板部とこの接地底板部に立設された竪補強板部を備えているので、接地底板部が受ける法面からの地盤反力による曲げモーメントに対抗でき、更に、その支持梁は、上方に開口を備える凹みのある形状を持ち、その突出部の先端が、鍔状板部との連接箇所よりも接地面に沿った外方に向けて突設させて構成してあるため、上述した請求項1及び2記載の発明と同様、地山の地滑りや法面崩壊を防止しながらも、アンカーピッチを拡大して、地山の露出部分を増加し、地山の露出部分に植栽するなどして、斜面の景観の向上を図ることができるようになる。
そして、接地底板部と鍔状板部にそれぞれ貫通孔を設けてあるので、接地底板部と鍔状板部の表面から接地面にかけて、水分が連通自在となるため、接地底板部と鍔状板部の上に植栽用の土を盛り込んで草木を植栽し、地山の緑化を一層促進させることが可能となるのである。
つまり、接地底板部と鍔状板部の上に植栽用の土を盛り込んで草木を植栽する際、かかる植栽用の土に過剰の水分が供給されたときには貫通孔を介して水分が地山側に排出される一方、水分が不足するときには地山から貫通孔を介して水分を補給されることも期待され、その植栽用の土の適度な水分状態が維持されることとなる。よって接地底板部と鍔状板部の上に植栽された草木は、天候等に左右されて枯れたりするということがなくなり、十分に成長するまで植栽されるようになる。
従って、地山の緑化を一層促進させて、法面に受圧板を設置した後における地山の傾斜面の美観をより向上させることが可能となる。
【0013】
さらに、その接地底板部と鍔状板部の上に植栽され成長した草木の根が、かかる貫通孔を介して地山中にまで達して、かかる草木が、地山中にはった根から地山中の水分及び養分を補給することもできるようになるとともに、貫通孔を介して過剰の水分を地山に排水することができるようになることも期待できる。また、そのように草木が貫通孔を介して地山中にまで根を植生することで、一層地すべりや法面崩壊などが起り難くなることをも期待することができるのである。
【0014】
尚、上述のように、図面との対照を便利にするために符号を記したが、該記入により本発明は添付図面の構成に限定されるものではない。
【0015】
【発明の実施の形態】
以下に本発明の実施の形態を図面に基づいて説明する。尚、図面において従来例と同一の符号で表示した部分は、同一又は相当の部分を示している。
【0016】
本発明に係るアンカー工法用受圧板(以下、単に受圧板と略称する)は、図1〜3に示す如く、金属材料の一種である例えばダクタイル鋳鉄で形成して、法面Fに接地自在に構成され且つ接地面3aに沿って四方に突出して十字形に形成された支持梁1と、アンカー部材8挿通用として前記支持梁1に形成されたアンカー挿通部5と、アンカー部材8を係止するために前記アンカー挿通部5に形成されたアンカー係止部6と、前記支持梁1の隣合う突出部7間に連接され且つ前記法面Fに接地自在に構成される鍔状板部2とを、一体に鋳造して製造する。
【0017】
以下、前記受圧板の構造について、図1〜3を参照しながら、詳細に説明する。
【0018】
前記受圧板は、図1に示す如く、法面Fに接地自在となるように支持梁1と鍔状板部2とを一体に設けて、その接地面3aが単一の平面からなるように形成してあるとともに、全体形状は、略菱形の4つの頂部が外方に向けて突出する形状に構成してある。
【0019】
前記支持梁1は、当該実施形態では、図1,2に示す如く、その略中央に前記係止部6を設けると共に、その係止部6を中心として、接地面3aに沿った外方に向けて四方に突出する突出部7を設けて、十字形に形成してある。
【0020】
前記係止部6は、前記十字形の支持梁1の法面Fに接地自在となる接地底板部3の略中央の位置に設けられるアンカー部材8挿通用としてのアンカー挿通部5に、アンカー部材8を係止するように構成してある。
そして、前記接地底板部3には、この係止部6を囲繞するように、四方の囲み竪補強板部10が立設されるとともに、その囲み竪補強板部10と係止部6に接続される十字状の補強リブ11が、設けてある。
【0021】
前記突出部7は、前記囲み竪補強板部10から十字形に四方に突出するものであり、当該実施形態では、接地底板部3の周縁部に沿って周縁竪補強板部7Aを一体に立設して、構成してある。
因みに、前記突出部7を構成する接地底板部3及び周縁竪補強板部7Aは、平面視及び側面視の何れの方向視においても端部側ほど幅狭となるよう先細のテーパー状に構成してある。これは、法面Fからの地盤反力による曲げモーメントが突出部7の端部側ほど小さくなることに鑑み、負担すべき応力の大きさに対応させたものである。また、本構成であれば、必要最小限の部材によって構成することができ、受圧板の軽量化を図ることができる。尚、同様の理由から、前記周縁竪補強板部7Aについては、その板厚も、端部側ほど薄く構成してもよく、一層、受圧板の軽量化を図ることも可能である。
【0022】
また、当該実施形態では、図1,2に示す如く、前記突出部7の強度を高める等の目的で、突出部7には、接地底板部3に縦貫竪補強板部7B及び横方向竪補強板部7Cを一体に立設してある。
前記縦貫竪補強板部7Bは、突出部7の長手方向に沿って接地底板部3の略幅中央に設けたものであり、主に、前記接地底板部3の曲げ耐力を向上させる機能を有する。
前記横方向竪補強板部7Cは、突出部7の長手方向に対して略垂直2等分に横断する方向に沿って設けたものであり、突出部7のねじり剛性を高める等の機能を有する。
【0023】
そして、前記突出部7は、図1,2に示す如く、その外方に向けて突出する先端側が、鍔状板部2との連接箇所よりも、突出するように設けてある。
この突出部7の先端の鍔状板部2との連接箇所からの突出具合は、適宜必要に応じて設定すれば良いが、図2に示す如く、L1=La/10〜La/2 (尚、La:囲み竪補強板部10から突出部7の先端までの長手方向の寸法、L1:囲み竪補強板部10から突出部7の鍔状板部2との連接箇所までの長手方向の寸法) となるように設ければ、より適切に地山の露出部分を増加させながらも地山の地滑りや法面崩壊を防止でき、また、また、受圧板の軽量化を図ることが可能にもなり、好ましい。
尚、当該実施形態の如く、かかる突出具合をL1=La/2となるようにすると共に、鍔状板部2が横方向竪補強板部7Cと一連に連接するように構成してあれば、鍔状板部2が支持梁1(殊に横方向竪補強板部7C)により確実に支持補強され、受圧板の全体としての強度及び耐久性等が向上され、より好ましい。
【0024】
前記鍔状板部2は、支持梁1の隣合う突出部7間を結び、前記支持梁1の接地底板部3の接地面3aを同一平面状に拡大するように連接してあり、当該実施形態では、先述のように、図1,2に示す如く、囲み竪補強板部10から横方向竪補強板部7Cまでの間にかけて、隣接する突出部7の周縁竪補強板部7Aを一体に結ぶように、三角形状に設けてある。
【0025】
前記鍔状板部2の厚みは均一の厚さにて構成してあっても良いが、当該実施形態では、一例として図3に示す如く、鍔状板部2は、周縁竪補強板部7Aとの連接箇所からその先端に向けて、その厚みが薄くなる形状に形成して(図3では一例としてR形状のものを例示)、構成してある。これは、法面Fからの地盤反力による曲げモーメントが鍔状板部2の先端側ほど小さくなることに鑑み、負担すべき応力の大きさに対応させたものである。
一方、図6に示すごとく従来のセミスクエアタイプの受圧板の場合、鍔状板部2は板厚が薄いため剛性が小さく変形し易いので、特に、鍔状板部2の端部では設計どおりの地盤反力を受け持っていない、つまり、法面Fを圧接していない懸念がある。この対策としては、板厚を厚くして剛性を大きくすることが考えられるが、その場合受圧板の重量が重くなり、施工面で望ましくないという問題があった。
これに対して本構成であれば、必要以上の強度を有することなく前記曲げモーメントに対抗可能な鍔状板部2の強度を確保できるから、アンカー部材8に対して所定の緊張力で受圧板を緊張固定したとしても地盤反力による鍔状板部2の変形を防止することができ、鍔状板部2の端部にまで確実に前記緊張力を伝達することができると共に、鍔状板部2の肉厚を薄くすることで軽量化を図ることもできる。また、このような形状をした鍔状板部2の形成は、金属製のものなら鋳型を使用した鋳造技術で簡単に形成することができると共に、樹脂製のものなら金型を使用した射出成形で簡単に形成することができる。この結果、受圧板の重量を軽減できる分その材料コストを低減することもできる。
【0026】
上述のように構成される受圧板を法面Fに設置する工程は、例えば以下のようになる。
[1] 受圧板を、施工現場に輸送する工程を実施する。
[2] 地山に掘削したアンカー穴にアンカー部材8を挿入して、アンカー穴にグラウト材を注入し、アンカー部材8を地中に固定しておく。
[3] 受圧板を揚重機械で吊り上げ、吊り上げた受圧板のアンカー挿通部5にアンカー部材8の地上露出部を貫通させた状態で、受圧板を法面F上に設置する工程を実施する。
[4] アンカー部材8の地上露出部に締結部として螺設した雄ねじ部にアンカー緊張固定部材としてのナット9を螺合締結し、受け座4を介してアンカー部材8を緊張する工程を実施する。
以上の四工程を順次実施することで、法面保護の施工を完了する。
【0027】
すると、図4(イ)に示す如く、法面Fに複数の受圧板を並設配置しても、セミスクエアタイプの受圧板の利点を引き継ぎながらも、地山の露出部分を増加でき、地山の略全体が受圧板で覆われるようなことは解消される。この為、図4 (ロ)に示す如く、かかる地山の露出部分に草木を植栽するなどして、地山の緑化を図り、景観を向上させることが可能となる。しかも、その植栽した草木が十分に成長し、地山中にまで根を植生することで、地すべりや法面崩壊などが起り難くなることを期待することもできる。
【0028】
因みに、図1,2に示す如く、鍔状板部2にその表面から接地面3aにかけて貫通する貫通孔としての底孔21を設けておけば、鍔状板部2の上にも植栽用の土を盛り込んで、その植栽用の土を適度な水分状態に保ち、草木を十分に成長させて植栽することができ、一層、地山の緑化を図ることが可能となる(図4(ロ)参照)。しかも、その植栽した草木が十分に成長し、かかる底孔21を介して地山中にまで根を植生することで、一層地すべりや法面崩壊などが起り難くなることを期待することもできる。
尚、先述の如く、鍔状板部2は、周縁竪補強板部7Aとの連接箇所からその先端に向けてその厚みが薄くなる形状に形成しておけば、鍔状板部2の表面においては、かかる厚みが薄くなる形状の勾配に沿って水分が排出され溜まり難くなる。
【0029】
〔別実施形態〕
以下に他の実施形態を説明する。
〈1〉支持梁1は、例えば、プレキャストコンクリート等により凹みのない箱枠体状に形成してあっても良いが、例えば、先の実施形態で説明したように接地底板部3と周縁竪補強板部7A等から構成して、上方に開口を備える凹みのある形状にしてあれば、かかる凹み空間を植栽空間Sとして利用し、土を盛り込んで草木を植栽することで、より一層、地山の緑化を促進させて、図4(ロ)に示す如く、地山の略全体を緑化させることも可能となる。尚、図4(ロ)では、囲み竪補強板部で囲まれる空間も緑化させてある。
因みに、先の実施形態の如く支持梁1を構成しておけば、植栽空間Sが所定の大きさに区画されているので、図5に示す如く、植栽用の土と草木の種子等を含有させた土嚢Dを植栽区間S内に埋め込み固定することで、簡便に草木を植栽することが可能となり、より好ましい。尚、このように土嚢Dを固定する場合、植栽用の土や草木の種子等を袋状のカバー体で覆えば、降水や風等により植栽空間から植栽用の土や草木の種子等が流失し難くなり、より確実かつ効率良く、草木を植栽空間に植栽させ、緑化を図り、地山の景観を向上させることができるようになる。尚、かかるカバー体は、勿論網目状のものであり、草木の成長を阻害することがないのはいうまでもない。
【0030】
また、支持梁1に植栽空間Sを設ける場合、植栽空間S側と地山側との間にて給排水自在となる貫通孔を設けておけば、一層好ましい。その一構成例を説明すると、図1,2に示す如く、接地底板部3、及び、前記接地底板部3・周縁竪補強板部7A・縦貫竪補強板部7B・横方向竪補強板部7Cで形成される隅部に、夫々、第一貫通孔22、第二貫通孔23を設けておけば、次のような作用効果を期待することができるのである。
つまり、受圧板は傾斜面に設置するものであるから、接地底板部3も傾斜しており、殊に前記隅部には雨水等による水分が溜まり易いのであるが、上記構成によれば、前記第一貫通孔22や第二貫通孔23を介して、接地底板部3に溜まろうとする水分を確実に地山に排出することができる。このため、植栽空間Sに土を盛り込んで草木を植栽した場合でも、当該盛り込んだ土中の水分が過剰になることなく適当に維持されて、これら植栽を適切な条件で育成させることができ、また、受圧板そのものが水分により腐食される虞も低減することができる。
しかも、その植栽した草木が十分に成長し、第一貫通孔22や第二貫通孔23を介して地山中にまで根を植生することで、地山中にはった根から地山中の水分及び養分を補給してより地山の緑化が促進されたり、また、一層地すべりや法面崩壊などが起り難くなることを期待することもできる。尚、第一貫通孔22や第二貫通孔23を設けることで、受圧板を軽量化するという効果も得ることができる。
【0031】
〈2〉先の実施形態では、支持梁1の4つの突出部7すべてにおいて、その先端側が、鍔状板部2との連接箇所よりも突出する構成例について説明したが、先端を鍔状板部2との連接箇所よりも突出させる突出部7の数は適宜選択すれば良く、例えば、一方向のみの2つの突出部7のみについてかかる構成にすれば、半端な面Kにおける地すべりや法面崩壊を防止することができ、利便である(図4参照)。
【0032】
〈3〉また、先の実施形態では、複数の受圧板を前後左右に同列の直線状になるように並設配置したが、その配列は適宜必要に応じて設定すれば良く、例えば、千鳥状に並設配置しても良い。
【0033】
〈4〉先の実施形態では、鍔状板部2の形状は三角形状のものを例示したが、適宜種々の形状に形成すれば良く、例えば、扇状になるように形成すれば、全方向に対してより均等に地山を圧接することができ、合理的である
【0034】
〈5〉本発明に係る受圧板は、所定の強度及び耐久性等を有するものであればよく、例えば、ポリカーボネート、ナイロン、FRP、BMC等の高強度の樹脂材料(繊維強化樹脂も含む)から構成しても良く、通常の鋼材を溶接組立して構成しても良い。
【図面の簡単な説明】
【図1】本発明に係るアンカー工法用受圧板の一構成例を示す斜視図
【図2】本発明に係るアンカー工法用受圧板の一構成例を示す平面図
【図3】本発明に係るアンカー工法用受圧板の要部拡大断面図
【図4】本発明に係るアンカー工法用受圧板の施工状態を示す説明図
【図5】本発明に係るアンカー工法用受圧板自体への植栽の一施工例
【図6】従来のアンカー工法用受圧板の構成を示す説明図
【符号の説明】
B 地山
F 法面
1 支持梁
2 鍔状板部
接地底板部
3a 接地面
5 アンカー挿通部
6 係止部
7 突出部
7A,7B,7C 竪補強板部
8 アンカー部材
21,22,23 貫通孔
[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to a pressure receiving plate for an anchor method that is configured to prevent landslide and slope failure by pressing against a slope using an anchor member that is locked in the ground of a natural ground. A support beam configured to be groundable on the surface and projecting in four directions along the ground surface, and an anchor insertion portion formed on the support beam for anchor member insertion, and the anchor member are locked. For this purpose, an anchor locking portion formed in the anchor insertion portion and a hook-like plate portion connected between adjacent projecting portions of the support beam and configured to be groundable on the slope are provided in the ground. The present invention relates to a pressure receiving plate for an anchor method that is configured to be able to press-contact the slope using a locked anchor member.
[0002]
[Prior art]
Conventionally, a pressure receiving plate for this type of anchor method (hereinafter simply referred to as a pressure receiving plate) is configured to be grounded on a slope F as shown in FIG. 6 and protrudes in all directions along the ground surface 3a. The support beam 1 formed in a letter shape has a rhombus shape as a whole by connecting the flange-shaped plate portion 2 between the adjacent protruding portions 7 so as to linearly connect the corners of the tips of the protruding portions 7. The so-called semi-square type is used.
As shown in FIG. 6, the semi-square type pressure receiving plate is configured to press against the slope F using an anchor member 8 locked in the ground of the natural ground B and prevent landslide and slope collapse. However, the support beam 1 and the bowl-shaped plate portion 2 have the following functions, respectively.
That is, the support beam 1 is provided with an anchor insertion part 5 for inserting the anchor member 8 and an anchor locking part 6 formed on the anchor insertion part 5 for locking the anchor member 8. By fixing the anchor member 8 locked inside with a predetermined tension force, (1) the function of pressing the slope F with the ground contact surface 3a, and (2) the ground generated by the anchor tension force It has a function of supporting and reinforcing so that the pressure receiving plate is not deformed or broken by the reaction force.
On the other hand, the saddle-like plate portion 2 is connected between the projecting portions 7 of the support beam 1 and can be installed on the slope, so that the grounding surface 3a of the support beam 1 is expanded in the same plane and supported. A function is provided to press the slope F together with the beam 1 and to increase the pressure receiving area that receives the ground reaction force.
As described above, according to the semi-square type pressure receiving plate, the specific functions of the support beam 1 and the bowl-shaped plate portion 2 are combined, for example, pressing a natural ground in a larger area, It has various advantages such as being able to prevent the pressure receiving plate from biting into the slope even when the soil resistance of the surface is small.
[0003]
[Problems to be solved by the invention]
However, in the case of the semi-square type pressure receiving plate configured as described above, by arranging it side by side with respect to the slope, almost the entire slope is covered with the pressure receiving plate, and the pressure receiving plate is attached to the slope. after installation, there is a problem that much rather exposed portion of the natural ground, is impaired aesthetics of the inclined surface of the natural ground.
[0004]
In other words, for example, if the size of the pressure receiving plate is kept as it is, the interval between the plurality of anchor members locked to the natural ground (anchor pitch), that is, the interval between the pressure receiving plates arranged side by side in the natural mountain is enlarged. It is possible to increase the portion where the natural ground is exposed between the plurality of pressure receiving plates. However, in this case, it is possible to improve the landscape of the slope by planting the exposed part of the natural ground, but the area of the contact surface of the pressure plate remains the same, and the landslide of the pressure plate is Since the ability to prevent or slope failure remains the same, there is a possibility that the increased exposed part of the natural ground may cause landslide or slope failure, preventing the original landslide and slope failure of the pressure plate There is a problem that the purpose is lost.
On the other hand, if the ability to prevent the landslide and slope collapse is improved by expanding the diamond shape of the conventional pressure plate in a similar shape, the landslide and slope failure can be prevented even if the anchor pitch is increased. However, in this case, there is a problem that the exposed portion of the natural ground cannot be increased and the landscape of the inclined surface of the natural ground is damaged.
[0005]
The present invention has been made in view of the above circumstances, and its purpose is to increase the anchor pitch and improve the beauty of the natural mountain while preventing the landslide and slope failure of the natural mountain. There is a place to provide a pressure plate that can.
[0006]
[Means for Solving the Problems]
As shown in FIGS. 1, 2 and 4, the characteristic structure of the first aspect of the invention is a support beam which is configured to be grounded on the slope F and protrudes in four directions along the ground surface 3a. 1, an anchor insertion portion 5 formed on the support beam 1 for inserting the anchor member 8, an anchor locking portion 6 formed on the anchor insertion portion 5 for locking the anchor member 8, and the support A hook-like plate portion 2 connected between adjacent projecting portions 7 of the beam 1 and configured to be groundable to the slope F, and using the anchor member 8 locked in the ground, the slope F is It is a pressure receiving plate for an anchor method constructed so as to be capable of pressure contact,
The support beam 1 has a concave shape with an opening on the upper side, and the tip of the projecting portion 7 is directed outward along the ground contact surface 3a rather than the connection point with the bowl-shaped plate portion 2. It is in a place to project.
[0007]
[Function and effect]
The pressure receiving plate for anchor method (hereinafter simply referred to as pressure receiving plate) according to the present invention includes a supporting beam and a hook-shaped plate portion connected to the supporting beam, and supports the pressure receiving plate having a conventional semi-square type structure. It inherits the advantages from the functions of the beam and the saddle plate.
[0008]
In addition, the support beam has a concave shape with an opening on the upper side, and the tip of the protruding portion protrudes outward along the grounding surface from the connection point with the bowl-shaped plate portion. Since it is configured, the area of the ground plane is enlarged, and the function of pressing the slope with the ground plane is also improved.
Therefore, even if the anchor pitch is increased than before and arranged side by side on the natural ground so that the exposed portion of the natural ground increases, the support beam that protrudes from the connection point with the bowl-shaped plate portion. Landslides and slope failures are prevented by improving the function of the protrusions.
On the other hand, according to the above configuration, after being installed on the slope, the end side of the bowl-shaped plate portion, the peripheral edge of the protruding portion of the portion projecting from the connecting portion with the bowl-shaped plate portion, and the support beam The natural ground is exposed at a portion surrounded by a straight line connecting the corners of the distal ends (that is, the protruding portion distal ends), and the exposed portion of the natural ground can be increased.
[0009]
Therefore, while preventing landslides and slope failures in the natural ground, the anchor pitch is increased, the exposed part of the natural ground is increased, and the exposed part of the natural ground is planted to improve the landscape of the slope. Can be planned.
In addition, by planting the exposed part of the natural ground and planting it, not only can the landscape be improved, but the roots of the planted vegetation extend to the natural ground, which can cause landslides and slope failures of the natural ground. It will also be prevented.
[0010]
Incidentally, as in this configuration, since the support beam itself is extended by projecting the projecting portion beyond the connecting portion with the bowl-shaped plate portion, the function of supporting and reinforcing the pressure receiving plate of the support beam is of course also provided. As a result, it has become possible to provide a pressure receiving plate having a function having a strength that does not cause deformation or breakage of the pressure receiving plate as compared with a conventional semi-square type pressure receiving plate.
As shown in FIGS. 1, 2, and 4 , the characteristic configuration of the second aspect of the invention is a support beam that is configured to be grounded on the slope F and that protrudes in four directions along the ground surface 3 a. 1, an anchor insertion portion 5 formed on the support beam 1 for inserting the anchor member 8, an anchor locking portion 6 formed on the anchor insertion portion 5 for locking the anchor member 8, and the support A hook-like plate portion 2 connected between adjacent projecting portions 7 of the beam 1 and configured to be groundable to the slope F, and using the anchor member 8 locked in the ground, the slope F is It is a pressure receiving plate for an anchor method constructed so as to be capable of pressure contact,
When the support beam 1 is configured, the tip of the projecting portion 7 protrudes outwardly along the grounding surface 3a from the connecting portion with the saddle-like plate portion 2, and the saddle-like plate The portion 2 is in a shape in which the thickness is reduced from the connection location toward the tip .
[Function and effect]
The support beam is formed by projecting the tip of the projecting portion outward from the connecting portion with the bowl-shaped plate portion along the grounding surface. As in the previous invention, while preventing landslides and slope failures of natural ground, increasing the anchor pitch, increasing the exposed part of natural ground, planting in the exposed part of natural ground, etc. The landscape can be improved.
Furthermore, since the thickness of the bowl-shaped plate portion is reduced from the connecting portion toward the tip, the bending moment due to the ground reaction force from the slope becomes smaller toward the end portion side of the protruding portion. This corresponds to the magnitude of stress to be borne, and can be configured with the minimum necessary members, and the pressure receiving plate can be reduced in weight.
[0011]
As shown in FIGS. 1, 2, and 4 , the characteristic configuration of the third aspect of the invention is a support beam that is configured to be grounded on the slope F and that protrudes in four directions along the ground surface 3 a. 1, an anchor insertion portion 5 formed on the support beam 1 for inserting the anchor member 8, an anchor locking portion 6 formed on the anchor insertion portion 5 for locking the anchor member 8, and the support A hook-like plate portion 2 connected between adjacent projecting portions 7 of the beam 1 and configured to be groundable to the slope F, and using the anchor member 8 locked in the ground, the slope F is It is a pressure receiving plate for an anchor method constructed so as to be capable of pressure contact,
The support beam 1 has a grounded bottom plate portion 3 and ridge reinforcing plate portions 7A, 7B, 7C erected on the grounded bottom plate portion 3 and has a concave shape with an opening on the upper side, and a protruding portion thereof 7 protrudes outwardly along the grounding surface 3a from the connection point with the bowl-shaped plate portion 2, and the grounding bottom plate portion 3 and the bowl-shaped plate portion 2 have through holes 21, 22 and 23 are provided .
[0012]
[Function and effect]
Since the support beam has a grounding bottom plate part and a reinforced plate part erected on the grounding bottom plate part, it can resist the bending moment due to the ground reaction force from the slope that the grounding bottom plate part receives, and further support it. The beam has a concave shape with an opening in the upper part, and the tip of the projecting part is configured to project outwardly along the grounding surface rather than the connection point with the bowl-shaped plate part. Therefore, as in the first and second aspects of the invention described above, while preventing landslides and slope failures of natural ground, the anchor pitch is increased to increase the exposed portion of natural ground, and the exposed portion of natural ground. It is possible to improve the landscape of the slopes by planting the plant.
Since is provided with respective through holes in the flange-like plate portion grounding the bottom plate portion, toward the ground plane from the surface of the ground bottom plate portion and the flange-like plate portion, because moisture is that Do freely communicating, ground bottom plate portion and the flange It is possible to further promote the greening of natural ground by planting vegetation by incorporating soil for planting on the plate-like plate part.
In other words, when planting vegetation with soil for planting on the grounded bottom plate portion and the bowl-shaped plate portion, when excessive moisture is supplied to the soil for planting, moisture is passed through the through holes. On the other hand, when it is discharged to the natural ground side, it is expected that water will be replenished from the natural ground through the through-hole when the water is insufficient, and an appropriate moisture state of the soil for planting will be maintained. Therefore, the plants planted on the grounded bottom plate portion and the bowl-shaped plate portion are not affected by the weather or the like and will not die, and will be planted until they grow sufficiently.
Therefore, the greening of the natural ground can be further promoted, and the beauty of the inclined surface of the natural ground after the pressure plate is installed on the slope can be further improved.
[0013]
Furthermore, the roots of planted trees that have been planted and grown on the grounded bottom plate part and the bowl-shaped plate part reach the ground through the through-holes , and such plants grow from the roots in the ground to the ground. It is possible to replenish water and nutrients, and it can be expected that excess water can be drained to the natural ground through the through holes . In addition, it can be expected that landslides and slope failures are less likely to occur when the vegetation grows roots through the through-holes and into the ground.
[0014]
In addition, as mentioned above, although the code | symbol was written in order to make contrast with drawing convenient, this invention is not limited to the structure of an accompanying drawing by this entry.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. In the drawings, the parts denoted by the same reference numerals as those in the conventional example indicate the same or corresponding parts.
[0016]
The anchoring method pressure receiving plate (hereinafter simply referred to as pressure receiving plate) according to the present invention is formed of, for example, ductile cast iron, which is a kind of metal material, as shown in FIGS. The support beam 1 that is configured and protrudes in four directions along the ground surface 3a and is formed in a cross shape, the anchor insertion portion 5 formed in the support beam 1 for inserting the anchor member 8, and the anchor member 8 are locked. In order to achieve this, a hook-like plate part 2 connected between the anchor engaging part 6 formed in the anchor insertion part 5 and the adjacent projecting part 7 of the support beam 1 and configured to be groundable on the slope F. Are manufactured by integrally casting.
[0017]
Hereinafter, the structure of the pressure receiving plate will be described in detail with reference to FIGS.
[0018]
As shown in FIG. 1, the pressure receiving plate is formed such that the support beam 1 and the bowl-shaped plate portion 2 are integrally provided so as to be groundable on the slope F, and the grounding surface 3a is formed of a single plane. While being formed, the overall shape is configured such that the four tops of the approximately rhombus project outward.
[0019]
In the embodiment, as shown in FIGS. 1 and 2, the support beam 1 is provided with the locking portion 6 at the approximate center thereof, and outwardly along the grounding surface 3a with the locking portion 6 as a center. Protruding portions 7 projecting in all directions are provided to form a cross shape.
[0020]
The locking portion 6 is connected to the anchor insertion portion 5 for insertion of the anchor member 8 provided at a substantially central position of the ground bottom plate portion 3 that can be grounded to the slope F of the cross-shaped support beam 1. 8 is configured to be locked.
The grounding bottom plate portion 3 is provided with four surrounding fence reinforcing plate portions 10 so as to surround the locking portion 6, and is connected to the surrounding fence reinforcing plate portion 10 and the locking portion 6. A cross-shaped reinforcing rib 11 is provided.
[0021]
The projecting portion 7 projects in a cruciform shape from the surrounding heel reinforcing plate portion 10 in four directions. In the present embodiment, the peripheral heel reinforcing plate portion 7A stands integrally along the peripheral portion of the grounded bottom plate portion 3. Set up and configured.
Incidentally, the grounding bottom plate portion 3 and the peripheral edge reinforcing plate portion 7A constituting the projecting portion 7 are configured in a tapered shape so as to become narrower toward the end portion in either a plan view or a side view. It is. This corresponds to the magnitude of stress to be borne in view of the fact that the bending moment due to the ground reaction force from the slope F becomes smaller toward the end of the protruding portion 7. Moreover, if it is this structure, it can comprise with a required minimum member and the weight reduction of a pressure receiving plate can be achieved. For the same reason, the peripheral edge reinforcing plate portion 7A may be configured so that the thickness of the peripheral edge reinforcing plate portion 7A is thinner toward the end portion side, and the pressure receiving plate can be further reduced in weight.
[0022]
Moreover, in this embodiment, as shown in FIGS. 1 and 2, for the purpose of increasing the strength of the projecting portion 7, the projecting portion 7 has a vertical bottom reinforcing plate portion 7 </ b> B and a lateral direction reinforcing member for the grounding bottom plate portion 3. The plate portion 7C is erected integrally.
The longitudinal penetrating reinforcing plate portion 7B is provided substantially in the center of the width of the grounding bottom plate portion 3 along the longitudinal direction of the projecting portion 7, and mainly has a function of improving the bending strength of the grounding bottom plate portion 3. .
The lateral heel reinforcing plate portion 7C is provided along a direction that is substantially perpendicular to the longitudinal direction of the protruding portion 7 and has a function of increasing the torsional rigidity of the protruding portion 7. .
[0023]
As shown in FIGS. 1 and 2, the protruding portion 7 is provided such that the tip side protruding toward the outside protrudes from the connecting portion with the bowl-shaped plate portion 2.
The degree of protrusion from the position where the protrusion 7 is connected to the flange-shaped plate portion 2 may be set as necessary. However, as shown in FIG. 2, L1 = La / 10 to La / 2 (note that La: Longitudinal dimension from the surrounding saddle reinforcing plate 10 to the tip of the protruding part 7 L1: Longitudinal dimension from the surrounding saddle reinforcing plate 10 to the connecting part of the protruding part 7 with the saddle-like plate 2 ), It is possible to prevent the landslide and slope collapse of the natural ground while increasing the exposed portion of the natural ground more appropriately, and also to reduce the weight of the pressure receiving plate. It is preferable.
Note that, as in the present embodiment, if the projecting state is set to L1 = La / 2, and the flange-shaped plate portion 2 is configured to be connected in series with the lateral-direction flange reinforcing plate portion 7C, The saddle-like plate portion 2 is more reliably supported and reinforced by the support beam 1 (particularly the lateral-direction saddle reinforcing plate portion 7C), and the strength and durability of the pressure receiving plate as a whole are improved, which is more preferable.
[0024]
The hook-shaped plate portion 2 connects adjacent projecting portions 7 of the support beam 1 and is connected so as to expand the ground contact surface 3a of the ground contact bottom plate portion 3 of the support beam 1 in the same plane. In the form, as described above, as shown in FIGS. 1 and 2, the peripheral edge reinforcing plate portion 7A of the adjacent projecting portion 7 is integrally formed between the surrounding edge reinforcing plate portion 10 and the lateral direction reinforcing plate portion 7C. It is provided in a triangular shape so as to be tied.
[0025]
Although the thickness of the bowl-shaped plate portion 2 may be a uniform thickness, in the present embodiment, as shown in FIG. 3 as an example, the bowl-shaped plate portion 2 is composed of a peripheral collar plate reinforcing plate portion 7A. From the connecting point to the tip, the shape is formed so that the thickness is reduced (in FIG. 3, an R shape is illustrated as an example) and configured. This corresponds to the magnitude of stress to be borne in view of the fact that the bending moment due to the ground reaction force from the slope F becomes smaller toward the tip side of the bowl-shaped plate portion 2.
On the other hand, as shown in FIG. 6, in the case of the conventional semi-square type pressure receiving plate, the bowl-shaped plate portion 2 is thin and has a small rigidity and is easily deformed. There is a concern that it is not responsible for the ground reaction force, that is, it does not press the slope F. As a countermeasure, it is conceivable to increase the rigidity by increasing the thickness of the plate. In this case, however, the weight of the pressure receiving plate is increased, which is undesirable in terms of construction.
On the other hand, according to the present configuration, the strength of the bowl-shaped plate portion 2 capable of resisting the bending moment can be secured without having an unnecessarily strong strength, and therefore the pressure receiving plate with a predetermined tension against the anchor member 8. Even if the tension is fixed, the deformation of the bowl-shaped plate portion 2 due to the ground reaction force can be prevented, and the tension force can be reliably transmitted to the end of the bowl-shaped plate portion 2, and the bowl-shaped plate It is possible to reduce the weight by reducing the thickness of the portion 2. In addition, the bowl-shaped plate portion 2 having such a shape can be easily formed by a casting technique using a mold if it is made of metal, and injection molding using a mold if it is made of resin. Can be formed easily. As a result, the material cost can be reduced as much as the weight of the pressure receiving plate can be reduced.
[0026]
The process of installing the pressure receiving plate configured as described above on the slope F is, for example, as follows.
[1] Carry out the process of transporting the pressure plate to the construction site.
[2] An anchor member 8 is inserted into an anchor hole excavated in a natural ground, a grout material is injected into the anchor hole, and the anchor member 8 is fixed in the ground.
[3] A step of lifting the pressure receiving plate with a lifting machine and setting the pressure receiving plate on the slope F in a state where the ground insertion portion of the anchor member 8 is passed through the anchor insertion portion 5 of the lifted pressure receiving plate. .
[4] A step of tightening the anchor member 8 via the receiving seat 4 by screwing and fastening a nut 9 as an anchor tension fixing member to a male screw portion screwed to the ground exposed portion of the anchor member 8 as a fastening portion. .
By implementing the above four steps sequentially, the slope protection construction is completed.
[0027]
Then, as shown in FIG. 4 (a), even if a plurality of pressure receiving plates are arranged side by side on the slope F, the exposed portion of the natural ground can be increased while taking over the advantages of the semi-square type pressure receiving plate. The fact that almost the entire mountain is covered with the pressure plate is eliminated. For this reason, as shown in FIG. 4 (b), it is possible to plant the vegetation on the exposed part of the natural ground, thereby greening the natural ground and improve the landscape. Moreover, it can be expected that landslides and slope failures will not easily occur when the planted plants grow sufficiently and vegetate roots in the ground.
[0028]
By the way, as shown in FIGS. 1 and 2, if a bottom hole 21 as a through-hole penetrating from the surface to the ground plane 3 a is provided in the bowl-shaped plate portion 2, it is also used for planting on the bowl-shaped plate portion 2. The soil for planting can be kept in an appropriate moisture state, and the plant can be planted with sufficient growth of plants and trees, making it possible to further green the ground (Fig. 4). (See (b)). Moreover, it can be expected that the planted plant grows sufficiently and the roots are vegetated into the natural ground through the bottom hole 21 so that landslides and slope failures are less likely to occur.
Note that, as described above, the hook-shaped plate portion 2 is formed on the surface of the hook-shaped plate portion 2 if it is formed in a shape in which the thickness is reduced from the connecting portion with the peripheral hook-shaped reinforcing plate portion 7A toward the tip. In this case, moisture is discharged along the gradient of the shape where the thickness is reduced, and it is difficult to accumulate.
[0029]
[Another embodiment]
Other embodiments will be described below.
<1> The support beam 1 may be formed in a box frame shape having no dent, for example, by precast concrete or the like. For example, as described in the previous embodiment, the grounding bottom plate portion 3 and the peripheral edge reinforcement are reinforced. If it consists of board part 7A etc., if it is in the shape with a dent which has an opening in the upper part, using such a dent space as planting space S, planting vegetation in which soil is included, and much more, By promoting the greening of the natural ground, as shown in FIG. 4 (b), it is possible to green the substantially entire natural ground. In FIG. 4B, the space surrounded by the surrounding fence reinforcing plate is also greened.
Incidentally, if the support beam 1 is configured as in the previous embodiment, the planting space S is partitioned into a predetermined size, so as shown in FIG. By embedding and fixing the sandbag D containing the plant in the planting section S, it becomes possible to plant plants and plants more easily. In addition, when fixing the sandbag D in this way, if the soil for planting and the seeds of plants are covered with a bag-like cover body, the seeds for planting soil and plants from the planting space due to rain, wind, etc. Etc. are less likely to be washed away, making it possible to plant vegetation in a planting space, plant trees, and improve the natural landscape, more reliably and efficiently. Needless to say, such a cover body is of a mesh shape and does not hinder the growth of plants.
[0030]
Moreover, when providing the planting space S in the support beam 1, it is still more preferable if the through-hole which becomes water supply / drainage is provided between the planting space S side and the natural ground side. An example of the configuration will be described. As shown in FIGS. 1 and 2, the grounding bottom plate portion 3, and the grounding bottom plate portion 3, the peripheral edge reinforcing plate portion 7A, the longitudinal penetration reinforcing plate portion 7B, and the lateral direction reinforcing plate portion 7C. If the first through hole 22 and the second through hole 23 are respectively provided in the corners formed by the above, the following operational effects can be expected.
That is, since the pressure receiving plate is installed on the inclined surface, the grounding bottom plate portion 3 is also inclined, and in particular, the corner portion is liable to collect moisture due to rainwater or the like. Through the first through-hole 22 and the second through-hole 23, the water that tends to accumulate in the grounded bottom plate portion 3 can be surely discharged to the ground. For this reason, even when soil is included in the planting space S and plants are planted, the water in the soil that has been included is appropriately maintained without being excessive, and these plants are grown under appropriate conditions. In addition, the possibility that the pressure receiving plate itself is corroded by moisture can be reduced.
Moreover, the planted vegetation grows sufficiently, and the roots are vegetated through the first through hole 22 and the second through hole 23 into the natural ground. In addition, it can be expected that replenishment of nutrients will promote greening of natural ground, and that landslides and slope failures will be less likely to occur. In addition, by providing the first through hole 22 and the second through hole 23, an effect of reducing the weight of the pressure receiving plate can be obtained.
[0031]
<2> In the previous embodiment, the configuration example in which the tip side of all the four protruding portions 7 of the support beam 1 protrudes from the connecting portion with the bowl-shaped plate portion 2 has been described. The number of the protrusions 7 that protrude from the connecting portion with the part 2 may be appropriately selected. For example, if only the two protrusions 7 in only one direction are configured as described above, a landslide or slope on the half-end surface K may be used. Collapse can be prevented, which is convenient (see FIG. 4).
[0032]
<3> In the previous embodiment, the plurality of pressure receiving plates are arranged side by side so as to form a straight line in the same row in the front, rear, left, and right. However, the arrangement may be set as necessary. May be arranged side by side.
[0033]
<4> In the previous embodiment, the shape of the bowl-shaped plate portion 2 is exemplified as a triangular shape, but may be appropriately formed in various shapes, for example, if it is formed in a fan shape, in all directions On the other hand, it is reasonable to press the ground more evenly .
[0034]
<5> The pressure receiving plate according to the present invention may be any pressure-receiving plate having predetermined strength, durability, and the like. For example, from a high-strength resin material (including fiber reinforced resin) such as polycarbonate, nylon, FRP, BMC, and the like. It may be configured, and a normal steel material may be assembled by welding.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a configuration example of a pressure receiving plate for an anchor method according to the present invention. FIG. 2 is a plan view showing a configuration example of a pressure receiving plate for an anchor method according to the present invention. Fig. 4 is an enlarged cross-sectional view of the main part of the pressure receiving plate for the anchor method. Fig. 4 is an explanatory diagram showing the construction state of the pressure receiving plate for the anchor method according to the present invention. Fig. 5 is a diagram of planting the pressure receiving plate for the anchor method according to the present invention. One construction example [Fig. 6] An explanatory diagram showing the structure of a conventional pressure receiving plate for the anchor method [Explanation of symbols]
B Ground mountain F Slope 1 Support beam 2 Saddle plate
3 Grounding bottom plate 3a Grounding surface 5 Anchor insertion part 6 Locking part 7 Protruding part
7A, 7B, 7C 竪 Reinforcement plate part 8 Anchor member 21 , 22, 23 Through hole

Claims (3)

法面に接地自在に構成され且つ接地面に沿って四方に突出して十字形に形成された支持梁と、アンカー部材挿通用として前記支持梁に形成されたアンカー挿通部と、アンカー部材を係止するために前記アンカー挿通部に形成されたアンカー係止部と、前記支持梁の隣合う突出部間に連接され且つ前記法面に接地自在に構成される鍔状板部とを備え、地中に係止したアンカー部材を用いて前記法面を圧接可能に構成されているアンカー工法用受圧板であって、
前記支持梁は、上方に開口を備える凹みのある形状を持ち、且つ、その突出部の先端が、前記鍔状板部との連接箇所よりも接地面に沿った外方に向けて突設するようにしてあるアンカー工法用受圧板。
The support beam is configured to be groundable on the slope and protrudes in four directions along the ground surface, and the anchor insertion portion formed in the support beam for anchor member insertion, and the anchor member is locked. An anchor locking portion formed in the anchor insertion portion, and a hook-like plate portion connected between adjacent projecting portions of the support beam and configured to be groundable on the slope, A pressure receiving plate for an anchor construction method configured to be able to press-contact the slope using an anchor member locked to
The support beam has a concave shape with an opening on the upper side, and the tip of the protruding portion protrudes outwardly along the grounding surface from the connection point with the bowl-shaped plate portion. A pressure receiving plate for anchor method.
法面に接地自在に構成され且つ接地面に沿って四方に突出して十字形に形成された支持梁と、アンカー部材挿通用として前記支持梁に形成されたアンカー挿通部と、アンカー部材を係止するために前記アンカー挿通部に形成されたアンカー係止部と、前記支持梁の隣合う突出部間に連接され且つ前記法面に接地自在に構成される鍔状板部とを備え、地中に係止したアンカー部材を用いて前記法面を圧接可能に構成されているアンカー工法用受圧板であって、
前記支持梁を構成するに、その突出部の先端が、前記鍔状板部との連接箇所よりも接地面に沿った外方に向けて突設し、且つ、前記鍔状板部は、その厚みが前記連接箇所から先端に向けて薄くなる形状にしてあるアンカー工法用受圧板。
The support beam is configured to be groundable on the slope and protrudes in four directions along the ground surface, and the anchor insertion portion formed in the support beam for anchor member insertion, and the anchor member is locked. An anchor locking portion formed in the anchor insertion portion, and a hook-like plate portion connected between adjacent projecting portions of the support beam and configured to be groundable on the slope, A pressure receiving plate for an anchor construction method configured to be able to press-contact the slope using an anchor member locked to
To constitute the support beam, the tip of the projecting portion protrudes outwardly along the ground surface from the connection point with the saddle plate portion, and the saddle plate portion A pressure receiving plate for an anchor method , which has a shape in which the thickness becomes thinner from the connected portion toward the tip .
法面に接地自在に構成され且つ接地面に沿って四方に突出して十字形に形成された支持梁と、アンカー部材挿通用として前記支持梁に形成されたアンカー挿通部と、アンカー部材を係止するために前記アンカー挿通部に形成されたアンカー係止部と、前記支持梁の隣合う突出部間に連接され且つ前記法面に接地自在に構成される鍔状板部とを備え、地中に係止したアンカー部材を用いて前記法面を圧接可能に構成されているアンカー工法用受圧板であって、
前記支持梁は、接地底板部とこの接地底板部に立設された竪補強板部を備えて上方に開口を備える凹みのある形状を持ち、且つ、その突出部の先端が、前記鍔状板部との連接箇所よりも接地面に沿った外方に向けて突設すると共に、前記接地底板部と鍔状板部にそれぞれ貫通孔を設けてあるアンカー工法用受圧板。
The support beam is configured to be groundable on the slope and protrudes in four directions along the ground surface, and the anchor insertion portion formed in the support beam for anchor member insertion, and the anchor member is locked. An anchor locking portion formed in the anchor insertion portion, and a hook-like plate portion connected between adjacent projecting portions of the support beam and configured to be groundable on the slope, A pressure receiving plate for an anchor construction method configured to be able to press-contact the slope using an anchor member locked to
The support beam has a grounded bottom plate portion and a heel reinforcing plate portion erected on the grounded bottom plate portion, and has a concave shape with an opening on the upper side. A pressure receiving plate for an anchor method , which protrudes outwardly along the grounding surface from the connection point with the part, and has a through hole in each of the grounding bottom plate portion and the bowl-shaped plate portion .
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