JP3721455B2 - Fish run-up structure and waterway member used therefor - Google Patents

Fish run-up structure and waterway member used therefor Download PDF

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Publication number
JP3721455B2
JP3721455B2 JP2002282263A JP2002282263A JP3721455B2 JP 3721455 B2 JP3721455 B2 JP 3721455B2 JP 2002282263 A JP2002282263 A JP 2002282263A JP 2002282263 A JP2002282263 A JP 2002282263A JP 3721455 B2 JP3721455 B2 JP 3721455B2
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water
fish
water channel
downstream
upstream
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JP2004068571A (en
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典夫 黒橋
世司 上野
憲二 端
棚橋  尚
脩 野辺
浩 吉田
昭一 石本
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Shiga Prefectural Government.
Hokukon Co Ltd
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Shiga Prefectural Government.
Hokukon Co Ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
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    • Y02A40/60Ecological corridors or buffer zones

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Description

【0001】
【発明の属する技術分野】
本発明は、排水路と、それよりも水位の高い水田や休耕田、溜め池、親水公園の池等としての貯水池との間に設けられ、該排水路から貯水池に無理なく魚類を遡上可能とする貯水池への魚類遡上構造に関するものであり、又該魚類遡上構造を構成する水路部材に関するものである。
【0002】
【従来の技術】
近年、水田や休耕田等の貯水池への、鮒、鯉、鯰等の魚類の遡上を可能として、水田等を魚類の産卵繁殖・育成の場として活用することにより、生態系保全を達成せんとする試みが成されている。本出願人の一人も、特開2000−120052号において、淡水貯留池への魚類の遡上システムを提案した。
【0003】
該遡上システムを構成する魚道は、図67に示すように、淡水貯留池側aが淡水貯留池bの水位より低位で且つ水路側cが水路dの水位より低位にある床部eと、この床部eの両側から夫々上方に立ち上がり且つ淡水貯留池bと水路dとを連通させる水の通路を形成する側壁fと、前記床部eと両側壁f,fとにより構成される空間g内に設けられ且つ上流側と下流側とを隔てると共に上流側の水を溢流させる越流部hとが設けられた隔壁jとを具える構成のものであった。
【0004】
前記遡上システムは、その出願明細書に記載の通り、各隔壁の越流部を、下流側の水位に対して魚類が遡上可能な高さとなるように設計し、淡水貯留池の水位を略所定のレベルに維持して、水路側から淡水貯留池側に魚類を遡上させるようにしていたため、水路側から淡水貯留池側に魚類を容易に遡上させることができ、淡水貯留池における生物保全機能を向上させ、ビオトープに多様な生物を生息させることができるという大きな効果を奏するものであった。
【0005】
【特許文献1】
特開2000−120052号公報(第4−7頁、第3図)
【0006】
【非特許文献1】
「農業用排水路の生態系配慮型工法」、滋賀県農林土木コンクリート製品協会、平成13年12月21日、P.2−6
【0007】
【発明が解決しようとする課題】
しかしながら前記遡上システムによるときは、魚道の床部とこの床部の両側から立ち上がる側壁を、水路と淡水貯留池とを繋ぐように一連に形成していたため、魚道の構築が、現場打ち施工を主体としたものとなり、畦部等の幅や落差に応じた個別的な施工に多くの手間を要し施工コストの上昇を招くばかりか、工期が長引く問題があった。更に、前記一連構築の魚道によるときは、屈曲した魚道は構築しにくいことから、水路と淡水貯留池との間の落差が大きい場合、屈曲魚道によりこれに対応せんとしても、その施工が容易でない問題もあった。
【0008】
又、前記床部eとその両側から夫々立ち上がる側壁f,fとが一体のU字溝状ブロックとして構成される場合は、施工現場に応じた所定長さのブロックを個別的に設計製造しなければならず、型枠が高騰して製造コストの著しい上昇を招くことになる。加えて、長さの長いU字溝状ブロックは重量が大きくなり、施工現場への搬送が容易でなく又施工性を悪化させる問題も発生させることになる。
【0009】
本発明は、主としてかかる問題点に鑑みて開発されたものであり、低水位の排水路から高水位の貯水池への魚類の遡上を容易に行わせ得るのはもとより、排水路の水位と貯水池の水位間の落差の程度に応じた適切な魚道を容易に形成できて施工能率の向上と施工コストの低減を期し得る、貯水池への魚類遡上構造の提供を課題とするものである。
【0010】
又、魚類の遡上を可能とする越流部の高さ調整を施工現場に応じて適切に行うことのできる魚類遡上構造の提供を課題とするものであり、更に、魚類の遡上を誘発し易い魚類遡上構造の提供を課題とするものである。加えて、かかる魚道を合理的に構成できる水路部材の提供を課題とするものである。
【0011】
【課題を解決するための手段】
前記課題を解決するため、本発明は以下の手段を採用する。
即ち本発明に係る魚類遡上構造は、排水路と、該排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を含み、該魚道を、水路部材の複数を順次接合して構成した貯水池への魚類遡上構造であって、前記水路部材は、その水路の上流側部と下流側部に、上流側開口と下流側開口を具え、上流側に設置された該水路部材の下流側開口が、下流側に設置された該水路部材の上流側開口に連通するように水路部材相互が接合されると共に、最上流側に設置された前記水路部材の上流側開口が前記貯水池に連通され、且つ最下流側に設置された前記水路部材の下流側開口が前記排水路に連通されている。又、前記水路部材の水路の下流側部位に、水路水を嵩上げする堰板が着脱可能に装着され、該堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とするものである。
【0012】
前記魚類遡上構造において、前記水路部材は、上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成すると共に、その上流側の水路幅を拡大し、該水路部材の下流側をなす接合部を嵌め入れるための接合嵌合部とし、該接合部が該接合嵌合部に嵌め入れられた状態において、前記接合部の前記接合嵌合部に対する、水路部材の長さ方向で見た挿入量を調節可能となし、又該水路部材の水路の下流側部位に、前記堰板を着脱可能に嵌め入れるためのガイド部を設け、上流側に設置された水路部材の前記接合部が、下流側に設置された水路部材の前記接合嵌合部に嵌め入れられたものとし、又前記ガイド部に前記堰板が嵌め入れられたものとするのがよい。
【0013】
前記魚類遡上構造において、前記水路部材の上流側の部分の水路の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台を突設するのがよい。
【0014】
本発明に係る魚類遡上構造のより好ましい態様は、排水路と、該排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を含み、該魚道を、水路部材の複数を順次接合して構成した貯水池への魚類遡上構造であって、前記水路部材は、上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成されると共に、その上流側の水路幅が拡大され、該水路部材の下流側をなす接合部を嵌め入れるための接合嵌合部とされている。又該水路部材の水路の下流側部位の対向側面と底面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられ、又、前記水路部材の上流側の部分の水路の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台が突設され、更に、前記水路部材の水路の上流側部位の対向側面と底面に、前記貯水池の水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられている。又、上流側に設置された水路部材の前記接合部が、下流側に設置された水路部材の前記接合嵌合部に、該接合部を前記支持台に載せた状態で嵌め入れられると共に、最上流側に設置された前記水路部材の上流側開口が前記貯水池に連通され、且つ最下流側に設置された前記水路部材の下流側開口が前記排水路に連通されている。又、前記各嵌入溝に嵌め入れられた堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とするものてある。
【0015】
支持台を有する前記魚類遡上構造において、該支持台を、前記水路部材の上流側の部分の水路の底部に、水路の長さ方向の前後に所要間隔を置いて突設し、より上流側に位置する支持台を、その下流側に位置する支持台よりも低い高さに設定するのがよい。
【0016】
支持台を有する前記魚類遡上構造において、前記支持台を前記水路部材と別体に形成し、該支持台を水路部材に後付けすることがある。該後付けされる支持台は、所要高さの支持台片を複数段に積重して構成されることがある。
【0017】
前記水路部材をU字溝状に形成する場合、該水路部材の水路の下流側部位に前記堰板を着脱可能に嵌め入れる際、該堰板の外周面の下流端側が、前記水路の下流端の内周面に当接し、該堰板の下流側の面が前記水路部材の下流端面と面一となるように構成するのがよい。
【0018】
本発明に係る魚類遡上構造の他の態様は、排水路と、該排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を含み、該魚道を、水路部材の複数を順次接合して構成した貯水池への魚類遡上構造であって、前記水路部材は、上端開放で且つ周方向の壁部で閉じられた有底の箱状に形成されると共に、該壁部の上流側部の所要部位と下流側部の所要部位に、上流側開口と下流側開口が設けられており、上流側に設置された水路部材の前記下流側開口が、下流側に設置された水路部材の前記上流側開口に連通するように水路部材相互が接合され、該両開口の連通部分に、水路水を嵩上げする堰板が着脱可能に装着されている。又、最上流側に設置された前記水路部材の上流側開口が前記貯水池に連通され、且つ最下流側に設置された前記水路部材の下流側開口が前記排水路に連通されており、前記堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とするものである。
【0019】
前記魚類遡上構造において、上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材の前記上流側開口に、上流側に設置された前記水路部材の下流側部分を挿入し、その挿入量を調節可能となすと共に、前記水路部材の前記下流側開口に、下流側に設置された前記水路部材の上流側部分を挿入し、その挿入量を調節可能となすのがよい。
【0020】
上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材を具える前記魚類遡上構造において、該水路部材の水路に、前記上流側開口と前記下流側開口間を仕切るように、水路水を嵩上げする中間の堰板を着脱可能に装着し、該中間の堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定するのがよい。
【0021】
上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材を具える前記魚類遡上構造において、該水路部材の水路に、前記上流側開口と前記下流側開口間を複数に仕切るように、水路水を嵩上げする中間の堰板の複数を着脱可能に装着し、該各中間の堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定するのがよい。
【0022】
上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材を具える前記各魚類遡上構造において、該水路部材の前記上流側開口と下流側開口は、該両開口を通過する水の流れ方向が屈曲するように前記壁部に設けるのがよい。
【0023】
前記各魚類遡上構造において、前記越流部の下流側を円弧面に形成するのがよい。又前記各魚類遡上構造において、前記越流部の下流側を13〜60度の角度で下方に傾斜する傾斜面に形成するのがよい。
【0024】
本発明に係る魚類遡上構造のその他の態様は、排水路と、該排水路の水位よりも高い水位を有する水田に魚類を遡上させるための魚道を含む魚類遡上構造であって、該魚道は、水路部材の複数を、前記排水路と前記水田との間をなす畦部の延長方向に順次接合して魚道本体を形成すると共に、該魚道本体を構成するために最下流側に設置された水路部材に設けた下流側開口に、前記排水路に連通され且つ地下埋設されたパイプ状の水路部材の上流側の端部分が接合される一方、前記魚道本体を構成する最上流側に設置された水路部材の上流側開口に、水田に結果的に連通される水路部材の下流側の端部分が接合されており、又、前記魚道本体を構成する前記水路部材の夫々に、水路水を嵩上げする堰板が着脱可能に装着され、該堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とするものである。
【0025】
本発明に係る魚類遡上構造のその他の態様は、排水路と、該排水路の水位よりも高い水位を有する水田に魚類を遡上させるための魚道を含む魚類遡上構造であって、該魚道は、水路部材の複数を、前記排水路と前記水田との間をなす畦部の延長方向に順次接合して魚道本体を形成すると共に、該魚道本体を構成するために最下流側に設置された水路部材に設けた下流側開口に、前記排水路に連通され且つ地下埋設されたパイプ状の水路部材の上流側の端部分が接合される一方、前記魚道本体を構成する最上流側に設置された水路部材の上流側開口に、水田に結果的に連通され且つ地下埋設されたパイプ状の水路部材の下流側の端部分が接合されており、又、前記魚道本体を構成する前記水路部材の夫々に、水路水を嵩上げする堰板が着脱可能に装着され、該堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とするものである。
【0026】
これらの場合、前記パイプ状水路部材は、例えば円形パイプ状に形成し、又、略水平に配設するのがよい。
【0027】
前記各魚類遡上構造において、前記堰板に、前記魚道を流れる水に漂う魚類誘導用の紐状物の上端側を取り付けるのがよい。
【0028】
前記各魚類遡上構造において、前記堰板を、水路部材に着脱可能に装着される堰板本体と該堰板本体に付設されるスライド調整板とから構成し、該堰板本体は、上端開放の切欠部が設けられたものとし、前記スライド調整板は、前記切欠部の下側部分を覆うように前記堰板本体に当接状態に且つ上下方向でスライド可能に付設し、又該スライド調整板の上端を前記越流部とし、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該スライド調整板の上下方向のスライド状態を調整できるものとし且つ該調整状態で該スライド調整板を前記堰板本体に固定可能とするのがよい。
【0029】
前記各魚類遡上構造において、前記魚道を遡上する魚類が魚道の外に飛び出すのを防止すると共に、遡上中の魚類が鳥類に捕食されるのを防止するために、魚道の上側を防止ネットや透明被覆材で覆うのがよい。この場合、該防止ネット又は透明被覆材は、前記水路部材に立設状態に設けた支持枠に被せて、前記魚道の上側を覆うように構成するのがよい。
【0030】
又前記各魚類遡上構造において、前記排水路に、該排水路を流れる水を嵩上げする隔壁を着脱可能に装着し、該隔壁を、前記排水路に着脱可能に装着される隔壁本体と該隔壁本体に付設される調整板とから構成し、該隔壁本体は、上端開放の切欠部が設けられると共に、前記調整板は、前記切欠部の下側部分を覆うように前記隔壁本体に当接状態に且つ上下方向でスライド可能に付設されるものとし、又、該調整板の上端を前記越流部とし、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該調整板の上下方向のスライド状態を調整でき且つ該調整状態で該調整板を前記隔壁本体に固定可能とするのがよい。
【0031】
又前記各魚類遡上構造において、前記排水路に、該排水路を流れる水を嵩上げする隔壁を装着し、該隔壁は、前記排水路における水の流れ方向に延長し且つ前記排水路の幅に略等しい幅を有する底板の上流側の端部に前板が立設されると共に、該底板の下流側の端部に後板が立設されてなる洗掘防止ブロックの該前板を以って形成し、該前板の一部分を、下流側の水位に対して魚類が遡上可能な高さに設定された越流部とするのがよい。
【0032】
この場合、前記隔壁となる前板を、その一部をなす隔壁本体と、該隔壁本体に付設される調整板とから構成し、該隔壁本体は、上端開放の切欠部が設けられると共に、前記調整板は、前記切欠部の下側部分を覆うように前記隔壁本体に当接状態に且つ上下方向でスライド可能に付設されるものとし、又該調整板の上端を前記越流部とし、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該調整板の上下方向のスライド状態を調整でき且つ該調整状態で該調整板を前記隔壁本体に固定可能とするのがよい。
【0033】
又前記各魚類遡上構造において、前記排水路に、前記魚道の下流側に位置させて洗掘防止ブロックを配設し、該洗掘防止ブロックは、前記排水路における水の流れ方向に延長し且つ前記排水路の幅に略等しい幅を有する底板の上流側の端部に、該排水路を流れる水を嵩上げする隔壁として機能する前板が立設されると共に、該底板の下流側の端部に後板が立設されたものとし、該前板の一部分を、下流側の水位に対して魚類が遡上可能な高さに設定された越流部とし、且つ前記前板と後板との間をなす空所に濾過材を収容するのがよい。
【0034】
隔壁が着脱可能に装着された前記魚類遡上構造において、前記越流部の下流側を円弧面に形成するのがよい。又該魚類遡上構造において、前記越流部の下流側を、13〜60度の角度で下方に傾斜する傾斜面に形成するのもよい。
前記隔壁を洗掘防止ブロックの前板を以って構成する場合、該前板を、排水路に装着される、上端開放の切欠部が設けられた隔壁本体と、該隔壁本体に付設される調整板とから構成する場合、該切欠部の下流側の縁部分を、13〜60度の角度で拡大するように、下流側に向けて傾斜する傾斜面に形成するのがよい。
【0035】
前記堰板を堰板本体とスライド調整板とで構成する場合、前記切欠部の下流側の縁部分を円弧面に形成するのがよい。或いは、該切欠部の下流側の縁部分を、13〜60度の角度で拡大するように、下流側に向けて傾斜する傾斜面に形成するのがよい。
【0036】
又前記隔壁を隔壁本体と調整板とで構成する場合、前記切欠部の下流側の縁部分を円弧面に形成するのがよい。或いは、該切欠部の下流側の縁部分を、13〜60度の角度で拡大するように、下流側に向けて傾斜する傾斜面に形成するのがよい。
【0037】
排水路が隔壁を具える前記魚類遡上構造において、前記越流部の下側に位置させて水抜き孔を設けるのがよい。
【0038】
前記各魚類遡上構造において、前記排水路に、その幅方向に適宜間隔で、産卵育成用の水草状紐体を配置するのがよい。この場合、該水草状紐体は、紐状体の一端に重りが設けられると共にその他端に浮きが設けられたものとし、該紐状体を、紐片の周面に50〜100mm程度の長さを有する毛片が多数設けられたものとし、前記重りを前記排水路の底部に設置する。
【0039】
本発明に係る魚類遡上構造に用いる水路部材(以下水路部材という)は、排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成されると共に、その上流側の水路幅が拡大され、その下流側をなす接合部の全部又は一部を嵌め入れるための接合嵌合部が形成されており、又前記水路の下流側部位に、水路水を嵩上げする堰板を着脱可能に嵌め入れるためのガイド部が設けられ、又、前記水路の上流側の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台が突設されていることを特徴とするものである。
【0040】
本発明に係る水路部材のより好ましい態様は、排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成されると共に、その上流側の水路幅が拡大され、その下流側をなす接合部の全部又は一部を嵌め入れるための接合嵌合部が形成されており、又前記水路の下流側部位に、その対向側面と底面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられ、又、前記水路の上流側の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台が突設されていることを特徴とするものである。
【0041】
本発明に係る水路部材の他の態様は、排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、上端開放で且つ周方向の壁部で閉じられ、その内部が水路とされた有底の箱状に形成されると共に、該壁部の上流側の所要部位と下流側の所要部位に、上流側開口と下流側開口が設けられ、該上流側開口と下流側開口の内面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるためのガイド部が設けられており、又、前記水路の内面に、前記上流側開口と下流側開口間を仕切るように、水路水を嵩上げする中間の堰板を着脱可能に嵌め入れるためのガイド部が設けられており、前記各堰板の越流部が、下流側の水位に対して魚類が遡上可能な高さに設定されていることを特徴とするものである。
【0042】
この場合、前記上流側開口と前記下流側開口間を複数に仕切るように、その対向側面と底面に、水路水を嵩上げする中間の堰板の複数を着脱可能に嵌め入れるためのガイド部を設け、前記各堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定するのがよい。
【0043】
本発明に係る水路部材のその他の態様は、排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、上端開放で且つ周方向の壁部で閉じられ、その内部が水路とされた有底の箱状に形成されると共に、該壁部の上流側の所要部位と下流側の所要部位に、上流側開口と下流側開口が設けられ、該上流側開口と下流側開口の、対向側面と底面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられており、又、前記水路の、対向側面と底面に、前記上流側開口と下流側開口間を仕切るように、水路水を嵩上げする中間の堰板を着脱可能に嵌め入れるための嵌入溝が設けられており、前記各堰板の越流部が、下流側の水位に対して魚類が遡上可能な高さに設定されていることを特徴とするものである。
【0044】
この場合、前記上流側開口と前記下流側開口間を複数に仕切るように、その対向側面と底面に、水路水を嵩上げする中間の堰板の複数を着脱可能に嵌め入れるための嵌入溝を設け、前記各堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定するのがよい。
【0045】
前記各水路部材において、前記上流側開口と前記下流側開口は、該両開口を通過する水の流れ方向が屈曲するように前記壁部に設けるのがよい。
【0046】
又前記各水路部材において、前記堰板の越流部の下流側を円弧面に形成するのがよい。或いは、前記堰板の越流部の下流側を、13〜60度の角度で下方に傾斜する傾斜面に形成するのがよい。
【0047】
又前記各水路部材において、前記堰板は、水路部材に着脱可能に装着される堰板本体と該堰板本体に付設されるスライド調整板とから構成し、該堰板本体は、上端開放の切欠部が設けられると共に、前記スライド調整板は、前記切欠部の下側部分を覆うように前記堰板本体に当接状態に且つ上下方向でスライド可能に付設されるものとし、該スライド調整板の上端を前記越流部とし、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該スライド調整板の上下方向のスライド状態を調整でき且つ該調整状態で該スライド調整板を前記堰板本体に固定可能するのがよい。
【0048】
【発明の実施の形態】
以下、本発明の実施の形態を図面に基づいて説明する。
〔第1の実施の形態〕
図1において本発明に係る魚類遡上構造1は、河川や湖等に連なる排水路2と、該排水路2の水位よりも高い水位を有する水田3aとしての貯水池3に魚類を遡上させるための魚道6を含むものである。そして該魚道6は、前記水田3aと前記排水路2との間をなす畦部5に、水路部材7の複数を直線状に段違いに順次接合して構成されており、排水路2の水位と水田3aとしての貯水池3の水位間の落差が比較的小さい場合に好都合に対応できる。今、畦部5の幅(図3にL1で示す)が約1900mmで、且つ排水路2の水位と水田3aの水位間の落差(図2にL2で示す)が約650mmである場合を想定する。
【0049】
前記水路部材7は、本実施の形態においては図4〜5に示すように、上端が開放され且つ上流端から下流端に向かう連続した水路9を有したU字溝状に形成されており、該水路9の上流端が上流側開口10とされると共に、下流端が下流側開口11とされている。又該水路部材7の上流側の部分は、水路幅が拡大されて、該水路部材7の下流側の部分をなす接合部12を略密接に嵌め入れるための接合嵌合部13とされている。該水路部材7の主要部の寸法を例示すれば、その全長が約600mmに設定されると共にその水路深さが約500mmに設定され、前記上流側の部分の水路幅が約610mmに設定され、前記下流側の部分の水路幅が約500mmに設定されている。
【0050】
又、前記水路部材7の前記上流側の部分の底部15には、図5、図7に示すように、その全幅に亘って、上流側に設置された水路部材7の接合部12の下面16を下方から支持する支持台17が突設されている。該支持台17は、その上面19が水平面に形成され、その高さは約100mmに設定されている。且つ、該支持台17の上面19と前記水路部材の下面18との間の距離L3(図7)が、魚類が遡上可能な水位差に略等しい約150mmに設定されている。
【0051】
又図4〜7に示すように、前記水路部材7の水路9の下流側部位の対向側面21,21と底面22に、水路水を嵩上げし、且つその越流部24(図4、図9)で水を下流側に向けて越流させる堰板23を嵌め入れるための嵌入溝25が連続して設けられている。そして前記水路9の上流側部位には、前記支持台17に近接する状態で、その上流側部位の対向側面26,26と底面27に、前記貯水池3の水を嵩上げし、且つその越流部24(図4、図9)で水を下流側に向けて越流させる堰板23を嵌め入れるための嵌入溝29が連続して設けられている。
【0052】
又前記堰板23には図4に示すように、その上端の中央部に、台形状や円弧状、矩形状、V字状等をなし且つ下端が前記越流部24となる越流切欠部30が設けられている。その形状や幅、深さは、前記魚道6を遡上する魚類の大きさや魚道6を流れる水量等を考慮して、該越流切欠部30において必要な越流幅や越流水深が得られように設定される。例えば、越流幅が小さく且つ越流水深が浅い場合は、小型魚類は遡上させ得ても大型魚類は遡上させ得ないことになり、限られた魚類しか遡上させ得ないことになる。そこで本実施の形態においては、大型魚類も遡上させ得るように、前記越流切欠部30を、上端幅L4が約150mmで深さL5が約100mmの台形状に形成している。又前記越流切欠部30の上端の下流側は、図8に拡大して示すように円弧面28に形成し、遡上する魚類が引っ掛かりにくくしている。
【0053】
然して、かかる構成を有する水路部材7を用いて前記魚類遡上構造1を構成するには、図1〜3に示すように、排水路2と水田3aとの間をなす畦部5を、該排水路2の流れ方向と略直交する直線状の傾斜状態で掘削し、該掘削部31で、4個の水路部材7,7,7,7を、直線状に段違いに順次接合するのであるが、その際、図7に示すように、下流側に設置された水路部材7aの前記接合嵌合部13に、上流側に設置された水路部材7bの前記接合部12を嵌め入れ、該接合部12を、前記下流側の水路部材7aの支持台17に載せ、各水路部材を略水平状態にして設置する。これにより、前記接合部12の下面16が前記支持台17の上面19に当接し、該接合部12が接合嵌合部13に嵌め入れられた状態となる。このようにして水路部材7,7相互を接合すると、前記魚道6が形成される。なお、上流側に設置された水路部材7bの接合部を、下流側に設置された水路部材7aの接合嵌合部13に嵌め入れる構成を採用するため、水路部材相互の接合部分32(図7)に特別な漏水対策を施す必要がない。図9は魚道6の拡大斜視図であり、図10は魚道の拡大断面図である。
【0054】
前記接合の際、前記接合嵌合部13に対する前記接合部12の挿入長さを、前記畦部5の幅と水路部材7の使用個数を考慮して所要に設定し、魚道の全長を、畦部の幅に合わせて適切に調節する。図2、図7においては、前記接合部12の端部33が、前記支持台17よりも下流側に突出し、例えば7cm程度の重なり代を有し、接合部の該突出した部分35の下面36と前記接合嵌合部13の前記底面15との間に空隙部37が形成されている。
【0055】
そして図2に示すように、最上流側に設置された水路部材7cの前記上流側開口10が前記水田3aに連通されると共に、最下流側に設置された水路部材7dの前記下流側開口11が、前記排水路2に連通されている。又、各水路部材7に設けられた前記下流側の嵌入溝25,25,25,25と、最上流側に設置された水路部材7cの前記上流側の嵌入溝29に、前記堰板23が夫々、着脱可能に嵌め入れられている。
【0056】
今説明の便宜上、図9、図10において、前記4個の水路部材を上から順に、第1水路部材7A、第2水路部材7B、第3水路部材7C、第4水路部材7Dといい、又、前記嵌入溝に嵌め入れられた5枚の堰板を上から順に、第1堰板23A、第2堰板23B、第3堰板23C、第4堰板23D、第5堰板23Eという。更に、前記堰板により嵩上げされた各水路部材内の貯水を上から順に、第1貯水39A、第2貯水39B、第3貯水39C、第4貯水39Dといい、該貯水を溜める部分を第1溜め部40A、第2溜め部40B、第3溜め部40C、第4溜め部40Dという。
【0057】
又前記排水路2は、本実施の形態においては図1〜2、図11〜12に示すように、コ字状支持枠41を所要間隔を置いて並設すると共に、排水路2の長さ方向で隣り合う立上がり片42,42間で側板43を複数段に支持させて構成され、複数段に支持された該側板43によって水路壁44が形成されている。そして、隔壁50(図1〜3、図11〜12)によって排水路2の水位が所要に嵩上げされている。
【0058】
該隔壁50は、排水路2の勾配や該排水路2を流れる水量に応じて、魚類が排水路2を遡上できるように、所要間隔で設置される。例えば図1〜2に示すように、その両端の縁部分50a,50aが、例えば1〜2m間隔で選択されたコ字状支持枠41の内面に設けられた挿入溝49(図1)に挿入せしめられ、該隔壁50によって排水路2の水位を所要に嵩上げし、該隔壁に設けた上端開放の越流切欠部52で水が下流側に越流するようになされ、該越流切欠部52の下端としての越流部54が、下流側の水位に対して魚類が遡上可能な高さ(例えば50〜150mm)に設定されている。該越流切欠部52は、排水路2の長さ方向で見て一直線上で並設されることの他、例えば図11〜12に示すように千鳥配置で設けられることもある。そして図11においては、隔壁間のコーナ部分53に魚類の遊泳場所が形成されている。
【0059】
又、前記水路壁44に欠切形成した開口38に、前記最下流側の水路部材7Dの下流側開口11が連通される。その際、図10に示すように、該開口38の底面38aと該下流側開口11の底面48が略面一状態になされている。
【0060】
該排水路2は、部分的に、例えば図12に示すように、一方の水路壁44aの一部分が畦側に拡大され、必要に応じ底部も掘り下げられて、魚介類の産卵や生息、避難に適した淀み部分、深み部分が設けられている。又、該拡大した部分45の底部から上端に亘って、階段状やスロープ状の、適宜凹凸が設けられた傾斜部材46が配設されており、昆虫類や両生類、爬虫類が該傾斜部材46を上り下りして排水路2と、畦部表面47や水田3aとの間を行き来できるようになされている。なお前記拡大した部分は、双方の水路壁44,44に設けられてもよい。
【0061】
次に、このように構成された魚類遡上構造1の作用を図9〜10に基づいて説明する。即ち、前記構成の魚道6によるときは、図示しないポンプを介して水田に淡水が供給されると、その水位が、最上流側に設置された前記水路部材7Aの第1堰板23Aによって嵩上げされ、該淡水は、該越流切欠部30の下端としての前記越流部24を越流して第1溜め部40A内に流入する。該第1溜め部40Aに流入した水路水は、前記第2堰板23Bによって嵩上げされ、該第2堰板23Bに設けた越流切欠部30の下端としての越流部24を越流した水路水が、前記第2溜め部40B内に流入する。そして、該第2溜め部40Bに流入された水路水は、前記第3堰板23Cで嵩上げされ、該堰板の越流切欠部30の下端としての越流部24を越流して前記第3溜め部40C内に流入する。該第3溜め部40C内に流入した水路水は、前記第4堰板23Dで嵩上げされ、該堰板の越流切欠部30の下端としての越流部24を越流して前記第4溜め部40D内に流入する。そして該第4溜め部40D内に流入した水路水は、前記第5堰板23Eで嵩上げされ、該堰板の越流切欠部30の下端としての越流部24を越流して、前記排水路2内に流出する。
【0062】
そして、排水路の水位56と第4貯水39Dの水位57との間、第4貯水39Dの水位57と第3貯水39Cの水位59との間、第3貯水39Cの水位59と第2貯水39Bの水位60との間、第2貯水39Bの水位60と第1貯水39Aの水位61との間に、夫々、魚類が遡上可能な50〜150mm程度の水位差、例えば100mm程度の水位差が設けられている。又、水田の水位62と、該最上流側の水路部材7Aにおける水位61との間にも、70mm程度の水位差が設けられている。そして、前記各越流部(越流水深は30〜50mm程度)24において魚類が遡上できる。
【0063】
従って本発明に係る魚類遡上構造1によるときは、鮒や鯉、鯰等の魚類を、河川や湖等から排水路2に進入させ、前記隔壁50の越流切欠部52を遡上させて前記魚道6が存する場所に至らせることができる。その後、該魚道6を遡上させ得る。具体的には、水面が階段状である前記第4貯水39D、第3貯水39C、第2貯水39B、第1貯水39Aに順に遡上させて水田3aに至らせ、水田で産卵させることができる。これにより水田3aを、魚類の産卵、繁殖、育成の場として活用でき、自然と共生した稲作を展開できることとなる。
【0064】
なお図9、図13に示すように、前記堰板23の例えば上端側66に、魚類誘導用の紐状物67の一端側68を、ビス止め等の手段で固定したり、該一端側を、堰板23等に設けた被掛着部に掛着させる等して取り付けるのがよい。取り付けた紐状物67に魚類誘導の機能をもたせることができる限り、前記上端側66は、前記越流切欠部30の下側や、越流切欠部30の周辺(側方部位等)として設定できる。
【0065】
該紐状物67は、魚道6の使用時期が終わった時点における最終処分を考慮し、有機性素材を用いて、例えば荒縄(5〜20mm程度の直径のもの)や綿素材等を用いて形成するのが好ましいが、樹脂製とされてもよい。図14は、該紐状物67の具体的な一例を示しており、1〜3mm程度の太さを有する紐片67aの周面に50〜100mm程度の長さを有する毛片67bを、放射状に多数に設けてなる。
【0066】
該紐状物67は、前記のように、各堰板23に一端側68が取り付けられ、その他端69が、下流側に設置された水路部材に至る程度に、例えば30〜50cm程度と比較的短く長さ設定されることの他、図10に破線で示すように、一端側68が最上段の堰板23Aに取り付けられて、水田3a側から排水路2側にまで垂れ流されるように長さ設定されることもある。或いは、複数の水路部材に亘って垂れ流されるように長さ設定されることもある。
【0067】
このように取り付けられた該紐状物67は、自然界の河川における水草のように、水流に乗って、下流側に流れる状態で揺れ動くため、魚類の遡上を誘発できることとなる。
【0068】
貯水池3が水田である場合、水田への魚類の産卵遡上時期が田植え時期に略合致しているため、この時期において前記堰板23を装着すると、前記魚道6における一定量の排水を行わせつつ水田の水位を一定に保つことができる。逆に、中干しや稲刈り前等の水位を下げる必要のあるときは(この時期には魚道が必要でない)、図15に示すように、前記全ての堰板を取り外し、水路64を通して水田の水を排水路2に排水する。又、このように堰板を取り外すことによって、魚道6の掃除を容易に行うことができる。
【0069】
又本実施の形態においては、上流側に設置された水路部材の前記接合部12の下面16を、下流側に設置された水路部材の前記支持台17で下方から支持させる構成であり、且つ、各水路部材の下流側部位に堰板23が装着されているため、図10、図7に示すように、各水路部材の底部には泥溜め72が形成される。従ってこの泥溜め72において、魚道を流下する水路水に含有されている水田からの有機物を沈殿させることができ、排水路2への有機物の流出をそれだけ防止できる。更に、該泥溜め72に堆積した土から水草等が生え、これが水路水の有機物を捕捉して水質浄化を図ることも期待できる。これ等により河川の汚染防止に寄与できる。又図7に示すように、前記水路部材7の底面部73を、更には側面部75を、自然石が露出した面に形成することにより、該自然石面に藻類を繁殖させることが可能になり、水路の底部を、小魚類や底生生物の餌場ともなし得え、その生息場を提供できることとなる。
【0070】
又水路部材相互を接合するに際して、図2、図7に示すように、接合嵌合部13内に突出した接合部12の突出部分の下面36と接合嵌合部13の底面15との間に前記空隙部37が形成されているため、この場所に藻を生やすことができ、該空隙部37を、陰を好む底生生物の生息場所となし得、又、稚魚の非難場所ともなし得る。
【0071】
本実施の形態においては図16に示すように、魚道6を遡上する魚類が魚道の外に飛び出すのを防止したり、遡上中の魚類が鳥類に捕食されるのを防止するするために、該魚道6の上側を覆うように、支持枠76を介して、例えば樹脂製の防止ネット77を取り付けることとしている。該防止ネット77の網目は、例えば、一辺長が30mm程度の菱形に形成される。
【0072】
前記支持枠76は、例えば、上下方向で接合された前記4個の水路部材7,7,7,7の夫々に取り付けられるものであり、図17〜18に示すように、上端高さが略等しい逆U字状をなす3本の枠片79a,79b,79cを間隔を置いて配置すると共に、該3本の枠片の上端水平部80,80,80を、その下面の両側で、2本の直線状連結片81,81により一体に連結してなり、前記水路部材7の上流端側に位置する枠片79aは、残りの枠片79b,79cよりも稍幅広に形成されている。そしてこれらの枠片は、例えば、直径10mm程度の中空パイプや中実棒材(金属製や樹脂製)を所定長さに切断し、これを逆U字状を屈曲して形成されており、水路部材7の上端からの最大高さは、例えば300〜400mm程度に設定されている。
【0073】
かかる構成の支持枠76を前記水路部材7に取り付けるには、前記幅広の枠片79aの両下端部分82,82を、該水路部材7の前記接合嵌合部13の上面の長さ方向の略中央に設けられた支持孔83,83に密接に挿入させると共に、中間の枠片79bの両下端部分82,82を、前記水路部材7の上面の長さ方向の略中央(前記接合嵌合部13と前記接合部12との接続部分)に設けた支持孔83,83に密接に挿入させ、又、水路部材7の下流端側に位置する前記枠片79cの両下端部分82,82を、前記水路部材7の下流端側の上面に設けた支持孔83,83に密接に挿入させて行う。このようにして各支持枠76を各水路部材に立設状態に取り付けて後、前記防止ネット77を、これらの支持枠76,76,76,76の上面部と両側部を覆うように且つ各水路部材7,7,7,7の側面部の上側部分を覆うように被せると、図16に示すように、魚道6の上側が防止ネット77で、上に突の半円形蒲鉾状に覆われた状態となる。これらの支持枠76や防止ネット77は、魚道の不用時期には取り外すことができる。なお、水路部材7に設ける前記支持孔83は、便宜上、図16〜18においてのみ示している。
【0074】
図19〜20は、U字溝状に形成された図21に示す水路部材7を上下方向で順次接合して構成した魚道6を示すものであり、前記実施の形態におけるものとは、水田3aとしての貯水池3の水を嵩上げする堰板(以下第1の堰板という)23aと、水路水を嵩上げする堰板(以下第2の堰板という)23bの構成が異なる。又、該水路部材7の上流側部位に設けた嵌入溝29の溝幅が若干広く形成されている。
【0075】
貯水池3の水を嵩上げする前記第1の堰板23aは、図20〜22に示すように、前記嵌入溝29に嵌め入れられる堰板本体85と、該堰板本体85に付設される落とし込み調整板86とからなり、該堰板本体85は、一側に寄せて、上端から前記水路部材7の底面近傍に至る縦長の矩形状切欠部87(図22)が設けられている。該矩形状切欠部87の上端幅L6は約150mmに設定されると共に、該矩形状切欠部の対向側面89,90と底面91に、貯水池3の水を嵩上げする前記落とし込み調整板86を嵌め入れるための装着溝92が連続して設けられている。
【0076】
そして該第1の堰板23aの上流側の面の下端部分は、前記支持台17の下流側の傾斜面93と当接し得る傾斜面95として形成されており、該傾斜面95の上端で上方に延長する面96は、前記支持台17の上面19と直角に交わる。又、前記装着溝92に嵌め入れられる前記落とし込み調整板86は、本実施の形態においては、上下高さの異なる2枚を用いている。そして、上段の落とし込み調整板の上端の上側に、図21に示すような矩形状の越流切欠部30が形成され、該上端として越流部24が、下流側の水位に対して魚類が遡上可能な高さ(例えば50〜150mm)に設定され、該越流部24における越流水深は、例えば30〜50mm程度に設定される。
【0077】
又前記第2の堰板23bは、本実施の形態においては図20〜21、図23に示すように、水路部材7の下流側部位に設けられた前記嵌入溝25に嵌め入れられる堰板本体97と、該堰板本体97に当接状態に付設されるスライド調整板99とからなり、該堰板本体97は、その外周面100の上流端側に、前記嵌入溝25に嵌め入れられる突条部101が設けられている。そして、該突条部101が前記嵌入溝25に嵌め入れられた状態で、図20に示すように、外周面100の下流端側102が前記水路の下流端の内周面103に当接し、この状態で、図20、図24に示すように、第2の堰板23bの下流側の面105が前記水路部材7の下流端面106と面一となるように構成されている。
【0078】
又、前記第1の堰板23aにおけると同じ側に稍寄せて、上端幅L7が約150mmで深さが270mm程度の矩形状切欠部107が設けられている。本実施の形態においては該矩形状切欠部107の周縁部分109が、下流側に向けて拡大するように面取りされている。該面取りは、遡上する魚類が該周縁部分に引っ掛かりにくくするために設けられるものであり、その傾斜角度は13〜60度程度に、好ましくは35〜45度程度に、更に好ましくは45度程度に設定される。又、該矩形状切欠部107の下流側の面110の両側において、上下3段で、前記スライド調整板99をボルト固定するためのインサート111,111,111、111,111,111が埋設されている。
【0079】
又前記スライド調整板99は、前記矩形状切欠部107を、その上流側又は下流側で覆うことによって(図19〜20においては下流側で覆っている)、該スライド調整板99の上端の上側に、図21に示すような矩形状の越流切欠部30を形成するために用いられるものである。そして該上端としての越流部24は、下流側の水位に対して魚類が遡上可能な高さ(例えば50〜150mm)に設定されると共に、該越流部24における越流水深は、30〜50mm程度に設定される。
【0080】
又、該スライド調整板99の上端112の下流側108は、図23に示すように、例えば13〜60度程度に、好ましくは35〜45度程度に傾斜する傾斜面に、更に好ましくは45度程度に傾斜する傾斜面に形成されており、遡上する魚類が引っ掛かりにくくしている。又該スライド調整板99の両側には、前記インサート111に捩じ込まれるボルト112を挿通させるための上下に長い調整孔113,113が設けられている。
【0081】
図24は、下2段のインサート111,111、111,111を用いてスライド調整板99を前記堰板本体97に固定した状態を示すものであり、越流部24が、下流側の水位に対して50〜150mm程度に設定されると共に、該越流部24における越流水深が30〜50mm程度に設定される。又図25は、上2段のインサート111,111、111,111を用いてスライド調整板99を堰板本体97に固定した状態を示すものであり、越流部24の高さと越流水深は前記と同様に設定されている。
【0082】
なお図26に示すように、前記スライド調整板99を付設しないで、矩形状切欠部107の下端を越流部24とすることもある。
【0083】
なお前記第1、第2の堰板23a、23bは、重量のある例えばコンクリ─ト製とされ、又前記落とし込み調整板86や前記スライド調整板99は、例えば木製や樹脂製、金属製等とされる。
【0084】
図19は、前記構成を有する第1、第2の堰板23a,23bが装着された水路部材7を用いて構成された魚類遡上構造1を示すものであり、水路部材7,7相互を接合して魚道6を構成する要領は前記と同様である。即ち該魚道6は、排水路2と水田3aとの間をなす畦部5を、該排水路2の流れ方向と略直交する直線状の傾斜状態で掘削し、該掘削部31で、3個の水路部材7,7,7を、直線状に段違いに順次接合して構成されている。その際、前記実施の形態におけると同様に、下流側に設置された水路部材の前記接合嵌合部13に、上流側に設置された水路部材の前記接合部12を嵌め入れ、該接合部12を、前記下流側の水路部材7の支持台17に載せ、各水路部材を略水平にして設置する。これにより、前記接合部12の下面16が前記支持台17の上面19に当接し、該接合部12が接合嵌合部13に嵌め入れられた状態となる。水路部材7,7相互がこのように接合されて前記魚道6が形成されている。
【0085】
そして図19に示すように、最上流側に設置された水路部材7gの前記上流側開口10が前記水田3aに連通されると共に、最下流側に設置された水路部材7eの前記下流側開口11(越流切欠部30)が、前記排水路2に連通されている。又、各水路部材7に設けられた前記下流側の嵌入溝25,25,25に前記第2の堰板23bが着脱可能に嵌め入れられると共に、最上流側に設置された水路部材7gの前記上流側の嵌入溝29に、前記第1の堰板23aが着脱可能に嵌め入れられている。
【0086】
そして該第1の堰板23a及び第2の堰板23b,23b,23bの夫々に関し、前記矩形状切欠部87,107においての越流部24の高さと越流水深は、前記排水路2と前記水田3aの水位間の落差L2と、前記畦部5の幅L1に応じて、前記落とし込み調整板86及び前記スライド調整板99の調整により、魚類の遡上を可能とするように所要に設定されるものである。この設定要領は前記した通りである。
【0087】
本実施の形態においては、前記第1の堰板23aが、水田の土が魚道側に移動するのを防止する土留としても機能する。又、上下に位置する第2の堰板23b,23b間に形成された空所115及び、最上流側の水路部材7gにおける、第1、第2の堰板23a,23b間の空所116に、図19に散点を付して示すように、濾過材117を納めることができる。このように濾過材117を納めることにより、水田より越流した水に含まれている汚泥などの微粒子を濾過し、排水路2に流れ込む排水の水質浄化を図ることができる。なお濾過材117としては、その最終処分を考慮して、藁や籾殻等の有機性の材質からなるものを用いるのが好ましい。又前記と同様にして、図19に示すように、各水路部材7に支持枠76を装着して防止ネット77を被せるのがよい。又、図9や図10に示すと同様にして、第1、第2の堰板23a,23bに、水草状の紐状物67を取り付けるのがよい。図19は、水田3a側から排水路2側にまで垂れ流される長い紐状物67を取り付けた場合を示している。
【0088】
図27は、U字溝状を呈する前記水路部材7を用いて構成した魚道6のその他の態様を示すものであり、畦の天端118や、畦の法面下端と排水路との間を成す畦道119に一輪車等を障害無く走行させたい場合に設けられて好都合である。
【0089】
該魚道6は、図27〜28に示すように、4個の水路部材7,7,7,7を、前記畦道6と畦の法面部120の境界部分において畦の長さ方向に順次接合して魚道本体121を形成するものである。そのために、下流側に設置された水路部材7jの前記接合嵌合部13に、上流側に設置された水路部材7kの前記接合部12を嵌め入れ、該接合部12を、前記下流側の水路部材7jの前記支持台17に載せ、各水路部材を略水平状態に設置して構成されている。そして最上流側に設置された水路部材7mの上流端側の嵌入溝29と、最下流側に設置された水路部材7jの下流端側の嵌入溝25に、図27、図30、図32に示すように、前記のような矩形状切欠部87,107を有さない端面板122,123を嵌め入れてなる。又、最下流側の水路部材を除く各水路部材の下流側の嵌入溝25,25,25に、前記第2の堰板23bと同様構成の堰板23,23,23を嵌め入れてなる。そして各堰板の越流切欠部30は、例えば図20に示すと同様にして、スライド調整板99のスライド操作により、所要高さの越流部24と越流水深が得られるように設定される。
【0090】
又前記魚道6は、図27〜30に示すように、最下流側に位置する水路部材7jの、排水路2に面する側の側面部125の下端側に、例えば円形孔としての下流側開口11が設けられており、該下流側開口11に、前記排水路2に連通される、例えば内径150〜200mm程度で、長さが畔道幅程度(60〜200cm程度)の塩化ビニール製パイプとして形成され且つ略水平に地下に埋設された水路部材7nの上流側の端部分127が挿入状態に接合されている。
【0091】
加えて図27、図31〜32に示すように、最上流側に位置する前記水路部材7mの、水田3aに面する側面部129の下端側に、例えば円形孔としての上流側開口10が設けられており、前記畦の水田側の部位に設けられた枡部材としての水路部材7pに連通する、例えば内径150〜200mm程度の塩化ビニール製パイプとして形成され且つ略水平に地下に埋設された水路部材7qの下流側の端部分130が挿入状態に接合されている。
【0092】
該枡部材としての水路部材7pは、前記魚道6の一構成要素であり、例えば図31〜32に示すように角筒状に構成され、パイプ状をなす前記最上流側に位置する水路部材7qの上流側の端部分131を挿入状態に接合するための下流側開口11が、前記魚道本体121に面する側面部132の下端側に設けられている。そして該枡部材(水路部材)7pの水田側は、全体が開口されており、該開口部133の対向側面135,135と底面136に、前記水田3aの水を嵩上げする堰板137を嵌め入れるための嵌入溝139が連続して設けられている。そして該堰板137は、図22に示す堰板におけると同様にして、堰板本体138に設けた矩形状切欠部138aの有する嵌入溝138bに落とし込み調整板138cの所要枚数を装着して構成されている。
【0093】
該魚類遡上構造1によるときは、前記排水路2から前記下側のパイプ状の水路部材7nに進入した魚類は、各U字溝状の水路部材7を、前記堰板23,23,23の越流切欠部30を通して遡上でき、最上流側に存するU字溝状の水路部材7mに至る。その後、上に位置するパイプ状の水路部材7q内に進入して前記枡部材(水路部材)7pに至り、該枡部材7pに設けられた前記堰板137の越流切欠部140を通して水田3aに至ることができる。
【0094】
なお、下に位置するパイプ状の水路部材7nの敷設高さは、該水路部材7n内への魚類の進入を容易とするために、該水路部材内が常時満水状態となるように設定するのがよい。なお前記上下のパイプ状水路部材7n,7qは、魚類の進入路として機能する他、例えば昼間において、魚類の避難場所としても機能し得る。
【0095】
なお、前記と同様に設けられる支持枠76や防止ネット77、紐状物67、濾過材117は、魚道の不要時期には取り外すことができる。
【0096】
なお、前記U字溝状の水路部材を、畦を横断するように接合して魚道本体を形成し、この魚道本体の下流端側にだけ、又は上流端側にだけ、パイプ状の水路部材を接合して魚道を構成する場合もある。
【0097】
図19、図33〜37は、本発明に係る魚類遡上構造1を構成する排水路2の他の態様を示すものであり、前記と同様構成のコ字状支持枠41を所要間隔を置いて並設すると共に、排水路2の長さ方向で隣り合う立上がり片42,42間で側板43を複数段に支持させ、複数段に支持された該側板43によって水路壁44を形成することとしている。そして、選択されたコ字状支持枠41の内面に設けられた挿入溝49に、例えばコンクリート製の隔壁50の両端の縁部分50a,50aを挿入させることにより、排水路2の水位を所要に嵩上げさせている。又該隔壁50の一方の端部側に、図34、図35に示すように、上端開放の矩形状切欠部140を設け、調整板141を、該矩形状切欠部140の例えば上流側の面において、上下方向にスライド可能に当接状態に設けることとし、該調整板141の上側に越流切欠部52を形成している。そして該越流切欠部52の周縁部分142が、下流側に向けて拡大するように面取りされている。なお該越流切欠部52の開口幅は例えば150mmと設定されると共に、深さは例えば180mmに設定されている。
【0098】
又図36に示すように、前記隔壁50の上流側の面に、前記矩形状切欠部140の両側に位置させて、上下3段に、前記調整板141を固定するためのインサート143,143,143、143,143,143を埋設している。
【0099】
該調整板141は、木製、樹脂製又は金属製等として形成されており、横長矩形板状を呈し、その両側に、上下方向に長い調節孔144,144が設けられている。図19、図34、図37は、上2段のインサート143,143、143,143にねじ込まれるボルト145を用いて、調整板141を隔壁50に固定した状態を示し、又図0は、下2段のインサート143,143、143,143にねじ込まれるボルト145を用いて、前記調整板141を隔壁50に固定した状態を示すものである。これらにおいて、排水路2における流水量に応じ、該調整板141の上端としての越流部54が下流側の水位に対して魚類が遡上可能な高さ(例えば50〜150mm程度の高さに設定され、該越流部54における越流水深は、例えば30〜50mm程度に設定される。なお流水量によっては、前記調整板を外して、矩形状切欠部140の下端を越流部54とすることもある。
【0100】
又本実施の形態においては、前記隔壁50の下端側において、前記矩形状切欠部140の下側(例えば、矩形状切欠部140の幅方向略中央)と、隔壁の他方の端部側に水抜き孔146,146を設けている。該水抜き孔146は、例えば、50〜100mmの直径を有する円形孔(図19、図34においては直径50mm程度の円形孔)として形成されており、排水路2の水路底147(図37)から、30〜50mm程度浮き上がるように設けられる。そして該水抜き孔146は、図38に示すように、嵌着やネジ込み等の手段によって、栓体148で閉塞可能となされている。
【0101】
前記矩形状切欠部140の下側に設けられた水抜き孔146a(図19、図34、図37)にあっては、これを開放して水を放出させることにより、前記越流切欠部52からの落水F1(図37)に加えて該水抜き孔146aからの水の放出F2(図37)が加わるため、それらの流れを感じて魚類が越流切欠部52に向けて誘導されやすくなる効果が期待できる。
【0102】
又、前記他端側の水抜き孔146b(図19)をも開放させる場合は、該水抜き孔146bからの水の排出による流れ作用によって、該水抜き孔146bの周辺において、流水の上側に比較的遅い流れ部分を形成できると共に下側に比較的速い流れ部分を形成でき、これらによって、澱みのある場所と流れのある場所を混在させることができ、魚類の生態環境に適した生育場所を形成できることになる。
【0103】
なお前記水抜き孔146は、前記スライド式の調整板141が最下降位置においても該調整板141で覆われることのないように設けられる。
【0104】
なお、排水路2における水嵩が予想外の降雨量によって異常に増した場合に、前記水抜き孔146を開放して放流させることにより、隔壁50を取り外さなくても、排水路2の水位を調整できる場合がある。このような目的のために、設ける水抜き孔の数を増やしたり、その径をより大きくすることもある。
【0105】
又、魚類や貝類が、前記水抜き孔146a,146bを通して隔壁50の反対側に移動できる効果もある。
【0106】
なお本実施の形態においては、図37に示すように、前記排水路2に適宜間隔で、産卵育成用の水草状紐体149を配置することとしている。該水草状紐体149は、図37に示すように、樹脂製の紐状体150の一端に、石やコンクリート隗等の重り151を設けると共に、その他端に、発泡スチロールや浮袋等の浮き152を設けてなる。該紐状物149は、直径が1〜3mm程度の紐片153の周面に、長さが50〜100mm程度の長さを有する毛片154を、放射状に多数設けた構成を有しており、その長さは、前記排水路2の水深に合わせて、例えば100〜130cm程度に設定される。かかる構成の水草状紐体149は、前記重り151を排水路2の水路底147に載せて、水路幅方向に適宜間隔で配設され、排水路2の底部分に水草が生えているような状態を形成するもので、魚類の産卵や育成の補助具として機能する。
【0107】
例えば図37に示すように、隔壁50に設けた越流切欠部52を通して下流側で落水した場合、該落水によって水路底が洗掘される場合が生ずる。そこで図39〜42においては、かかる洗掘を防止し得る機能を具えた洗掘防止ブロック156を用いて前記隔壁50を構成している。
【0108】
該洗掘防止ブロック156は、例えばプレキャストコンクリート製であり、図39、図42に示すように、前記排水路2の幅に略等しい幅を有し、且つ該排水路2の水の流れ方向に延長して設けられた底板157の上流側の端部に、隔壁50として機能する前板159を立設すると共に該底板157の下流側の端部に後板160を立設した、両側端が開放した構成を有しており、該後板160の高さは、その上端161が水路底147と略面一となるように設定されている。なお、該洗掘防止ブロック156の前記底板157の前後方向の長さは例えば820mmに設定されると共に、前板159の高さは例えば440mmに、又後板160の高さは例えば190mmに設定されており、前板159と後板160との間に、700mm程度の幅を有する空所163が形成されている。
【0109】
かかる構成の洗掘防止ブロック156は、隔壁50となる前記前板159が、排水路2を構成するコ字状支持枠41の下流側の面164に当接する状態で、下側部分165が排水路2の底部に埋設されて設置され、前記洗掘防止ブロック156の開放した両端166,166は、図42に示すように例えば側板167,167で塞がれ、或いは土嚢で塞がれる。そして、前記隔壁50となる前板159に、上端開放の矩形状切欠部(約150mmの開口幅を有する)169が設けられると共に、該矩形状切欠部169の両側において、上下3段にインサート170が埋設されている。そして、前記と同様に構成されたスライド式の調整板141の両側に上下方向で設けられた調整孔171,171を挿通するボルト172を所要のインサート170に捩じ込むことによって、該調整板141を前板159に固定可能となされている。これにより、該調整板141の上側に越流切欠部52を形成でき、前記と同様にして、魚類の遡上を可能とする越流部54を形成している。
【0110】
このように構成した場合は、前記隔壁(前板159)50の下流側に底板157が存するため、前記越流切欠部52を通して落水しても、水路底が該底板157で保護されていることから、水路底の洗掘を防止できる。又、越流切欠部52の下流側に、水路底がより掘り下げられた深み部172(図40)が形成されるため、前記越流切欠部52を魚類が遡上する際、その深みによって、勢いをつけて容易に遡上できる利点がある。
【0111】
加えて、該洗掘防止ブロック156の、前板159と後板160との間の前記空所163が泥溜めとなるため、前記魚道6を通して水田から排水路2に流入する等した、肥料成分等の有機物を含んだ微粒土を堆積させ、水質浄化を図り得ることともなる。
【0112】
なお、該洗掘防止ブロック156の前記空所163に、藁や籾殻等の濾過材173を収容することにより、排水路2における水質浄化効果を向上させることができる。又本実施の形態においても、前記と同様の機能を有する水抜き孔146を、矩形状切欠部169の例えば両側に設けている。又前記と同様にして、前記調整板141や前記矩形状切欠部169の周辺に、魚類誘導用の紐状物67を取り付けることができる。
【0113】
〔第2の実施の形態〕
図43〜45は、本発明に係る魚類遡上構造1の他の態様を示すもので、排水路2の水位と、水田3aとしての貯水池3の水位との間をなす畦部5に、該排水路2から貯水池3に向けて魚類を遡上させるための魚道6を形成するものであり、排水路2の水位と水田3aとしての貯水池3の水位間の落差が大きい場合に好都合に対応できる。今、畦部5の幅(図45にL1で示す)が約1900mmで且つ排水路2の水位と水田3aとしての貯水池3の水位間の落差(図44にL2で示す)が約900mmである場合を想定する。
【0114】
該水路部材7は、図46〜47に示すように、上端開放で且つ周方向の壁部180で閉じられ、その内部が水路9とされた有底の直方体箱状に構成され、平面視で、長辺長さが約1100mm、短辺長さが約600mm、上下高さが約860mmに設定されている。そして図47に示すように、一方の長辺側壁部180aの一方の短辺寄り部位に、上端から下端側に至る上下に長い、幅が約300mmで深さが約600mmの矩形状の下流側開口11が設けられると共に、他方の長辺側壁部180bの他方の短辺寄り部位には、図46に示すように、前記下流側開口11と同幅で且つその半分程度の深さを有する正方形状の上流側開口10が設けられている。
【0115】
そして該下流側開口11の対向する内側面181,181と底面182に、水路水を嵩上げする堰板23を嵌め込むための嵌入溝183が連続して設けられると共に、前記上流側開口10の対向する内側面185,185と底面186に、水路水を嵩上げする堰板23を嵌め入れるための嵌入溝187が連続して設けられている。又、両長辺側壁部180a,180bの中央部には、対向する内側面189,189と水路部材の底面190に、水路水を嵩上げする堰板23を嵌め入れるための中間の嵌入溝191が連続して設けられている。そして、前記各堰板23には、その上端中央部に、前記と同様の越流切欠部30が設けられている。
【0116】
そして図45に示すように、上流側に設置された水路部材7の前記下流側開口11が、下流側に設置された水路部材7の前記上流側開口10に連通されるように水路部材7,7相互が接合され、該上流側開口10と下流側開口11の連通部分において、いずれか一方の開口に設けた嵌入溝に、堰板23が嵌め入れられて、該堰板の上流側における水路水の嵩上げが行われている。
【0117】
然して、前記構成の水路部材7を用いて魚類遡上構造1を構成するには、図43〜45に示すように、排水路2と水田3aとの間をなす畦部5を掘削し、該掘削部で、上から順に3個の水路部材7E,7F,7Gを略水平状態にして、段違いに順次接合するのであるが、その際、図43に示すように最下流側に位置する水路部材7Gの前記下流側開口11を、前記と同様構成の排水路2の水路壁43に設けた開口38に連通させる。そして図48に示すように、該開口38の底面38aと前記下流側開口11の底面48を略面一状態にする。
【0118】
又図49に示すように、中段に位置する水路部材7Fの下流側開口11の底面48を、最下流側に設置された前記水路部材7Gの前記上流側開口10の底面192と略面一状態にする。
【0119】
又図50に示すように、最上流側に位置する水路部材7Eの前記下流側開口11の底面48を、中段に位置する水路部材7Fの上流側開口10の底面192と略面一状態にする。そして最上流側に設置された水路部材7Eの上流側開口10を前記水田3aに連通させる。なお、上下隣り合う水路部材7,7相互を例えば図45に示すアングル部材193を用いて連結する。図51は、魚道6の拡大斜視図である。
【0120】
そして図45に示すように、前記最下流側の水路部材7Gにおける下流側開口11に設けた嵌入溝183と前記中間の嵌入溝191、前記中段の水路部材7Fにおける下流側開口11に設けた嵌入溝183と該水路部材の中間の嵌入溝191、又、前記最上流側に設置された水路部材7Eにおける下流側開口11の嵌入溝183と該水路部材における中間の嵌入溝191、該水路部材における上流側開口10の嵌入溝187の夫々に堰板23を嵌め入れる。該堰板23には、前記と同様構成の越流切欠部30が設けられている。
【0121】
今説明の便宜上、図45及び図45のA−A断面図を示す図52、図51において、前記のように嵌め入れられた7枚の堰板を上から順に、第1堰板23E、第2堰板23F、第3堰板23G、第4堰板23H、第5堰板23I、第6堰板23J、第7堰板23Kという。又、前記第2〜7の堰板により嵩上げされた貯水を上から順に、第1貯水39E、第2貯水39F、第3貯水39G、第4貯水39H、第5貯水39I、第6貯水39Jといい、該貯水を溜める部分を、第1溜め部40E、第2溜め部40F、第3溜め部40G、第4溜め部40H、第5溜め部40I、第6溜め部40Jという。
【0122】
然して、かかる魚類遡上構造1によるときは、水田3aに供給された水の水位が前記第1堰板23Eで嵩上げされ、その越流切欠部30から前記第1溜め部40Eに流入する。又、第1溜め部40Eに流入した水は前記第2堰板23Fで嵩上げされてその越流切欠部30から第2溜め部40Fに流入する。同様にして、該第2溜め部40Fに流入した水は前記第3堰板23Gで嵩上げされてその越流切欠部30から第3溜め部40Gに流入し、該第3溜め部40Gに流入した水は前記第4堰板23Hで嵩上げされてその越流切欠部30から第4溜め部40Hに流入し、該第4溜め部40Hに流入した水は前記第5堰板23Iで嵩上げされてその越流切欠部30から第5溜め部40Iに流入し、該第5溜め部40Iに流入した水は前記第6堰板23Jで嵩上げされてその越流切欠部30から第6溜め部40Jに流入し、該第6溜め部40Jに流入した水は前記第7堰板23Kで嵩上げされてその越流切欠部30から前記排水路2内に流出する。そして図52においては、隣り合う貯水の水位間に、魚類が遡上可能な50〜150mm程度の水位差、例えば100mm程度の水位差を設けられ、又、水田3aの水位と第1貯水39Eの水位との間にも、同程度の水位差が設けられている。そして、前記した各越流切欠部30の下端としての越流部(越流水深は、例えば30〜50mm程度)24において、魚類が遡上できる。
【0123】
従って本発明に係る魚類遡上構造1によるときは、鮒や鯉、鯰等の魚類を、河川や湖等から排水路2に進入させ、前記隔壁50の越流切欠部52を遡上させて前記魚道6が存する場所に至らせることができる。その後、該魚道6を遡上させ得る。具体的には、水面が階段状である前記第6貯水39J、第5貯水39I、第4貯水39H、第3貯水39G、第2貯水39F、第1貯水39Eを、前記越流部24で順に遡上させて、水田3aに至らせ、水田で産卵させることができる。そして、各堰板23を取り外すことによって、水田の水を排水路2に円滑に排水できる。
【0124】
なお、前記堰板23の越流切欠部30の下流側を円弧面に形成し、又、堰板23に魚類誘導用の紐状物67を取り付ける構成は、前記実施の形態におけると同様である。そして、水路部材7の底部側に泥溜めを形成でき、これを前記実施の形態におけると同様に機能させ得る。
【0125】
前記堰板23は、排水路2の水位と水田3aの水位との落差や、畦部の幅に応じた適切な越流部24を形成できるようにするために、前記実施の形態におけると同様に構成するのがより好ましい。即ち、最上流側に位置する堰板23として、所要高さの落とし込み調整板86の所要枚数を装着溝92に順次に積み上げる構成の図22に示す第1の堰板23aを採用し、それ以外の堰板23として、図23に示すような、スライド調整板99を有する前記第2の堰板23bを採用するのがよい。
【0126】
〔第3の実施の形態〕
図53〜54は、本発明に係る魚類遡上構造1の水田3aと排水路2間をなす畦部5の幅(図54にL1で示す)が比較的小さいのに対して、排水路2の水位と水田3aとしての貯水池3の水位間の落差(図58にL2で示す)が比較的大きい場合に好都合に対応できる。該屈曲した魚道6は、円筒状をなす第1の水路部材7HとU字溝状をなす第2の水路部材7Iの2種類の水路部材を用い、これらの水路部材を所要に接合して形成するものである。今、畦部5の幅が約1700mmで且つ排水路2の水位と水田3aの水位間の落差が約580mmである場合を想定する。
【0127】
前記第1の水路部材7Hは、図55〜56に示すように、上端開放で且つ周方向の壁部180で閉じられた有底の円筒箱状に構成され、平面視で、内径が約900mmで上下高さが約720mmに形成されると共に、その壁部180の上流側部の所要部位と下流側部の所要部位に、上流側開口10と下流側開口11が設けられている。本実施の形態においては、該上流側開口10と下流側開口11は、上端が下端よりも稍拡大した上端開放の矩形状開口として形成され、該両開口10,11を通過する水の流れが略直角に屈曲するように設けられている。そして、該上流側開口10及び下流側開口11の上端幅は約610mmに形成されると共に、該上流側開口10の深さは約360mmに形成され、下流側開口11の深さはそれよりも稍深く、約560mmに形成されている。
【0128】
又前記第2の水路部材7Iは、図55、図57に示すように、U字溝状に構成されており、その水路の上流端部が上流側開口10とされると共に下流端部が下流側開口11とされている。又、水路内面の上流側部位と下流側部位に、その対向側面197,197と底面199に、水路水を嵩上げする堰板23を嵌め入れるための嵌入溝201,202が連続して設けられている。本実施の形態においては、その全長が約600mmに設定されると共にその水路深さが約500mmに設定されている。
【0129】
然して、該第1、第2の水路部材7H,7Iを用いて魚類遡上構造1を構成するには、図54〜55に示すように、前記畦部5を所要に掘削し、前記排水路2の延長方向に沿わせて上流側と下流側に、前記第1の水路部材7Hを配設する。そして、前記第1の水路部材7Hの下流側開口11に、下流側に略水平状態にして設置された前記第2の水路部材7Iの上流側部分203を、弾性止水材を介在させて嵌合状態に挿入すると共に、該第2の水路部材7Iの下流側開口11を、前記排水路2の水路壁44に設けた開口38に連通させる。
【0130】
又、隣り合う第1の水路部材7H,7H間を、U字溝としての前記第2の水路部材7Iで繋ぐのであるが、その際、該第2の水路部材7Iの下流側部分206を、下流側に設置された前記第1の水路部材7Hの上流側開口10に、弾性止水材を介在させて嵌合状態に挿入すると共に、該第2の水路部材7Iの上流側部分203を、上流側に設置された前記第1の水路部材7Hの下流側開口11に、弾性止水材を介在させて嵌合状態に挿入する。又、上流側に設置された第1の水路部材7Hの上流側開口10に、前記第2の水路部材7Iの下流側部分206を、同様に嵌合状態に挿入する。そして該第2の水路部材7Iの上流側開口10を水田3aに連通させる。
【0131】
又、前記第2の水路部材7Iの夫々において、その上流側の嵌入溝201と下流側の嵌入溝202に堰板23,23を着脱可能に嵌め入れる。これらの堰板23には越流切欠部30が設けられている。
【0132】
今説明の便宜上、図54及び図54のB−B断面図を示す図58、図55において、前記のように嵌め入れられた6枚の堰板を上から順に、第1堰板23L、第2堰板23M、第3堰板23N、第4堰板23P、第5堰板23Q、第6堰板23Rという。又、前記第2〜5の堰板により嵩上げされた貯水部を上から順に、第1貯水39L、第2貯水39M、第3貯水39N、第4貯水39P、第5貯水39Qといい、該貯水を溜める部分を第1溜め部40K、第2溜め部40L、第3溜め部40M、第4溜め部40N、第5溜め部40Pという。
【0133】
然して、かかる魚類遡上構造1によるときは、水田3aに供給された水の水位が前記第1堰板23Lで嵩上げされ、その越流切欠部30から前記第1溜め部40Kに流入する。又、該第1溜め部40Kに流入した水は前記第2堰板23Mで嵩上げされてその越流切欠部30から第2溜め部40Lに流入する。同様にして、該第2溜め部40Lに流入した水は前記第3堰板23Nで嵩上げされてその越流切欠部30から第3溜め部40Mに流入し、該第3溜め部40Mに流入した水は前記第4堰板23Pで嵩上げされてその越流切欠部30から第4溜め部40Nに流入し、第4溜め部40Nに流入した水は前記第5堰板23Qで嵩上げされてその越流切欠部30から第5溜め部40Pに流入し、最後に、第5溜め部40Pから前記排水路2内に流出する。そして図58においては、隣り合う水位間に、魚類が遡上可能な50〜150mm程度の水位差、例えば100mm程度の水位差を設けられている。そして、前記した各越流切欠部30の下端としての越流部(越流水深は、例えば30〜50mm程度)において、魚類が遡上できる。
【0134】
従って本発明に係る魚類遡上構造1によるときは、鮒や鯉、鯰等の魚類を、河川や湖等から排水路2に進入させ、前記隔壁50の越流切欠部52を遡上させて前記魚道6が存する場所に至らせることができる。その後、該魚道6を遡上させ得る。具体的には、水面が階段状である前記第5貯水39Q、第4貯水39P、第3貯水39N、第2貯水39M、第1貯水39Lを前記越流部24で順に遡上させて、水田3aに至らせ、水田で産卵させることができる。そして、各堰板23を取り外すことによって、水田の水を円滑に排水できる。
【0135】
なお、前記堰板23の越流切欠部30の下流側を円弧面に形成し、又、堰板23に魚類誘導用の紐状物67を取り付ける構成は、前記実施の形態におけると同様である。そして、水路部材7の底部側に泥溜めを形成でき、これを、前記実施の形態におけると同様に機能させ得る。
【0136】
前記堰板23は、排水路2の水位と水田3aの水位との落差や、畦部の幅に応じた適切な越流部24を形成できるようにするために、前記実施の形態におけると同様に構成するのがより好ましい。即ち、最上流側に位置する堰板23として、所要高さの落とし込み調整板86の所要枚数を装着溝92に順次積み上げる構成の図22に示す第1の堰板23aを採用し、それ以外の堰板23として、図23に示すような、スライド調整板99を有する前記第2の堰板23bを採用するのがよい。
【0137】
〔その他の実施の形態〕
本発明は、前記実施の形態で示したものに限定されるものでは決してなく、「特許請求の範囲」の記載内で種々の設計変更が可能であることはいうまでもない。その一例を挙げれば次のようである。
【0138】
(1) 本発明に係る魚類遡上構造は、前記した水田の他、休耕田を利用した養魚池、溜め池、親水公園の池等を含む、魚類の遡上を必要とする貯水池に対して応用できる。
【0139】
(2) 水路部材が前記したU字溝状に構成される場合、その水路内面の下流側部位に装着される堰板は、例えば図2に示すように下流端に装着されるとは限らず、それよりも稍上流側に装着される場合もある。
【0140】
(3) 図59は、U字溝状をなす水路部材7の他の態様を示すものであり、くの字状に屈曲した構成を有する。そして前記と同様にして接合部12と接合嵌合部13が設けられており、該接合部12が、下流側に設置された他の水路部材7A1の接合嵌合部13に嵌め入れられると共に、上流側に設置された他の水路部材7A2の接合部12が前記くの字状水路部材7の接合嵌合部13に嵌め入れられる。かかる構成のくの字状水路部材7は、例えば、畦部幅が比較的小さいのに対して排水路と水田間の水位差が比較的大きい場合に好都合に用い得る。
【0141】
(4) 水路部材7が、上端開放で且つ周方向の壁部180で閉じられた有底の箱状に構成される場合、その箱状の形態は、図51に示す直方体箱状や、図55に示す円筒箱状に構成されるものには限られない。
【0142】
(5) 水路部材7がU字溝状に構成される場合、その上流側開口10と下流側開口11間を仕切るように、水路水を嵩上げする中間の堰板23の一枚乃至複数枚が着脱可能に装着されることもある。
【0143】
(6) 水路部材7が、上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する場合、隣り合う貯水部の水位差を適正に設定するために、その水路に、上流側開口と下流側開口間を複数に仕切るように、水路水を嵩上げする中間の堰板の1枚乃至複数枚が着脱可能に装着されることもある。
例えば、水路部材7が図51に示すような直方体箱状に構成される場合、上流側開口10と下流側開口11間を複数に仕切るように、水路水を嵩上げする中間の堰板23の複数枚が着脱可能に装着されることもある。又、水路部材が図55に示すような有底の円筒箱状に構成される場合、上流側開口10と下流側開口11間を複数に仕切るように、水路水を嵩上げする中間の堰板の1枚乃至複数枚が着脱可能に装着されることもある
【0144】
(7) 水路部材7が有底の箱状に構成される場合、貯水池と排水路の水位差が比較的小さい場合は、中間の堰板23(例えば、図51に示す直方体箱状を呈する水路部材における中間堰板)を省略することもある。
【0145】
(8) 上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する水路部材の上流側開口10と下流側開口11は、例えば図55に示すように、該両開口10,11を通過する水の流れ方向が屈曲するように、前記壁部に設けるのが好ましいが、その屈曲状態は、畦部等の幅や、排水路と貯水池の水位差等を考慮して所要に設定され得る。
【0146】
(9) 水路部材7が有底の箱状に構成される場合、上流側開口10と下流側開口11の連通部分に、水路水を嵩上げする堰板を着脱可能に装着するとは、該上流側開口10の内面や下流側開口11の内面において装着される場合の他、上流側開口10の近傍部位や下流側開口11の近傍部位に装着される場合を含むものである。
【0147】
(10)堰板を嵌め入れるためのガイド部は、前記のように溝状に形成されることの他、該堰板を対向側で挟むように、間隔を置いた突部間で形成されてもよい。
【0148】
(11)最上流側に設置される水路部材における上流側部位に装着される堰板(例えば、図1に示す堰板231は省略されることもある
【0149】
(12)貯水池3と排水路2間に存する畦部等の幅が比較的小さいのに対して排水路と貯水池間の水位が比較的大きい場合は、魚道6が、図3に一点鎖線で示すように斜めに設けられることもある。
【0150】
(13)水路部材7がU字溝状に構成される場合、その上流側の水路底部15に突設される支持台17は、上流側に設置された水路部材の接合部の下面を下方から安定的に支持できるものであれば、該水路底部15の全幅に亘って設けられることは必ずしも必要ではない
又該支持台17は、図60〜61に示すように、水路部材7と別体に形成されて水路の底部15に接着等の手段で固定されることもある。更に該支持台17は、図62に示すように、例えば単位高さの支持台片207の複数を積み上げて所定の高さに構成されることもある。又支持台17が水路の底部15に一体に形成される場合、該支持台17の高さが低過ぎる場合は、図63に示すように、別体の補助支持台209を該支持台17に載せることにより、結果的に所要高さの支持台を構成することもある。
又図64は、水路の底部15に、水路長さ方向で見て前後に所要間隔を置いて複数の支持台17を突設した構成を示すものである。同図においては2個の支持台17a,17bを突設している。この場合、上流側に位置する支持台17aの高さを、下流側に位置する支持台17bの高さよりも低く設定する。このように構成すると、遡上する魚類の大きさに応じ、上流側に設置された水路部材の水位と下流側に設置された水路部材の水位との間に、魚類の遡上を可能とする所要水位差を設けることができる。遡上する魚類が大型であるときは、該水位差を大きく設定できるため、その場合は、高さのより高い支持台17bを選択して魚類遡上構造を構成できる。これにより、魚道6を構成する水路部材の使用個数を減じ得る経済性がある。
【0151】
(14)本発明に係る魚類遡上構造を構成する水路部材7は、前記した上端開放のものとして構成されることの他、例えば樹脂製等のパイプ状を呈するものとして構成されることもある。或いは、パイプ状を呈する水路部材と、上端が開放した水路部材との組み合わせで魚類遡上構造を構成することもある。
【0152】
(15)水路部材に堰板を着脱可能に装着する構成は、前記したような嵌入溝に堰板を嵌め入れ可能に構成することの他、水路水を嵩上げできるように着脱可能な各種の構成を採用できる。
【0153】
(16)又、前記堰板23には、前記のような越流切欠部30を設けない場合があるが、越流切欠部30を設ける場合は、該越流欠切部を堰板の幅方向中央部に設けるものには限られない。例えば図65に示すように、該越流切欠部30を堰板23の端に寄せ、上下方向で並設された堰板の有する越流切欠部が千鳥配置となるように設けることもある。このように構成するときは、魚道における水の流れを蛇行させて、魚類が遊泳できる淀み部分210を形成できることとなる。なお図65においては、説明の便宜上、越流切欠部30に斜線を付している。
【0154】
(17)前記越流水深は、魚類の遡上状態に応じて設定されるものであり、30〜50mmの越流水深を確保できるように構成すれば、各種魚類に応じた必要な越流水深を確保できる。
【0155】
(18)前記水路部材に装着される堰板に設けた越流部の下流側を面取りする場合、前記した何れの実施の形態においても、該面取りは、傾斜面としての他、円弧面として形成できる。
このことは、該越流部を、前記堰板に設けた矩形状欠切部の下側部分を覆うように設けられるスライド調整板の上端として形成する場合も同様であり、このように構成する場合は、該欠切部の縁部分を、下流側に向けて拡大するように面取り(傾斜面や円弧面等の面取り)するのがよい。
【0156】
(19)前記隔壁に設けた越流部の下流側を面取りする場合、前記した何れの実施の形態においても、該面取りは、傾斜面としての他、円弧面としても形成できる。
このことは、該越流部を、前記隔壁に設けた矩形状欠切部の下側部分を覆うように設けられるスライド式の調整板の上端として形成する場合も同様であり、このように構成する場合は、欠切部の縁部分を、下流側に向けて拡大するように面取り(傾斜面を円弧面等の面取り)するのがよい。
【0157】
(20)前記堰板や隔壁に欠切部を設け、該欠切部にスライド調整板やスライド式の調整板を付設して所要の越流部を構成する場合、該欠切部は、前記した矩形状欠切部には限られず、台形状やV字状、円弧状等を呈する欠切部としても形成できる。
【0158】
(21)前記堰板にスライド調整板を高さ調整可能に設けたり、前記隔壁に調整板を高さ調整可能に設ける手段は、前記のように、スライド調整板やスライド式の調整板の両側に設けた上下に長い調整孔にボルトを挿通させ、該ボルトをインサートに螺合して行う手段の他、公知の各種調整手段を用いて行うことができる。
【0159】
(22)前記洗掘防止ブロックは、前記実施の形態においては、開放した両端を側板や土嚢で覆うように構成しているが、底板と一体に設けた側板で該両端を閉じるように構成してもよい。
【0160】
(23)前記排水路は、前記コ字状枠を用いて組み立てるものの他、公知の各種構造のものを採用できる。
【0161】
(24)U字溝状の水路部材を接合して構成した魚道本体の上下にパイプ状の水路部材を接合して構成する図27に示す魚類遡上構造の考え方は、有底の箱状を呈する水路部材を用いて構成する前記第2、第3の実施の形態に係る魚類遡上構造にも応用できる。
【0162】
(25)魚道本体121にパイプ状の水路部材7を接合して魚道6を構成する場合、該パイプ状の水路部材7の上端を地表に一部露出させる場合もある。図66は、その一例を示すものであり、該パイプ状の水路部材7を、例えばU字溝状をなす上端開放の水路部材本体220と、その上端開放部221を着脱可能に閉蓋し得る蓋板222を以って構成し、該蓋板222の閉蓋によってパイプ状の水路部材7を形成している。この場合、図66に示すように、前記水路部材本体220を地下埋設状態とし、前記蓋板222を地表に露出状態とすることにより、必要時に該蓋板222を取り外すことによって、パイプ状の水路部材7の内部を点検したり清掃することができる。
【0163】
(26)前記隔壁50は、図1に示すように、コ字状支持枠41の内面に設けられた挿入溝49に両端の縁部分を挿入して該コ字状支持枠41に着脱可能に装着されることの他、該コ字状支持枠41の上流側の側面にネジ止めされることもある。
【0164】
(27)前記排水路2に、前記洗掘防止ブロック156を配設する場合、該洗掘防止ブロックの底板157は、越流部54を通しての落水によって排水路の水路底の洗掘を防止できる限り、該越流部54の下流側の近傍部分にのみ設けることがある。
【0165】
(28)前記魚道6の上側を覆う防止ネット77は、透明な塩化ビニルシート等の透明被覆材に変更されることもある。この透明被覆材は、魚道における魚類の遡上を可能とする限り、有色透明の被覆材であってもよい。
【0166】
【発明の効果】
本発明は以下の如き優れた効果を奏する
(1) 本発明に係る魚類遡上構造は、排水路と、該排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を含んで構成されており、該魚道を、水路部材の複数を順次接合して構成することとし、各水路部材に堰板を着脱可能に装着する構成を採用し、又、該堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定する構成を採用している。
従って発明によるときは、貯水池と排水路との間の平面視で見た幅(畦部等の幅)と、排水路の水位と貯水池の水位との間の落差に応じて、必要個数の水路部材を直線状態や所要の屈曲状態で順次接合し、該水路部材に装着した堰板の越流部の高さと該越流部における越流水深を所要に設定して魚道を形成することにより、魚類を、前記排水路に必要に応じて設けた隔壁の越流部を順次遡上させて、前記魚道が存在する場所にまで至らせることができ、その後、排水路から貯水池に魚類を無理なく遡上させ得ることとなる
排水路と貯水池との間に魚道を形成する前記従来システムにあっては、夫々の施工現場に合わせて、現場打ち施工を主体に構成するものであったため、その施工に多くの手間を要して施工能率が悪く、施工コストの上昇を招く問題があった他、工期が長引く問題があった。特に、落差が大きい場合に該魚道を屈曲状態に形成せんとするときは、現場打ち施工が非常に複雑となって施工性が悪化し、又、施工コストの一層の上昇を招く等の問題を発生させた。又、排水路から貯水池に亘る長さを有する一体成形されたコンクリート製の魚道ブロックを用いて魚道を形成せんとするときは、該魚道ブロックを、施工現場に応じた長さに個別的に設計、製造しなければならず、施工コストが大幅に上昇する問題があった他、該コンクリート製の魚道ブロックは重量が大きくなり、施工現場への搬送が容易でなく、又施工性を悪化させる問題もあった。
これに対して、水路部材の複数を順次接合して、換言すれば、必要個数の水路部材を順次接合して魚道を構成する本発明によるときは、かかる問題点を一挙に解消できる。
又前記堰板は着脱可能であるため、堰板の全てを取り外すことによって、貯水池の水を排水路に円滑に排出させ得ると共に、魚道の掃除も容易である。
【0167】
(2) 水路部材に装着する前記堰板の上端部に、台形状やU字状、矩形状、V字状等を呈する越流切欠部を設ける場合は、魚道を流れる水の量が多くないときも、該越流切欠部において、魚類の遡上を可能とする所要水深を確保できることになる。
【0168】
(3) 水路部材に設けた上流側開口と下流側開口間を仕切るように、水路水を嵩上げする中間の堰板を水路部材に着脱可能に装着するときは、水路に、中間堰板によって水位差を形成することが可能となるため、排水路と貯水池との落差が大きい場合に、水路部材の使用個数を増すことなく、適切な水位差を有した魚道を経済的に形成できることになる。
該中間の堰板を、所要間隔を置いて複数装着するときは、水路部材の水路を更に区画でき、中間堰板間にも所要の水位差を形成できることになる。
【0169】
(4) 上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する水路部材を用いる場合において、その上流側開口と下流側開口を、該両開口を通過する水の流れ方向が屈曲するように前記壁部に設けるときは、該上流側開口及び下流側開口に他の水路部材の端部分を挿入状態とすることにより、畦部等の幅や、貯水池の水位と排水路の水位との間の落差に応じた適切な屈曲魚道を合理的に構成できることになる。例えば、畦部等の幅が小さくて落差が大きい場合、直線状の魚道では対処できなくても、魚道を屈曲させることにより対処できる利点がある。
【0170】
(5) 水路部材の複数を順次接合して構成した魚道本体の、最下流側に位置する水路部材に、排水路に連通され且つ地下埋設されたパイプ状の水路部材を接合する一方、最上流側に位置する水路部材に、水田に結果的に連通されるパイプ状の水路部材の端部を接合する構成を採用する場合は、畦の天端や、畦の法面下端と排水路との間をなす畦道に、一輪車等を障害なく走行させて、農作業の容易化を達成できる利点がある。
又このような構成は、畦部の幅が比較的小さく、排水路の水位と貯水池の水位との間の落差が大きい場合にも、該落差に応じて適切な越流部と越流水深を有する魚道を合理的に構成できる。更にかかるパイプ状の水路部材は、例えば昼間において、魚類の避難場所としても機能させ得る。
【0171】
(6) 上端開放で周方向の壁部で閉じられた有底の箱状をなす水路部材を、上端開放の有底の円筒箱状に構成する場合は、例えば直方体箱状を呈する場合とは異なり、壁部に上流側開口と下流側開口を設ける際の位置的制約が少ないため、両開口を通過する水の流れ方向が屈曲するようになすとき、上流側開口と下流側開口を、その屈曲角度に合わせて容易に形成できる利点がある。
【0172】
(7) 前記水路部材を、上端が開放したU字溝状に形成し、その上流側部分の水路幅を拡大して、水路部材の下流側部分をなす接合部を嵌め入れるための接合嵌合部とし、又、該水路部材の上流側部分の水路の底部に、前記接合部の下面を下方から支持する支持台を突設する構成を採用したときは、以下の如き特別の効果を奏する。即ち、
【0173】
▲1▼ 前記支持台によって、水路の底部側に淀み場が形成されることになり、そこを、底生生物の生息場となし得る。
【0174】
▲2▼ 又、前記支持台によって形成された水路の底部側が泥溜めとなり、魚道を流れる汚泥等の微粒土を堆積させ得る。これによって、肥料成分等の有機物を沈殿させることができる。又、堆積土から水草等が生えることによって、水路水中の有機物が捕捉され、水質浄化が図られることにもなる。かかることから、有機物による河川の汚染防止に寄与できる。
【0175】
▲3▼ 前記接合嵌合部内に挿入された接合部の下側に空隙部を形成でき、この空隙部を、陰を好む底生生物の生息場所となし得、又、稚魚の避難場所ともなし得る。特に、この空隙部の表面側を自然石が露出した面とすることにより、藻類の繁殖を助けて底生生物の良好な餌場となし得る。
【0176】
▲4▼ 前記支持台が接合部の下面を下方から支持できるため、支持台を定規にして、隣り合う水路部材相互を、所要段差で敷設することが容易となる。
【0177】
(8) 前記支持台を水路部材と別体に構成し、該支持台を水路部材に後付けする構成を採用したときは、所要高さの支持台を水路部材に固定することにより、隣り合う水路部材の敷設段差を所要に調節できる利点がある。又、支持台高さの異なる水路部材を一体に形成する場合よりも、水路部材の製造コストの低減を期し得る。
【0178】
(9) 支持台を水路部材と一体に形成した場合に、補助支持台を積重して所要高さの支持台を構成したり、水路部材とは別体の支持台を水路部材に後付けしたり、複数個の支持台片を積み重ねて支持台を形成するときは、次のような効果を奏し得る。即ち、魚道を遡上する魚類が大型であるときは、該補助支持台の積重等によって支持台の高さを結果的に高くすることにより、隣り合う水路部材の敷設段差を大きくでき、従って、水路部材の使用個数を減じて魚類遡上構造を経済的に構成できることとなる。
例えば、排水路と貯水池の落差が約600mm程度ある場合、前記水路部材の下面と前記支持台の上面間の距離が150mmであれば、水路部材を4段に設置して対処しなければならないのに対し、この距離が200mmであれば、3段の水路部材で対処できることとなる。
【0179】
(10)更に、このように支持台を設ける場合、該支持台を、水路の長さ方向の前後に設け、上流側に位置する支持台を、下流側に位置する支持台よりも低く構成するときは、支持台の選択によって、隣り合う水路部材の敷設段差を変更できる利点がある。
【0180】
(11)前記水路部材の底面部を、更には側面部を、自然石が露出した面に形成することにより、該自然石面に藻類を繁殖させることが可能になり、水路の内面部を、小魚類や底生生物の餌場ともなし得る。
【0181】
(12)前記堰板を、欠切部が設けられた堰板本体と、該欠切部の下側部分を覆うように付設されたスライド調整板とにより構成する場合は、該スライド調整板の上下方向の高さ調節により、該スライド調整板の上端としての越流部の高さを、貯水池の水位と排水路の水位との間の落差に応じて、下流側の水位に対して魚類が遡上可能な適切な高さに設定することが容易である。
前記堰板として、例えば図4に示すように、欠切部が設けられた板体のみを以って形成する場合は、カッター等でカットして欠切部の深さを深くする等の現場調整が必要となるのであるが、スライド調整板を用いる場合は、このような面倒な調整を何ら要さず、越流部の高さ調整を簡易且つ確実に行い得る利点がある。
【0182】
(13)水路部材をU字溝状に構成する場合において、下流側部位に着脱可能に装着される堰板を、その下流側の面が水路部材の下端面と面一に形成する場合は、魚道を遡上する魚類が水路部材の下端の角部分に引っ掛かって傷つくのを防止できる。
【0183】
(14)排水路に着脱可能に装着する隔壁を、欠切部が設けられた隔壁本体と、該欠切部の下側部分を覆うように付設されるスライド式の調整板とにより構成する場合も、排水路の水嵩に応じて、魚類の遡上を可能とする越流部の高さを簡易且つ確実に調整できる利点がある。
【0184】
(15)排水路に装着される堰板に、その越流部の下側に位置させて水抜き孔を設ける場合は、該水抜き孔を開放して水を放出させることにより、越流部における落水に加えて水抜き孔からの水の放出が加わるため、それらの流れを感じて魚類が越流部(越流欠切部)に向けて誘導されやすくなる効果を期待できる。
【0185】
(16)排水路に設ける隔壁を、底板の前後に前板と後板を立設してなる洗掘防止ブロックの該前板を以って構成する場合は、越流部(越流欠切部)を通して落水しても、排水路の水路底が該底板で保護されていることから、水路底の洗掘を防止できる。又、越流欠切部の下流側に、水路底がより掘下げられた深み部が形成されるため、越流欠切部を魚類が遡上する際、その深みによって、勢いを付けて容易に遡上できる利点がある。更に、該洗掘防止ブロックの前板と後板との間をなす空所が泥溜めとなるため、魚道を通して水田から排水路に流入する等した、肥料成分等の有機物を含んだ微粒土を堆積させ、水質浄化を図り得ることとなる。この場合、前記空所に、藁や籾殻等の濾化材を収容することにより、排水路における水質浄化効果を向上させることができる。
【0186】
(17)特に、魚道の下流側に洗掘防止ブロックを設置し、前記空所に濾過材を収容する構成を採用した場合は、前記魚道を通して水田から排水路に流入した肥料成分等の有機物を含んだ微粒土を、該濾過材で濾過でき、それだけ排水路の水質浄化を図り得る利点がある。
【0187】
(18)魚道の上側を、図16に示すように防止ネットや透明被覆材で覆う場合は、魚道を遡上する魚類が魚道の外に飛び出すのを防止できると共に、遡上中に魚類が鳥類に捕食されるのを防止できる。
【0188】
(19)前記堰板の越流部の下流側を円弧面に形成し、或いは該下流側の部分を、13〜60度の角度で下方に傾斜する傾斜面に形成した場合は、該欠切部を遡上する魚類が該越流部の角部分に引っ掛かって傷つくのを防止できる。この場合、傾斜面の傾斜角度を35〜45度に設定することにより、このような引っ掛かりをより効果的に防止できる。
このことは、堰板に設けた欠切部をスライド調整板で覆う場合において、該欠切部の下流側の縁部分及びスライド調整板の上端としての越流部の下流側の部分を、前記と同様の円弧面や傾斜面に形成した場合も同様である。
更に、これらのことは、排水路に隔壁を設ける場合において、該隔壁の上端をなす越流部の下流側の部分を同様に形成し、又、該隔壁に欠切部を設け、該欠切部の下側部分をスライド式の調整板で覆う場合において、該調整板の上端をなす越流部の下流側の部分や欠切部の下流側の縁部分を、前記と同様に円弧面や傾斜面に形成した場合も同様である。
【0189】
(20)前記堰板に、魚道を流れる水に漂う魚類誘導用の紐状物の上端側を取り付ける場合は、魚道を遡上する魚類を、越流欠切部に効果的に誘導できる利点がある。
【0190】
(21)又、排水路の底部に、その幅方向に適宜間隔で水草状紐体を配置する場合は、排水路の底部分に水草が生えているような状態を形成でき、該水草状紐体を、魚類の産卵や育成の補助具として機能させ得る。
【図面の簡単な説明】
【図1】本発明に係る魚類遡上構造を示す全体斜視図である。
【図2】その断面図である。
【図3】その平面図である。
【図4】それに用いる水路部材を堰板と共に示す斜視図である。
【図5】その水路部材を示す斜視図である。
【図6】その水路部材を示す平面図である。
【図7】水路部材相互の接合状態を示す断面図である。
【図8】堰板の構成を越流状態と共に示す断面図である。
【図9】形成された魚道の作用を説明する斜視図である。
【図10】形成された魚道の作用を説明する断面図である。
【図11】排水路の構成を説明する部分斜視図である。
【図12】排水路のその他の構成を説明する部分斜視図である。
【図13】魚類誘導用の紐状物をその使用状態で示す断面図である。
【図14】魚類誘導用の紐状物を示す斜視図である。
【図15】魚道の堰板を取り外して水田の水を排水路に排水する状態を示す斜視図である。
【図16】魚道を防止ネットで覆った状態を示す斜視図である。
【図17】水路部材と、防止ネットを支持する支持枠を示す斜視図である。
【図18】支持枠を水路部材に取り付けた状態を示す断面図である。
【図19】本発明に係る魚類遡上構造の他の態様を作用と共に示す断面図である。
【図20】最上流側の水路部材と中間の水路部材の接合状態を示す断面図である。
【図21】水路部材と、これに装着される堰板を示す斜視図である。
【図22】最上流側の水路部材の上流端側の堰板を示す分解斜視図である。
【図23】水路部材の下流側に装着される堰板を示す分解斜視図である。
【図24】水路部材の下流側に装着された堰板における、スライド調整板の高さ調整状態の一例を示す斜視図である。
【図25】水路部材の下流側に装着された堰板における、スライド調整板の高さ調整状態の他の例を示す斜視図である。
【図26】スライド調整板が取り外された堰板の装着状態を示す断面図である。
【図27】本発明に係る魚類遡上構造の他の態様を示す平面図である。
【図28】その断面図である。
【図29】その魚類遡上構造における、最下流側の水路部材と排水路との接合状態を示す断面図である。
【図30】その魚類遡上構造における最下流側の構成を説明する斜視図である。
【図31】その魚類遡上構造における最上流側の構成を説明する断面図である。
【図32】その魚類遡上構造における最上流側の構成その斜視図である。
【図33】排水路に隔壁が装着された魚類遡上構造を示す平面図である。
【図34】その魚類遡上構造における隔壁の越流部分を上流側から見た斜視図である。
【図35】その魚類遡上構造における隔壁の越流部分を下流側から見た斜視図である。
【図36】その魚類遡上構造における隔壁の越流部分を分解して示す斜視図である。
【図37】排水路の底部に水草状の紐体を配置した状態を示す断面図である。
【図38】排水路の隔壁に設けた水抜孔を閉じた状態を示す断面図である。
【図39】洗掘防止ブロックを用いて排水路の隔壁を構成した状態を示す斜視図である。
【図40】その断面図である。
【図41】その正面図である。
【図42】その平面図である。
【図43】本発明に係る魚類遡上構造のその他の態様を説明する全体斜視図である。
【図44】その断面図である。
【図45】その平面図である。
【図46】それに用いる水路部材を堰板と共に示す斜視図である。
【図47】それに用いる水路部材を堰板と共に示す斜視図である。
【図48】最下流側に設置された水路部材と排水路の連通状態を示す断面図である。
【図49】中間の水路部材と最下流側の水路部材との接合状態を示す断面図である。
【図50】最上流側の水路部材と中間の水路部材との接合状態を示す断面図である。
【図51】形成された魚道を説明する斜視図である。
【図52】形成された魚道の使用状態を示す断面図である。
【図53】本発明に係る魚道遡上構造のその他の態様を示す全体斜視図である。
【図54】その平面図である。
【図55】形成された魚道を示す斜視図である。
【図56】それを構成する水路部材を示す斜視図である。
【図57】それを構成する水路部材を堰板と共に示す斜視図である。
【図58】形成された魚道の使用状態を示す断面図である。
【図59】コ字状水路部材をその使用状態で示す平面図である。
【図60】水路部材のその他の態様を示す分解斜視図である。
【図61】その部分断面図である。
【図62】水路部材のその他の態様を示す部分断面図である。
【図63】水路部材のその他の態様を示す部分断面図である。
【図64】水路部材のその他の態様を示す部分断面図である。
【図65】越流欠切部を千鳥状に配置した魚道を示す部分平面図である。
【図66】パイプ状水路部材の他の態様を示す断面図である。
【図67】従来の魚類遡上構造を示す斜視図である。
【符号の説明】
1 魚類遡上構造
2 用排水路
3 貯水池
5 畦部
6 魚道
7 水路部材
9 水路
10 上流側開口
11 下流側開口
12 接合部
13 接合嵌合部
17 支持台
23 堰板
24 越流部
25 嵌入溝
29 嵌入溝
30 越流欠切部
50 隔壁
52 越流欠切部
54 越流部
67 紐状物
76 支持枠
77 防止ネット
85 堰板本体
86 落とし込み調整板
87 矩形状欠切部
92 装着溝
95 傾斜面
97 堰板本体
99 スライド調整板
111 インサート
112 ボルト
113 調整孔
143 インサート
144 調整孔
146 水抜き孔
147 水路底
150 紐状体
151 重り
152 浮き
153 紐片
154 毛片
156 洗掘防止ブロック
157 底板
159 前板
160 後板
169 矩形状欠切部
170 インサート
172 ボルト
180 壁部
187 嵌入溝
191 嵌入溝
201 嵌入溝
202 嵌入溝
[0001]
BACKGROUND OF THE INVENTION
The present invention is provided between a drainage channel and a reservoir such as a paddy field, a fallow paddy field, a reservoir, a pond in a water park, etc. having a higher water level, and allows fish to be able to run up to the reservoir without difficulty. The present invention relates to a fish upstream structure to a reservoir, and also relates to a water channel member constituting the fish upstream structure.
[0002]
[Prior art]
In recent years, it has been possible to catch fish such as cormorants, cormorants, corals, etc., in reservoirs such as paddy fields and fallow fields, and by using paddy fields as a place for spawning breeding and breeding of fish, we must achieve ecosystem conservation An attempt has been made. One of the present applicants has also proposed a fish run-up system to a freshwater reservoir in Japanese Patent Application Laid-Open No. 2000-120052.
[0003]
As shown in FIG. 67, the fishway constituting the run-up system has a floor e where the fresh water reservoir side a is lower than the water level of the fresh water reservoir b and the water channel side c is lower than the water level of the water channel d. A space g formed by a side wall f that rises upward from both sides of the floor portion e and forms a water passage that connects the fresh water reservoir b and the water channel d, and the floor portion e and the side walls f and f. And a partition wall j provided with an overflow portion h that separates the upstream side and the downstream side and overflows the water on the upstream side.
[0004]
As described in the specification of the application, the upstream system is designed so that the overflow section of each partition wall is at a height that allows fish to run upstream relative to the downstream water level, and the water level of the freshwater reservoir is adjusted. Since the fish was moved up from the waterway side to the freshwater storage pond side, the fish could be easily moved up from the waterway side to the freshwater storage pond side. The biological conservation function was improved, and the biotope was able to inhabit various organisms.
[0005]
[Patent Document 1]
JP 2000-120052 (page 4-7, FIG. 3)
[0006]
[Non-Patent Document 1]
“Eco-friendly construction method for agricultural drainage channels”, Shiga Prefectural Agriculture, Forestry and Civil Engineering Products Association, December 21, 2001, p. 2-6
[0007]
[Problems to be solved by the invention]
However, when using the run-up system, the floor of the fishway and the side walls rising from both sides of the floor were formed in series to connect the waterway and the freshwater reservoir. There was a problem that not only increased the construction cost and required a lot of labor for individual construction according to the width and head of the buttocks etc., but also the construction cost was prolonged. Furthermore, when using a series of constructed fishways, it is difficult to construct a bent fishway, so if there is a large drop between the waterway and the freshwater reservoir, the construction is not easy even if the bent fishway responds to this. There was also a problem.
[0008]
In addition, when the floor portion e and the side walls f and f rising from both sides of the floor portion e are configured as an integral U-shaped groove block, a block having a predetermined length according to the construction site must be individually designed and manufactured. In other words, the formwork will soar and the manufacturing cost will increase significantly. In addition, the long U-shaped groove-shaped block increases in weight and is not easily transported to the construction site, and also causes a problem of degrading workability.
[0009]
The present invention has been developed mainly in view of such problems, and allows the fish to easily run up from a low water level drainage channel to a high water level reservoir, as well as the water level of the drainage channel and the reservoir. The objective is to provide a fish run-up structure to the reservoir, which can easily form an appropriate fishway according to the level of the difference between the water levels in the water level, and can improve the construction efficiency and reduce the construction cost.
[0010]
Another challenge is to provide a fish upstream structure that can appropriately adjust the height of the overflow section that allows fish to run up according to the construction site. The objective is to provide a fish-up structure that is easy to induce. In addition, an object of the present invention is to provide a water channel member that can rationally configure such a fishway.
[0011]
[Means for Solving the Problems]
In order to solve the above problems, the present invention employs the following means.
That is, the fish run-up structure according to the present invention includes a drainage channel and a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel, and the fishway is sequentially joined to a plurality of channel members. A fish upstream structure to a reservoir constructed as described above, wherein the water channel member has an upstream side opening and a downstream side opening on the upstream side and downstream side of the water channel, and the water channel installed on the upstream side The water channel members are joined together so that the downstream opening of the member communicates with the upstream opening of the water channel member installed on the downstream side, and the upstream opening of the water channel member installed on the most upstream side is A downstream opening of the water channel member that communicates with the reservoir and is installed on the most downstream side communicates with the drainage channel. In addition, a dam plate for raising the channel water is detachably attached to the downstream side portion of the water channel of the water channel member, and the overflow portion of the dam plate is high enough to allow fish to run up to the downstream water level. It is characterized by having been set to this.
[0012]
In the fish run-up structure, the water channel member is formed in a U-shaped groove shape having a continuous water channel that is open at the upper end and extends from the upstream end to the downstream end, and expands the width of the water channel on the upstream side. A joint fitting portion for fitting the joint portion forming the downstream side of the member, and in a state where the joint portion is fitted in the joint fitting portion, the water channel member with respect to the joint fitting portion of the joint portion It is possible to adjust the amount of insertion seen in the length direction, and in the downstream part of the water channel of the water channel member, a guide part for detachably fitting the barrier plate is provided, and the water channel member installed on the upstream side It is preferable that the joint portion is fitted into the joint fitting portion of a water channel member installed on the downstream side, and the weir plate is fitted into the guide portion.
[0013]
In the fish run-up structure, it is preferable that a support base for supporting the lower surface of the joint portion of the water channel member installed on the upstream side from below is projected from the bottom of the water channel on the upstream side of the water channel member.
[0014]
A more preferable aspect of the fish run-up structure according to the present invention includes a drainage channel and a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel, and the fishway includes a plurality of channel members. In the fish upstream structure to the reservoir constructed by sequentially joining, the water channel member is formed in a U-shaped groove shape having a continuous water channel from the upstream end to the downstream end with the upper end open, The upstream channel width is enlarged, and a joint fitting portion for fitting a joint portion on the downstream side of the channel member is formed. In addition, a fitting groove for detachably fitting a weir plate for raising the water channel water is provided on the opposite side surface and bottom surface of the downstream portion of the water channel member of the water channel member, and the water channel in the upstream portion of the water channel member A support base for supporting the lower surface of the joint portion of the water channel member installed on the upstream side from below is protruded from the bottom of the water channel member, and the reservoir is provided on the opposite side surface and bottom surface of the upstream portion of the water channel of the water channel member. An insertion groove for detachably inserting a weir plate for raising the water is provided. In addition, the joint portion of the water channel member installed on the upstream side can be fitted into the joint fitting portion of the water channel member installed on the downstream side in a state where the joint portion is placed on the support base. An upstream opening of the water channel member installed on the upstream side is communicated with the reservoir, and a downstream opening of the water channel member installed on the most downstream side is communicated with the drainage channel. In addition, the overflow portion of the weir plate fitted in each of the insertion grooves is set to a height at which fish can run up with respect to the downstream water level.
[0015]
In the fish run-up structure having a support base, the support base protrudes from the bottom of the water channel in the upstream portion of the water channel member with a required interval in the longitudinal direction of the water channel, and further upstream. It is good to set the support stand located in the height lower than the support stand located on the downstream side thereof.
[0016]
In the fish run-up structure having a support base, the support base may be formed separately from the water channel member, and the support base may be retrofitted to the water channel member. The support base to be retrofitted may be configured by stacking support base pieces having a required height in a plurality of stages.
[0017]
When the water channel member is formed in a U-shaped groove shape, when the dam plate is detachably fitted into the downstream side portion of the water channel of the water channel member, the downstream end side of the outer peripheral surface of the dam plate is the downstream end of the water channel It is good to comprise so that it may contact | abut to the inner peripheral surface of this, and the surface of the downstream side of this dam plate may become flush | level with the downstream end surface of the said channel member.
[0018]
Another aspect of the fish run-up structure according to the present invention includes a drainage channel and a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel. A fish upstream structure to a reservoir constructed by sequentially joining the water channel members, wherein the water channel member is formed in a bottomed box shape having an open upper end and closed by a circumferential wall portion, and the wall portion The upstream side opening and the downstream side opening are provided in the required site on the upstream side and the required site on the downstream side, and the downstream side opening of the water channel member installed on the upstream side is installed on the downstream side. The water channel members are joined to each other so as to communicate with the upstream opening of the water channel member, and a dam plate for raising the water of the water channel is detachably attached to a communicating portion of the both openings. The upstream opening of the water channel member installed on the most upstream side communicates with the reservoir, and the downstream opening of the water channel member installed on the most downstream side communicates with the drainage channel, and the weir The overflow part of the board is set to a height at which fish can run up with respect to the downstream water level.
[0019]
In the fish run-up structure, a downstream portion of the water channel member installed on the upstream side in the upstream opening of the water channel member having a bottomed box shape with an open upper end and closed by a circumferential wall portion The insertion amount can be adjusted, and the upstream portion of the water channel member installed downstream is inserted into the downstream opening of the water channel member so that the insertion amount can be adjusted. Is good.
[0020]
In the fish run-up structure comprising the water channel member having a bottomed box shape that is open at the top and closed by a circumferential wall, the water channel of the water channel member is provided between the upstream opening and the downstream opening. In order to divide the water, the middle dam that raises the channel water is detachably mounted, and the overflow part of the middle dam is set to a height that allows fish to run up to the downstream water level. It is good.
[0021]
In the fish run-up structure comprising the water channel member having a bottomed box shape that is open at the top and closed by a circumferential wall, the water channel of the water channel member is provided between the upstream opening and the downstream opening. It is possible to detachably attach a plurality of intermediate dam plates that raise the channel water so that the fish can run upstream from the water level on the downstream side. It is better to set the height.
[0022]
In each fish run-up structure including the channel member having a bottomed box shape with an open upper end and closed by a circumferential wall, the upstream side opening and the downstream side opening of the channel member are both It is good to provide in the said wall part so that the flow direction of the water which passes an opening may be bent.
[0023]
In each fish run-up structure, it is preferable that the downstream side of the overflow section is formed as an arc surface. Moreover, in each said fish upstream structure, it is good to form the downstream of the said overflow part in the inclined surface which inclines below at an angle of 13-60 degrees.
[0024]
Another aspect of the fish run-up structure according to the present invention is a fish run-up structure including a drainage channel and a fishway for allowing fish to run up to a paddy field having a water level higher than the water level of the drainage channel, The fishway is formed on the most downstream side in order to form a fishway body by sequentially joining a plurality of waterway members in the extending direction of the eaves part between the drainage channel and the paddy field. An upstream end portion of a pipe-shaped water channel member that communicates with the drainage channel and is buried underground is joined to a downstream side opening provided in the water channel member, and on the uppermost stream side that constitutes the fishway body. A downstream end portion of the water channel member that is eventually communicated with the paddy field is joined to the upstream side opening of the installed water channel member, and each of the water channel members constituting the fishway main body has a water channel water. A dam plate is mounted so as to be removable, and the overflow part of the dam plate , It is characterized in that the fish has been set to allow height intrusion relative water level on the downstream side.
[0025]
Another aspect of the fish run-up structure according to the present invention is a fish run-up structure including a drainage channel and a fishway for allowing fish to run up to a paddy field having a water level higher than the water level of the drainage channel, The fishway is formed on the most downstream side in order to form a fishway body by sequentially joining a plurality of waterway members in the extending direction of the eaves part between the drainage channel and the paddy field. An upstream end portion of a pipe-shaped water channel member that communicates with the drainage channel and is buried underground is joined to a downstream side opening provided in the water channel member, and on the uppermost stream side that constitutes the fishway body. The downstream end portion of the pipe-shaped water channel member that is communicated with the paddy field and is buried underground is joined to the upstream side opening of the installed water channel member, and the water channel constituting the fishway body Each member can be attached and detached with a weir plate that raises the channel water Is mounted, the overflow portion of the weir plate, and is characterized in that the fish has been set to allow height intrusion relative water level on the downstream side.
[0026]
In these cases, the pipe-shaped water channel member is preferably formed in a circular pipe shape, for example, and disposed substantially horizontally.
[0027]
In each fish run-up structure, it is preferable that the upper end side of the fish-guide string for drifting in the water flowing through the fishway is attached to the barrier plate.
[0028]
In each fish run-up structure, the dam plate is composed of a dam plate body that is detachably attached to the water channel member and a slide adjustment plate attached to the dam plate body, and the dam plate body has an open upper end. The slide adjusting plate is attached to the main body of the dam plate so as to cover the lower part of the notch and is slidable in the vertical direction. The upper end of the plate is the overflow section, and the upward and downward sliding state of the slide adjustment plate can be adjusted so that the overflow section is at a height that allows fish to rise upstream of the downstream water level. In addition, it is preferable that the slide adjustment plate can be fixed to the dam plate body in the adjustment state.
[0029]
In each fish run-up structure, the fish that runs up the fishway is prevented from jumping out of the fishway, and the fish that is going up is prevented from being preyed on by the birds. It is better to cover with a net or transparent covering material. In this case, the prevention net or the transparent covering material may be configured to cover the upper side of the fishway by covering a support frame provided on the water channel member in a standing state.
[0030]
In each of the fish run-up structures, a partition wall for raising water flowing through the drainage channel is detachably attached to the drainage channel, and the partition body is detachably mounted on the drainage channel and the partition wall. An adjustment plate attached to the main body, and the partition wall main body is provided with a notch portion having an open upper end, and the adjustment plate is in contact with the partition wall main body so as to cover a lower portion of the notch portion. In addition, the upper end of the adjustment plate is the overflow section, and the overflow section has a height that allows fish to run up to the downstream water level. Thus, it is preferable that the vertical sliding state of the adjusting plate can be adjusted and the adjusting plate can be fixed to the partition wall body in the adjusted state.
[0031]
Further, in each fish run-up structure, a partition for raising the water flowing through the drainage channel is attached to the drainage channel, and the partition extends in the direction of water flow in the drainage channel and has a width equal to the width of the drainage channel. With the front plate of the scouring prevention block in which a front plate is erected at the upstream end of the bottom plate having substantially the same width, and a rear plate is erected at the downstream end of the bottom plate. It is preferable that a part of the front plate be an overflow section that is set to a height at which fish can run up with respect to the downstream water level.
[0032]
In this case, the front plate to be the partition is composed of a partition main body forming a part of the front plate and an adjustment plate attached to the partition main body, and the partition main body is provided with a notch portion having an open upper end. The adjustment plate is attached to the bulkhead body so as to be slidable in the vertical direction so as to cover the lower portion of the notch, and the upper end of the adjustment plate is the overflow portion, The adjustment plate can be adjusted to slide in the vertical direction so that the overflow section is at a height that allows fish to run upstream of the downstream water level, and the adjustment plate is fixed to the bulkhead body in the adjustment state. It should be possible.
[0033]
In each fish run-up structure, a scouring prevention block is disposed in the drainage channel on the downstream side of the fishway, and the scouring prevention block extends in the direction of water flow in the drainage channel. A front plate functioning as a partition for raising water flowing through the drainage channel is erected at an upstream end portion of the bottom plate having a width substantially equal to the width of the drainage channel, and a downstream end of the bottom plate A rear plate is erected in the section, and a part of the front plate is an overflow section set at a height that allows fish to run up to the downstream water level, and the front plate and the rear plate It is better to store the filter medium in a space between the two.
[0034]
In the fish run-up structure in which the partition wall is detachably mounted, the downstream side of the overflow section may be formed in an arc surface. In the fish upstream structure, the downstream side of the overflow section may be formed on an inclined surface inclined downward at an angle of 13 to 60 degrees.
When the partition is configured with a front plate of a scouring prevention block, the front plate is attached to the drainage channel and provided with a partition main body provided with a notch portion with an open top, and the partition main body. In the case of the adjustment plate, the downstream edge portion of the notch is preferably formed on an inclined surface inclined toward the downstream side so as to expand at an angle of 13 to 60 degrees.
[0035]
In the case where the barrier plate is composed of a barrier plate main body and a slide adjusting plate, it is preferable that an edge portion on the downstream side of the notch portion is formed on an arc surface. Or it is good to form the edge part of the downstream of this notch part in the inclined surface which inclines toward the downstream so that it may expand at an angle of 13-60 degrees.
[0036]
In the case where the partition wall is composed of a partition wall main body and an adjusting plate, it is preferable that an edge portion on the downstream side of the notch is formed on an arc surface. Or it is good to form the edge part of the downstream of this notch part in the inclined surface which inclines toward the downstream so that it may expand at an angle of 13-60 degrees.
[0037]
In the fish run-up structure in which the drainage channel has a partition wall, it is preferable that a drain hole is provided below the overflow section.
[0038]
In each fish run-up structure, it is preferable to arrange aquatic string-like bodies for laying eggs in the drainage channel at appropriate intervals in the width direction. In this case, the aquatic string-like body is provided with a weight at one end of the string-like body and a float at the other end, and the string-like body has a length of about 50 to 100 mm on the peripheral surface of the string piece. It is assumed that a large number of hair pieces having a thickness are provided, and the weight is installed at the bottom of the drainage channel.
[0039]
A waterway member (hereinafter referred to as a waterway member) used for a fish run-up structure according to the present invention is a waterway member that constitutes a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel, It is open and has a U-shaped groove with a continuous water channel from the upstream end to the downstream end, and the width of the upstream water channel is enlarged, and all or part of the joint forming the downstream side is fitted. A joint fitting portion is formed for insertion, and a guide portion for detachably fitting a weir plate for raising the channel water is provided at a downstream portion of the channel, and the upstream side of the channel A support base for supporting the lower surface of the joint portion of the water channel member installed on the upstream side from below is projected from the bottom portion of the water channel member.
[0040]
A more preferable aspect of the water channel member according to the present invention is a water channel member that constitutes a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel, and is open at the upper end and from the upstream end to the downstream end. And a joint fitting portion that is formed in a U-shaped groove shape having a continuous water passage toward the water passage, has an enlarged upstream water passage width, and fits all or a part of the joint portion on the downstream side. Formed on the downstream side of the water channel, and on the opposite side and bottom surfaces thereof, there are provided insertion grooves for removably fitting a weir plate for raising the water of the water channel, and on the upstream side of the water channel. A support base for supporting the lower surface of the joint portion of the water channel member installed on the upstream side from below is projected from the bottom.
[0041]
Another aspect of the waterway member according to the present invention is a waterway member that constitutes a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel, the upper end being open and a circumferential wall portion. And is formed in a bottomed box shape whose inside is a water channel, and an upstream side opening and a downstream side opening are provided in a required part on the upstream side and a required part on the downstream side of the wall, A guide portion is provided on the inner surface of the upstream opening and the downstream opening for removably fitting a weir plate for raising the water of the channel, and the upstream opening and the downstream side are provided on the inner surface of the water channel. A guide portion is provided for detachably fitting an intermediate dam plate that raises the channel water so as to divide the openings, and the overflow portion of each dam plate is a fish relative to the downstream water level. Is set to a height that can be moved up.
[0042]
In this case, a guide portion for detachably fitting a plurality of intermediate weir plates for raising the water channel water is provided on the opposite side surface and bottom surface so as to divide the upstream opening and the downstream opening into a plurality. The overflow section of each weir plate is preferably set to a height that allows fish to run up with respect to the downstream water level.
[0043]
Another aspect of the waterway member according to the present invention is a waterway member that constitutes a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel, the upper end being open and the circumferential wall portion. And is formed in a bottomed box shape whose inside is a water channel, and an upstream side opening and a downstream side opening are provided in a required part on the upstream side and a required part on the downstream side of the wall, The upstream side opening and the downstream side opening are provided with insertion grooves for detachably fitting a weir plate for raising water in the channel, on the opposite side surface and bottom surface, and on the opposite side surface and bottom surface of the water channel. In order to partition between the upstream side opening and the downstream side opening, an insertion groove for detachably fitting an intermediate dam plate that raises the channel water is provided, and the overflow portion of each dam plate includes: Make sure that the fish is set at a height that allows the fish to run upstream of the downstream water level. It is an butterfly.
[0044]
In this case, in order to partition the upstream opening and the downstream opening into a plurality, an insertion groove for detachably inserting a plurality of intermediate weir plates for raising the channel water is provided on the opposite side surface and the bottom surface. The overflow section of each weir plate is preferably set to a height that allows fish to run up with respect to the downstream water level.
[0045]
In each of the water channel members, the upstream opening and the downstream opening may be provided in the wall portion so that a flow direction of water passing through both the openings is bent.
[0046]
In each of the water channel members, it is preferable that the downstream side of the overflow portion of the dam plate is formed as an arc surface. Or it is good to form the downstream of the overflow part of the said dam plate in the inclined surface which inclines below at an angle of 13-60 degrees.
[0047]
In each of the waterway members, the barrier plate includes a barrier plate body that is detachably attached to the water channel member, and a slide adjustment plate that is attached to the barrier plate body. A notch is provided, and the slide adjusting plate is attached to the main body of the dam plate so as to cover the lower part of the notch so as to be slidable in the vertical direction. The upper end of the slide adjustment plate can be adjusted as the overflow portion, and the slide state of the slide adjustment plate can be adjusted so that the overflow portion has a height that allows fish to be able to run up to the downstream water level. It is preferable that the slide adjusting plate can be fixed to the dam plate body in a state.
[0048]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
In FIG. 1, a fish run-up structure 1 according to the present invention is for raising fish to a drainage channel 2 connected to a river or a lake and a reservoir 3 as a paddy field 3 a having a higher water level than the drainage channel 2. The fishway 6 is included. The fishway 6 is constructed by joining a plurality of waterway members 7 in a straight line to the ridge part 5 between the paddy field 3a and the drainage channel 2, and the water level of the drainage channel 2 This can be handled conveniently when the drop between the water levels of the reservoir 3 as the paddy field 3a is relatively small. It is assumed that the width of the heel part 5 (indicated by L1 in FIG. 3) is about 1900 mm and the drop between the water level of the drainage channel 2 and the water level of the paddy field 3a (indicated by L2 in FIG. 2) is about 650 mm. To do.
[0049]
In the present embodiment, as shown in FIGS. 4 to 5, the water channel member 7 is formed in a U-shaped groove shape having a continuous water channel 9 that is open at the upper end and extends from the upstream end to the downstream end. The upstream end of the water channel 9 is an upstream opening 10 and the downstream end is a downstream opening 11. Further, the upstream portion of the water channel member 7 is a joint fitting portion 13 for fitting the joint portion 12 forming the downstream portion of the water channel member 7 in close contact with the water channel. . If the dimensions of the main part of the water channel member 7 are exemplified, the total length is set to about 600 mm, the water channel depth is set to about 500 mm, the water channel width of the upstream portion is set to about 610 mm, The channel width of the downstream portion is set to about 500 mm.
[0050]
Further, as shown in FIGS. 5 and 7, the bottom portion 15 of the upstream portion of the water channel member 7 has a lower surface 16 of the joint portion 12 of the water channel member 7 installed on the upstream side over the entire width. A support base 17 is provided so as to protrude from below. The upper surface 19 of the support base 17 is formed in a horizontal plane, and its height is set to about 100 mm. In addition, a distance L3 (FIG. 7) between the upper surface 19 of the support base 17 and the lower surface 18 of the water channel member is set to about 150 mm, which is substantially equal to a water level difference that allows fish to run up.
[0051]
As shown in FIGS. 4 to 7, the water is raised on the opposite side surfaces 21 and 21 and the bottom surface 22 of the downstream portion of the water channel 9 of the water channel member 7, and the overflow portion 24 (FIGS. 4 and 9). ) Is continuously provided with a fitting groove 25 for fitting a weir plate 23 that allows water to flow downstream. And in the state which adjoins the said support stand 17 in the upstream part of the said water channel 9, the water of the said reservoir 3 is raised to the opposing side surfaces 26 and 26 and the bottom face 27 of the upstream part, and its overflow part 24 (FIGS. 4 and 9), a fitting groove 29 is provided continuously for fitting a weir plate 23 that allows water to flow downstream.
[0052]
As shown in FIG. 4, the dam plate 23 has a trapezoidal shape, an arc shape, a rectangular shape, a V shape, or the like at the center of the upper end, and an overflow notch portion where the lower end becomes the overflow portion 24. 30 is provided. The shape, width and depth of the overflow notch 30 can be obtained in consideration of the size of fish going up the fishway 6 and the amount of water flowing through the fishway 6. Is set as follows. For example, if the overflow width is small and the overflow water depth is shallow, even if small fish can be run up, large fish cannot be run up, and only limited fish can be run up. . Therefore, in the present embodiment, the overflow notch 30 is formed in a trapezoidal shape having an upper end width L4 of about 150 mm and a depth L5 of about 100 mm so that large fishes can be moved up. Further, the downstream side of the upper end of the overflow notch 30 is formed on the circular arc surface 28 as shown in an enlarged view in FIG.
[0053]
However, in order to configure the fish run-up structure 1 using the water channel member 7 having such a configuration, as shown in FIGS. 1 to 3, the trough 5 between the drainage channel 2 and the paddy field 3a is Excavation is performed in a linearly inclined state substantially perpendicular to the flow direction of the drainage channel 2, and the four water channel members 7, 7, 7, 7 are sequentially joined in steps in a straight line at the excavation part 31. In this case, as shown in FIG. 7, the joint portion 12 of the water channel member 7b installed on the upstream side is fitted into the joint fitting portion 13 of the water channel member 7a installed on the downstream side, and the joint portion 12 is placed on the support base 17 of the downstream channel member 7a, and each channel member is installed in a substantially horizontal state. As a result, the lower surface 16 of the joint portion 12 comes into contact with the upper surface 19 of the support base 17, and the joint portion 12 is fitted into the joint fitting portion 13. When the waterway members 7 and 7 are joined to each other in this manner, the fishway 6 is formed. In addition, in order to employ | adopt the structure which fits the junction part of the channel member 7b installed in the upstream into the junction fitting part 13 of the channel member 7a installed in the downstream side, the junction part 32 (FIG. 7) between channel members. ) Need not take special measures against water leakage. FIG. 9 is an enlarged perspective view of the fishway 6, and FIG. 10 is an enlarged sectional view of the fishway.
[0054]
At the time of the joining, the insertion length of the joining part 12 with respect to the joining fitting part 13 is set as required in consideration of the width of the collar part 5 and the number of water channel members 7 used, and the total length of the fishway is Adjust appropriately according to the width of the part. 2 and 7, the end portion 33 of the joint portion 12 projects downstream from the support base 17, has an overlap margin of, for example, about 7 cm, and the lower surface 36 of the projecting portion 35 of the joint portion. A gap portion 37 is formed between the joint fitting portion 13 and the bottom surface 15.
[0055]
As shown in FIG. 2, the upstream opening 10 of the water channel member 7c installed on the most upstream side communicates with the paddy field 3a, and the downstream opening 11 of the water channel member 7d installed on the most downstream side. Is communicated with the drainage channel 2. Further, the weir plate 23 is inserted into the downstream insertion grooves 25, 25, 25, 25 provided in each water channel member 7 and the upstream insertion groove 29 of the water channel member 7 c installed on the most upstream side. Each is detachably fitted.
[0056]
For convenience of explanation, in FIGS. 9 and 10, the four water channel members are referred to as a first water channel member 7A, a second water channel member 7B, a third water channel member 7C, and a fourth water channel member 7D in order from the top. The five dams fitted in the fitting grooves are referred to as a first dam plate 23A, a second dam plate 23B, a third dam plate 23C, a fourth dam plate 23D, and a fifth dam plate 23E in order from the top. Further, the water storage in each channel member raised by the dam plate is referred to as a first water storage 39A, a second water storage 39B, a third water storage 39C, and a fourth water storage 39D in order from the top, and the portion for storing the water storage is the first. It is referred to as a reservoir 40A, a second reservoir 40B, a third reservoir 40C, and a fourth reservoir 40D.
[0057]
In the present embodiment, the drainage channel 2 has U-shaped support frames 41 arranged in parallel at a required interval as shown in FIGS. 1-2 and 11-12, and the length of the drainage channel 2. The side plates 43 are supported in a plurality of stages between the rising pieces 42 and 42 adjacent to each other in the direction, and the water channel wall 44 is formed by the side plates 43 supported in the plurality of stages. And the water level of the drainage channel 2 is raised as needed by the partition 50 (FIGS. 1-3, FIGS. 11-12).
[0058]
The partition 50 is installed at a required interval so that fish can run up the drainage channel 2 according to the gradient of the drainage channel 2 and the amount of water flowing through the drainage channel 2. For example, as shown in FIGS. 1 and 2, the edge portions 50a and 50a at both ends thereof are inserted into insertion grooves 49 (FIG. 1) provided on the inner surface of the U-shaped support frame 41 selected at intervals of 1 to 2 m, for example. Thus, the water level of the drainage channel 2 is raised as required by the partition wall 50, so that the water overflows to the downstream side by the overflow notch 52 having an open top provided in the partition wall, and the overflow notch 52 The overflow part 54 as the lower end of the water is set to a height (for example, 50 to 150 mm) that allows fish to run up with respect to the downstream water level. The overflow notch 52 may be provided in a staggered arrangement as shown in FIGS. 11 to 12, for example, in addition to being arranged in a straight line when viewed in the length direction of the drainage channel 2. And in FIG. 11, the swimming place of fish is formed in the corner part 53 between partition walls.
[0059]
Further, the downstream opening 11 of the most downstream water channel member 7 </ b> D communicates with the opening 38 formed in the water channel wall 44. At that time, as shown in FIG. 10, the bottom surface 38 a of the opening 38 and the bottom surface 48 of the downstream opening 11 are substantially flush with each other.
[0060]
For example, as shown in FIG. 12, the drainage channel 2 has a part of one channel wall 44a expanded to the shore side, and the bottom part is dug down if necessary to spawn, inhabit and evacuate seafood. Suitable stagnation and depth parts are provided. In addition, an inclined member 46 having a stepped shape or a sloped shape with appropriate unevenness is provided from the bottom to the upper end of the enlarged portion 45, and insects, amphibians, and reptiles use the inclined member 46. It is made to go up and down between the drainage channel 2, the buttock surface 47 and the paddy field 3a. The enlarged portion may be provided on both water channel walls 44 and 44.
[0061]
Next, the effect | action of the fish run-up structure 1 comprised in this way is demonstrated based on FIGS. That is, when using the fishway 6 having the above configuration, when fresh water is supplied to the paddy field through a pump (not shown), the water level is raised by the first dam plate 23A of the water channel member 7A installed on the most upstream side. The fresh water flows through the overflow part 24 as the lower end of the overflow notch 30 and flows into the first reservoir 40A. The channel water that has flowed into the first reservoir 40A is raised by the second dam plate 23B and flows over the overflow portion 24 as the lower end of the overflow notch 30 provided in the second dam plate 23B. Water flows into the second reservoir 40B. The channel water that has flowed into the second reservoir 40B is raised by the third dam plate 23C and overflows the overflow portion 24 as the lower end of the overflow notch 30 of the dam plate. It flows into the reservoir 40C. The channel water flowing into the third reservoir 40C is raised by the fourth dam plate 23D, overflows the overflow portion 24 as the lower end of the overflow notch 30 of the dam plate, and passes through the fourth reservoir portion. Flows into 40D. The channel water flowing into the fourth reservoir 40D is raised by the fifth dam plate 23E, overflows the overflow portion 24 as the lower end of the overflow notch 30 of the dam plate, and the drainage channel 2 flows out.
[0062]
And between the water level 56 of the drainage channel and the water level 57 of the fourth reservoir 39D, between the water level 57 of the fourth reservoir 39D and the water level 59 of the third reservoir 39C, the water level 59 of the third reservoir 39C and the second reservoir 39B. Between the water level 60 of the second reservoir 39B and the water level 61 of the first reservoir 39A, there is a water level difference of about 50 to 150 mm, for example, a water level difference of about 100 mm. Is provided. Further, a water level difference of about 70 mm is also provided between the water level 62 of the paddy field and the water level 61 in the most upstream water channel member 7A. And fish can go up in each overflow part (overflow water depth is about 30-50 mm) 24.
[0063]
Therefore, when the fish run-up structure 1 according to the present invention is used, fish such as corals, corals, corals and the like enter the drainage channel 2 from rivers, lakes, etc., and the overflow notch 52 of the partition wall 50 is moved up. It can be made to the place where the said fishway 6 exists. Thereafter, the fishway 6 can be run up. Specifically, the water surface can be stepped up in order to the fourth water storage 39D, the third water storage 39C, the second water storage 39B, and the first water storage 39A to reach the paddy field 3a and lay eggs in the paddy field. . As a result, the paddy field 3a can be utilized as a place for spawning, breeding and nurturing fish, and rice cultivation that coexists with nature can be developed.
[0064]
As shown in FIGS. 9 and 13, for example, one end side 68 of the fish-guide string 67 is fixed to the upper end side 66 of the barrier plate 23 by means such as screws, or the one end side is fixed. It is preferable to attach it by hooking it to the hooked portion provided on the barrier plate 23 or the like. As long as the attached string-like object 67 can be provided with a fish guiding function, the upper end side 66 is set as the lower side of the overflow notch 30 or the periphery of the overflow notch 30 (such as a side part). it can.
[0065]
The string 67 is formed by using an organic material, for example, a rough rope (having a diameter of about 5 to 20 mm), a cotton material, or the like in consideration of final disposal when the use time of the fishway 6 is over. However, it may be made of resin. FIG. 14 shows a specific example of the string-like object 67. The hair pieces 67b having a length of about 50 to 100 mm are radially formed on the peripheral surface of the string piece 67a having a thickness of about 1 to 3 mm. Many are provided.
[0066]
As described above, the string-like object 67 is relatively fixed, for example, about 30 to 50 cm, so that one end side 68 is attached to each barrier plate 23 and the other end 69 reaches the water channel member installed on the downstream side. In addition to being set to a short length, as shown by a broken line in FIG. 10, one end side 68 is attached to the uppermost dam plate 23A and is long so as to run down from the paddy field 3a side to the drainage channel 2 side. Sometimes it is set. Alternatively, the length may be set so as to flow down over a plurality of water channel members.
[0067]
Since the string-like object 67 attached in this way rides on a water stream and swings in a state of flowing downstream like aquatic plants in natural rivers, it is possible to induce fish ascending.
[0068]
When the reservoir 3 is a paddy field, the spawning time of fish to the paddy field substantially coincides with the rice planting time. If the dam plate 23 is attached at this time, a certain amount of water is drained from the fishway 6. The water level of the paddy field can be kept constant. On the other hand, when it is necessary to lower the water level, such as before mid-drying or rice harvesting (no fishway is necessary at this time), remove all the dams and drain the water from the paddy field through the water channel 64 as shown in FIG. Drain to drain 2. Moreover, the fishway 6 can be easily cleaned by removing the barrier plate in this way.
[0069]
In the present embodiment, the lower surface 16 of the joint portion 12 of the water channel member installed on the upstream side is supported from below by the support base 17 of the water channel member installed on the downstream side, and Since the weir plate 23 is attached to the downstream portion of each channel member, a mud pool 72 is formed at the bottom of each channel member as shown in FIGS. Therefore, in this mud pool 72, organic matter from the paddy field contained in the water channel flowing down the fishway can be precipitated, and the outflow of organic matter to the drainage channel 2 can be prevented accordingly. Furthermore, aquatic plants and the like grow from the soil accumulated in the mud reservoir 72, and this can be expected to capture the organic matter in the canal water and purify the water quality. This can contribute to the prevention of river pollution. Further, as shown in FIG. 7, by forming the bottom surface portion 73 of the water channel member 7 and the side surface portion 75 on the surface where the natural stone is exposed, algae can be propagated on the natural stone surface. Thus, the bottom of the waterway can be used as a feeding ground for small fish and benthic organisms, and the habitat can be provided.
[0070]
Further, when the water channel members are joined to each other, as shown in FIGS. 2 and 7, between the bottom surface 36 of the projecting portion of the joint portion 12 projecting into the joint fitting portion 13 and the bottom surface 15 of the joint fitting portion 13. Since the space 37 is formed, algae can grow in this place, and the space 37 can be a habitat for benthic organisms that prefer shade, and can also be a blame for fry.
[0071]
In the present embodiment, as shown in FIG. 16, in order to prevent fish traveling up the fishway 6 from jumping out of the fishway, or to prevent predatory fish from being preyed on by the birds. For example, a resin-preventing net 77 is attached via a support frame 76 so as to cover the upper side of the fishway 6. The mesh of the prevention net 77 is formed in, for example, a rhombus having a side length of about 30 mm.
[0072]
For example, the support frame 76 is attached to each of the four water channel members 7, 7, 7, 7 joined in the vertical direction. Three frame pieces 79a, 79b, 79c having the same inverted U-shape are arranged at intervals, and the upper horizontal portions 80, 80, 80 of the three frame pieces are arranged on both sides of the lower surface thereof with 2 The frame piece 79a, which is integrally connected by the linear connecting pieces 81, 81 and located on the upstream end side of the water channel member 7, is formed wider than the remaining frame pieces 79b, 79c. These frame pieces are formed, for example, by cutting a hollow pipe or a solid bar (made of metal or resin) having a diameter of about 10 mm into a predetermined length, and bending this in an inverted U shape. The maximum height from the upper end of the water channel member 7 is set to about 300 to 400 mm, for example.
[0073]
In order to attach the support frame 76 having such a configuration to the water channel member 7, both lower end portions 82, 82 of the wide frame piece 79 a are approximately in the length direction of the upper surface of the joint fitting portion 13 of the water channel member 7. The lower end portions 82 and 82 of the intermediate frame piece 79b are inserted into the support holes 83 and 83 provided in the center closely, and the lower end portions 82 and 82 of the intermediate frame piece 79b are substantially at the center in the length direction of the upper surface of the water channel member 7 (the joint fitting portion). 13 and a connecting portion between the joint portion 12) and the lower end portions 82, 82 of the frame piece 79c positioned on the downstream end side of the water channel member 7, This is performed by closely inserting into the support holes 83, 83 provided on the upper surface on the downstream end side of the water channel member 7. Thus, after each support frame 76 is attached to each water channel member in an upright state, the prevention net 77 covers each of the support frames 76, 76, 76, 76 so as to cover the upper surface portion and both side portions thereof. If it covers so that the upper part of the side part of the waterway members 7, 7, 7, and 7 may be covered, as shown in FIG. 16, the upper side of the fishway 6 will be covered with the prevention net 77, and it will be covered in the shape of a semicircular bowl protruding upward. It becomes a state. The support frame 76 and the prevention net 77 can be removed when the fishway is not used. In addition, the said support hole 83 provided in the water channel member 7 is shown only in FIGS.
[0074]
FIGS. 19 to 20 show a fishway 6 constructed by sequentially joining the water channel members 7 shown in FIG. 21 formed in a U-shaped groove shape in the vertical direction. The configuration of a dam plate (hereinafter referred to as a first dam plate) 23a for raising water in the reservoir 3 is different from that of a dam plate (hereinafter referred to as a second dam plate) 23b for raising water in the channel. Further, the groove width of the fitting groove 29 provided in the upstream portion of the water channel member 7 is formed to be slightly wider.
[0075]
As shown in FIGS. 20 to 22, the first dam plate 23 a that raises the water in the reservoir 3 includes a dam plate body 85 fitted into the fitting groove 29, and a drop adjustment attached to the dam plate body 85. The dam plate main body 85 is provided with a vertically long rectangular cutout 87 (FIG. 22) that extends to one side and extends from the upper end to the vicinity of the bottom surface of the water channel member 7. The upper end width L6 of the rectangular cutout 87 is set to about 150 mm, and the drop adjusting plate 86 for raising the water of the reservoir 3 is fitted into the opposite side faces 89 and 90 and the bottom face 91 of the rectangular cutout. A mounting groove 92 is provided continuously.
[0076]
The lower end portion of the upstream surface of the first barrier plate 23 a is formed as an inclined surface 95 that can come into contact with the inclined surface 93 on the downstream side of the support base 17. The surface 96 extending in the direction intersects the upper surface 19 of the support base 17 at a right angle. In the present embodiment, two drop adjustment plates 86 having different vertical heights are used as the drop adjustment plate 86 fitted into the mounting groove 92. Then, a rectangular overflow notch 30 as shown in FIG. 21 is formed above the upper end of the upper drop adjustment plate, and the overflow portion 24 is used as the upper end to allow fishes to go back to the downstream water level. It is set to a height that can be increased (for example, 50 to 150 mm), and the overflow water depth in the overflow portion 24 is set to, for example, about 30 to 50 mm.
[0077]
In the present embodiment, as shown in FIGS. 20 to 21 and FIG. 23, the second dam plate 23b is a dam plate body that is fitted in the fitting groove 25 provided in the downstream portion of the water channel member 7. 97 and a slide adjusting plate 99 attached in contact with the barrier plate main body 97. The barrier plate main body 97 is a protrusion fitted into the insertion groove 25 on the upstream end side of the outer peripheral surface 100 thereof. A strip 101 is provided. Then, with the protrusion 101 fitted in the insertion groove 25, as shown in FIG. 20, the downstream end side 102 of the outer peripheral surface 100 abuts on the inner peripheral surface 103 of the downstream end of the water channel, In this state, as shown in FIGS. 20 and 24, the downstream surface 105 of the second dam plate 23 b is configured to be flush with the downstream end surface 106 of the water channel member 7.
[0078]
Further, a rectangular cutout 107 having an upper end width L7 of about 150 mm and a depth of about 270 mm is provided near the same side as the first dam plate 23a. In the present embodiment, the peripheral edge 109 of the rectangular cutout 107 is chamfered so as to expand toward the downstream side. The chamfer is provided to prevent the fish going up from being caught on the peripheral portion, and the inclination angle thereof is about 13 to 60 degrees, preferably about 35 to 45 degrees, and more preferably about 45 degrees. Set to Inserts 111, 111, 111, 111, 111, 111 for bolting the slide adjustment plate 99 are embedded in three stages on both sides of the surface 110 on the downstream side of the rectangular notch 107. Yes.
[0079]
Further, the slide adjustment plate 99 covers the rectangular cutout portion 107 on the upstream side or the downstream side thereof (on the downstream side in FIGS. 19 to 20), so that the upper side of the upper end of the slide adjustment plate 99. In addition, it is used to form a rectangular overflow notch 30 as shown in FIG. And the overflow part 24 as this upper end is set to the height (for example, 50-150 mm) which fish can go up with respect to the downstream water level, and the overflow water depth in this overflow part 24 is 30 It is set to about 50 mm.
[0080]
Further, as shown in FIG. 23, the downstream side 108 of the upper end 112 of the slide adjusting plate 99 has an inclined surface inclined at, for example, about 13 to 60 degrees, preferably about 35 to 45 degrees, more preferably 45 degrees. It is formed on a sloping surface that is slanted to the extent that it makes it difficult for fish going up. Further, on both sides of the slide adjustment plate 99, vertically long adjustment holes 113 and 113 are provided for inserting bolts 112 to be screwed into the insert 111.
[0081]
FIG. 24 shows a state in which the slide adjusting plate 99 is fixed to the weir plate body 97 using the lower two-stage inserts 111, 111, 111, 111, and the overflow section 24 is at the downstream water level. On the other hand, it is set to about 50 to 150 mm, and the overflow water depth in the overflow section 24 is set to about 30 to 50 mm. FIG. 25 shows a state in which the slide adjusting plate 99 is fixed to the dam plate body 97 using the upper two stages of inserts 111, 111, 111, 111. The height of the overflow portion 24 and the overflow water depth are shown in FIG. It is set similarly to the above.
[0082]
As shown in FIG. 26, the lower end of the rectangular cutout 107 may be used as the overflow portion 24 without providing the slide adjusting plate 99.
[0083]
The first and second weir plates 23a, 23b are made of heavy concrete, for example, and the drop adjustment plate 86 and the slide adjustment plate 99 are made of, for example, wood, resin, metal, etc. Is done.
[0084]
FIG. 19 shows the fish run-up structure 1 configured using the water channel member 7 to which the first and second dam plates 23a and 23b having the above-described configuration are attached. The point which joins and comprises the fishway 6 is the same as that of the above. That is, the fishway 6 excavates the trough 5 between the drainage channel 2 and the paddy field 3a in a linear inclined state substantially orthogonal to the flow direction of the drainage channel 2, and the excavation unit 31 includes three pieces. The water channel members 7, 7, 7 are sequentially joined in a straight line stepwise. At that time, as in the above embodiment, the joint portion 12 of the water channel member installed on the upstream side is fitted into the joint fitting portion 13 of the water channel member installed on the downstream side, and the joint portion 12 is inserted. Is placed on the support base 17 of the downstream channel member 7, and each channel member is set to be substantially horizontal. As a result, the lower surface 16 of the joint portion 12 comes into contact with the upper surface 19 of the support base 17, and the joint portion 12 is fitted into the joint fitting portion 13. The fishway 6 is formed by joining the waterway members 7 and 7 in this way.
[0085]
And as shown in FIG. 19, while the said upstream opening 10 of the channel member 7g installed in the most upstream side is connected to the said paddy field 3a, the said downstream side opening 11 of the channel member 7e installed in the most downstream side. The (overflow notch 30) communicates with the drainage channel 2. Further, the second dam plate 23b is detachably fitted in the downstream insertion grooves 25, 25, 25 provided in each water channel member 7, and the water channel member 7g installed on the most upstream side is The first dam plate 23 a is detachably fitted in the upstream insertion groove 29.
[0086]
And about each of this 1st dam plate 23a and 2nd dam plates 23b, 23b, and 23b, the height of the overflow part 24 and the overflow water depth in the said rectangular-shaped notches 87 and 107 are the said drainage channel 2 and According to the drop L2 between the water levels of the paddy field 3a and the width L1 of the eaves part 5, it is set as required so that fish can be moved up by adjusting the drop adjustment plate 86 and the slide adjustment plate 99. It is what is done. The setting procedure is as described above.
[0087]
In the present embodiment, the first dam plate 23a also functions as a soil retaining to prevent the paddy soil from moving to the fishway side. Further, in the space 115 formed between the second dam plates 23b, 23b positioned above and below, and the space 116 between the first and second dam plates 23a, 23b in the water channel member 7g on the most upstream side. The filter medium 117 can be accommodated as shown in FIG. By storing the filter medium 117 in this way, fine particles such as sludge contained in the water overflowed from the paddy field can be filtered, and the water quality of the drainage flowing into the drainage channel 2 can be purified. The filter medium 117 is preferably made of an organic material such as straw or rice husk in consideration of final disposal. In the same manner as described above, as shown in FIG. 19, each water channel member 7 may be provided with a support frame 76 and covered with a prevention net 77. In addition, as shown in FIGS. 9 and 10, it is preferable to attach a weed-like string-like object 67 to the first and second dam plates 23a and 23b. FIG. 19 shows a case where a long string-like object 67 that hangs down from the paddy field 3a side to the drainage channel 2 side is attached.
[0088]
FIG. 27 shows another embodiment of the fishway 6 configured using the waterway member 7 having a U-shaped groove shape, and the top end 118 of the carp and the lower end of the slope of the carp and the drainage channel. This is convenient when a unicycle or the like is desired to travel on the road 119 formed without any obstacles.
[0089]
As shown in FIGS. 27 to 28, the fishway 6 is formed by sequentially joining four water channel members 7, 7, 7, 7 in the longitudinal direction of the ridge at the boundary between the ridge 6 and the slope 120 of the ridge. The fishway main body 121 is formed. For this purpose, the joint portion 12 of the water channel member 7k installed on the upstream side is fitted into the joint fitting portion 13 of the water channel member 7j installed on the downstream side, and the joint portion 12 is connected to the downstream water channel. Each water channel member is placed in a substantially horizontal state on the support base 17 of the member 7j. Then, in the insertion groove 29 on the upstream end side of the water channel member 7m installed on the most upstream side and the insertion groove 25 on the downstream end side of the water channel member 7j installed on the most downstream side, FIG. As shown, end plates 122 and 123 not having the rectangular cutouts 87 and 107 as described above are fitted. Further, dam plates 23, 23, 23 having the same configuration as the second dam plate 23b are fitted into the insertion grooves 25, 25, 25 on the downstream side of the water channel members excluding the most downstream water channel member. And the overflow notch part 30 of each dam is set so that the overflow part 24 and overflow water depth of required height can be obtained by the slide operation of the slide adjustment board 99 like FIG. The
[0090]
In addition, as shown in FIGS. 27 to 30, the fishway 6 has, for example, a downstream opening as a circular hole at the lower end side of the side surface portion 125 on the side facing the drainage channel 2 of the water channel member 7 j located on the most downstream side. 11 is formed in the downstream opening 11 as a pipe made of vinyl chloride that communicates with the drainage channel 2 and has, for example, an inner diameter of about 150 to 200 mm and a length of about a side road width (about 60 to 200 cm). The upstream end portion 127 of the water channel member 7n that is embedded in the basement substantially horizontally is joined in an inserted state.
[0091]
In addition, as shown in FIGS. 27 and 31 to 32, an upstream side opening 10 as a circular hole, for example, is provided on the lower end side of the side surface portion 129 facing the paddy field 3 a of the water channel member 7 m located on the most upstream side. A water channel formed as a vinyl chloride pipe having an inner diameter of about 150 to 200 mm and embedded in the basement substantially horizontally, which communicates with a water channel member 7p, which is a water channel member provided in a portion of the paddy side of the paddy field. The end portion 130 on the downstream side of the member 7q is joined in the inserted state.
[0092]
The water channel member 7p as the trough member is one component of the fishway 6, and is formed in a rectangular tube shape, for example, as shown in FIGS. 31 to 32, and is located on the most upstream side in a pipe shape. A downstream opening 11 for joining the upstream end portion 131 in the inserted state is provided on the lower end side of the side surface portion 132 facing the fishway main body 121. The paddy side of the dredging member (water channel member) 7p is opened as a whole, and a weir plate 137 for raising the water of the paddy field 3a is fitted into the opposite side surfaces 135, 135 and the bottom surface 136 of the opening 133. An insertion groove 139 is provided continuously. The dam plate 137 is configured by mounting the required number of drop adjustment plates 138c in the fitting grooves 138b of the rectangular cutouts 138a provided in the dam plate body 138 in the same manner as in the dam plate shown in FIG. ing.
[0093]
When the fish run-up structure 1 is used, the fish that has entered the lower pipe-shaped channel member 7n from the drainage channel 2 are connected to the U-shaped channel-shaped channel member 7 by the weir plates 23, 23, 23. It can be run up through the overflow notch 30 and reaches the U-shaped channel member 7m existing on the most upstream side. Then, it enters into the pipe-shaped water channel member 7q positioned above, reaches the dredging member (water channel member) 7p, and enters the paddy field 3a through the overflow notch 140 of the dam plate 137 provided in the dredging member 7p. Can be reached.
[0094]
The laying height of the pipe-like channel member 7n located below is set so that the inside of the channel member is always full in order to facilitate the entry of fish into the channel member 7n. Is good. The upper and lower pipe-shaped water channel members 7n and 7q function not only as an approach path for fish but also as an evacuation place for fish in the daytime, for example.
[0095]
The support frame 76, the prevention net 77, the string 67, and the filter material 117 provided in the same manner as described above can be removed when the fishway is not needed.
[0096]
The U-shaped groove-shaped channel member is joined so as to cross the ridge to form a fishway body, and a pipe-shaped channel member is formed only on the downstream end side or on the upstream end side of the fishway body. In some cases, a fishway is formed by joining.
[0097]
FIGS. 19 and 33 to 37 show another embodiment of the drainage channel 2 constituting the fish run-up structure 1 according to the present invention, and a U-shaped support frame 41 having the same configuration as described above is provided at a necessary interval. The side plates 43 are supported in a plurality of stages between the rising pieces 42 and 42 adjacent in the length direction of the drainage channel 2, and the water channel walls 44 are formed by the side plates 43 supported in the plurality of stages. Yes. Then, by inserting the edge portions 50a, 50a at both ends of the partition wall 50 made of concrete, for example, into the insertion groove 49 provided on the inner surface of the selected U-shaped support frame 41, the water level of the drainage channel 2 is required. Raised. Further, as shown in FIGS. 34 and 35, a rectangular notch 140 having an open top end is provided on one end side of the partition wall 50, and the adjustment plate 141 is disposed on, for example, an upstream surface of the rectangular notch 140. In this case, the overflow notch 52 is formed on the upper side of the adjustment plate 141. The peripheral portion 142 of the overflow notch 52 is chamfered so as to expand toward the downstream side. The opening width of the overflow notch 52 is set to 150 mm, for example, and the depth is set to 180 mm, for example.
[0098]
Also, as shown in FIG. 36, inserts 143, 143 for fixing the adjusting plate 141 in three upper and lower stages are positioned on both sides of the rectangular cutout 140 on the upstream surface of the partition wall 50. 143, 143, 143, and 143 are buried.
[0099]
The adjustment plate 141 is formed of wood, resin, metal, or the like, has a horizontally long rectangular plate shape, and is provided with adjustment holes 144, 144 that are long in the vertical direction on both sides thereof. 19, 34, and 37 show a state in which the adjustment plate 141 is fixed to the partition wall 50 using bolts 145 that are screwed into the upper two stages of inserts 143, 143, 143, and 143, and FIG. The adjustment plate 141 is fixed to the partition wall 50 by using bolts 145 screwed into the two-stage inserts 143, 143, 143, 143. In these, according to the amount of flowing water in the drainage channel 2, the overflow portion 54 as the upper end of the adjusting plate 141 has a height (for example, a height of about 50 to 150 mm) that allows fish to run upstream of the downstream water level. The overflow depth in the overflow portion 54 is set to about 30 to 50 mm, for example, depending on the amount of water flow, the adjustment plate is removed and the lower end of the rectangular notch 140 is connected to the overflow portion 54. Sometimes.
[0100]
Further, in the present embodiment, water is provided on the lower end side of the partition wall 50 below the rectangular notch 140 (for example, approximately the center in the width direction of the rectangular notch 140) and the other end of the partition wall. Holes 146 and 146 are provided. The drain hole 146 is formed as, for example, a circular hole having a diameter of 50 to 100 mm (a circular hole having a diameter of about 50 mm in FIGS. 19 and 34), and the water channel bottom 147 (FIG. 37) of the drainage channel 2. From about 30 to 50 mm. As shown in FIG. 38, the drain hole 146 can be closed with a plug 148 by means such as fitting or screwing.
[0101]
In the drain hole 146a (FIGS. 19, 34, and 37) provided on the lower side of the rectangular notch 140, the overflow notch 52 is released by releasing the water to release water. Since the water discharge F2 (FIG. 37) from the drain hole 146a is added in addition to the falling water F1 (FIG. 37) from the water, the fish can be easily guided toward the overflow notch 52 by feeling their flow. The effect can be expected.
[0102]
When the drain hole 146b (FIG. 19) on the other end side is also opened, the flow action caused by the discharge of water from the drain hole 146b causes the drainage hole 146b to be located above the flowing water. A relatively slow flow part can be formed and a relatively fast flow part can be formed on the lower side, so that it is possible to mix a place with a stagnation and a place with a flow, and a habitat suitable for the fish ecological environment. It can be formed.
[0103]
The drain hole 146 is provided so that the slide type adjustment plate 141 is not covered with the adjustment plate 141 even in the lowest lowered position.
[0104]
In addition, when the water volume in the drainage channel 2 is abnormally increased due to an unexpected amount of rainfall, the water level of the drainage channel 2 is adjusted without removing the partition wall 50 by opening the drainage hole 146 and discharging it. There are cases where it is possible. For this purpose, the number of drain holes provided may be increased or the diameter thereof may be increased.
[0105]
In addition, fish and shellfish can move to the opposite side of the partition wall 50 through the drain holes 146a and 146b.
[0106]
In the present embodiment, as shown in FIG. 37, aquatic string members 149 for laying eggs are arranged in the drainage channel 2 at appropriate intervals. As shown in FIG. 37, the aquatic string-like body 149 is provided with a weight 151 such as a stone or a concrete fence at one end of a resinous string-like body 150 and a float 152 such as a polystyrene foam or a floating bag at the other end. It is provided. The string-like object 149 has a configuration in which a large number of hair pieces 154 having a length of about 50 to 100 mm are radially provided on the circumferential surface of the string piece 153 having a diameter of about 1 to 3 mm. The length is set to about 100 to 130 cm, for example, according to the water depth of the drainage channel 2. The aquatic string-like body 149 having such a configuration is such that the weight 151 is placed on the water channel bottom 147 of the drainage channel 2 and is arranged at appropriate intervals in the width direction of the water channel. It forms a state and functions as an aid for spawning and growing fish.
[0107]
For example, as shown in FIG. 37, when the water falls on the downstream side through the overflow notch 52 provided in the partition wall 50, the water channel bottom may be scoured by the water fall. Therefore, in FIGS. 39 to 42, the partition wall 50 is configured by using a scouring prevention block 156 having a function capable of preventing such scouring.
[0108]
The scouring prevention block 156 is made of, for example, precast concrete, and has a width substantially equal to the width of the drainage channel 2 as shown in FIG. 39 and FIG. A front plate 159 functioning as a partition wall 50 is erected at an upstream end portion of the bottom plate 157 provided in an extended manner, and a rear plate 160 is erected at a downstream end portion of the bottom plate 157. The rear plate 160 is set so that the upper end 161 thereof is substantially flush with the channel bottom 147. The length of the bottom plate 157 in the longitudinal direction of the scour prevention block 156 is set to 820 mm, for example, the height of the front plate 159 is set to 440 mm, and the height of the rear plate 160 is set to 190 mm, for example. A space 163 having a width of about 700 mm is formed between the front plate 159 and the rear plate 160.
[0109]
The scouring prevention block 156 having such a configuration is such that the lower portion 165 is drained while the front plate 159 serving as the partition wall 50 is in contact with the downstream surface 164 of the U-shaped support frame 41 constituting the drainage channel 2. As shown in FIG. 42, the open ends 166 and 166 of the scouring prevention block 156 are closed by, for example, side plates 167 and 167 or closed by sandbags. The front plate 159 serving as the partition wall 50 is provided with a rectangular notch portion (having an opening width of about 150 mm) 169 having an open upper end, and on both sides of the rectangular notch portion 169, the insert 170 is vertically arranged in three stages. Is buried. Then, a bolt 172 that passes through adjustment holes 171 and 171 provided in the vertical direction on both sides of the slide type adjustment plate 141 configured in the same manner as described above is screwed into the required insert 170 to thereby adjust the adjustment plate 141. Can be fixed to the front plate 159. Thereby, the overflow notch 52 can be formed on the upper side of the adjusting plate 141, and the overflow portion 54 that enables the fish to run up is formed in the same manner as described above.
[0110]
In this case, since the bottom plate 157 exists on the downstream side of the partition wall (front plate 159) 50, the bottom of the water channel is protected by the bottom plate 157 even if the water flows through the overflow notch 52. Therefore, scouring of the bottom of the waterway can be prevented. Further, since a depth portion 172 (FIG. 40) in which the bottom of the water channel is further dug down is formed on the downstream side of the overflow notch 52, when the fish goes up the overflow notch 52, There is an advantage that you can easily go up with momentum.
[0111]
In addition, since the empty space 163 between the front plate 159 and the rear plate 160 of the scouring prevention block 156 serves as a mud reservoir, the fertilizer component such as flowing into the drainage channel 2 from the paddy field through the fishway 6 It is also possible to deposit fine soil containing organic matter such as water to purify water.
[0112]
In addition, the water purification effect in the drainage channel 2 can be improved by accommodating the filter medium 173 such as straw and rice husk in the empty space 163 of the scour prevention block 156. Also in this embodiment, the drain holes 146 having the same function as described above are provided on, for example, both sides of the rectangular cutout 169. In the same manner as described above, a fish-guide string 67 can be attached around the adjustment plate 141 and the rectangular cutout 169.
[0113]
[Second Embodiment]
43 to 45 show another embodiment of the fish run-up structure 1 according to the present invention. In the eaves part 5 between the water level of the drainage channel 2 and the water level of the reservoir 3 as the paddy field 3a, It forms a fishway 6 for moving fish up from the drainage channel 2 toward the reservoir 3, and can cope with a case where the difference between the water level of the drainage channel 2 and the water level of the reservoir 3 as the paddy field 3 a is large. . Now, the width of the heel part 5 (indicated by L1 in FIG. 45) is about 1900 mm, and the drop (indicated by L2 in FIG. 44) between the water level of the drainage channel 2 and the water level of the reservoir 3 as the paddy field 3a is about 900 mm. Assume a case.
[0114]
46 to 47, the water channel member 7 is formed in a bottomed rectangular parallelepiped box shape that is open at the upper end and is closed by a circumferential wall portion 180 and has a water channel 9 therein. The long side length is set to about 1100 mm, the short side length is set to about 600 mm, and the vertical height is set to about 860 mm. As shown in FIG. 47, a rectangular downstream side having a length of about 300 mm and a depth of about 600 mm that is long in the vertical direction from the upper end to the lower end side at one short side portion of one long side wall portion 180a. As shown in FIG. 46, a square having the opening 11 and the width of the other long side wall portion 180b near the other short side is the same width as the downstream side opening 11 and about half the depth thereof. A shaped upstream opening 10 is provided.
[0115]
The inner side surfaces 181 and 181 and the bottom surface 182 of the downstream side opening 11 are continuously provided with a fitting groove 183 for fitting the weir plate 23 for raising the channel water, and the upstream side opening 10 is opposed. The inner side surfaces 185 and 185 and the bottom surface 186 are continuously provided with fitting grooves 187 for fitting the weir plates 23 for raising the water channel. In addition, an intermediate fitting groove 191 for fitting a weir plate 23 for raising water channel water into the inner side surfaces 189 and 189 facing each other and the bottom surface 190 of the water channel member is formed at the center of both long side wall portions 180a and 180b. It is provided continuously. Each dam plate 23 is provided with an overflow notch 30 similar to the above at the center of the upper end.
[0116]
And as shown in FIG. 45, the water channel member 7, so that the downstream side opening 11 of the water channel member 7 installed on the upstream side is communicated with the upstream side opening 10 of the water channel member 7 installed on the downstream side. 7 are joined to each other, and a weir plate 23 is fitted into a fitting groove provided in one of the openings in the communicating portion of the upstream opening 10 and the downstream opening 11, and a water channel on the upstream side of the weir plate Water is being raised.
[0117]
However, in order to configure the fish run-up structure 1 using the water channel member 7 having the above-described configuration, as shown in FIGS. 43 to 45, the trough 5 between the drainage channel 2 and the paddy field 3a is excavated, In the excavation part, the three water channel members 7E, 7F, and 7G are placed in a substantially horizontal state in order from the top, and are sequentially joined in steps. At that time, the water channel member located on the most downstream side as shown in FIG. The downstream opening 11 of 7G is communicated with the opening 38 provided in the water channel wall 43 of the drainage channel 2 having the same configuration as described above. As shown in FIG. 48, the bottom surface 38a of the opening 38 and the bottom surface 48 of the downstream side opening 11 are made substantially flush with each other.
[0118]
As shown in FIG. 49, the bottom surface 48 of the downstream opening 11 of the water channel member 7F located in the middle stage is substantially flush with the bottom surface 192 of the upstream opening 10 of the water channel member 7G installed on the most downstream side. To.
[0119]
As shown in FIG. 50, the bottom surface 48 of the downstream opening 11 of the water channel member 7E located on the most upstream side is substantially flush with the bottom surface 192 of the upstream opening 10 of the water channel member 7F located in the middle stage. . Then, the upstream opening 10 of the water channel member 7E installed on the most upstream side is communicated with the paddy field 3a. Note that the water channel members 7 and 7 adjacent to each other are connected to each other using, for example, an angle member 193 shown in FIG. FIG. 51 is an enlarged perspective view of the fishway 6.
[0120]
Then, as shown in FIG. 45, the fitting groove 183 and the intermediate fitting groove 191 provided in the downstream opening 11 in the most downstream channel member 7G, and the fitting provided in the downstream opening 11 in the middle channel member 7F. An insertion groove 191 between the groove 183 and the water channel member, an insertion groove 183 of the downstream opening 11 in the water channel member 7E installed on the most upstream side, an intermediate insertion groove 191 in the water channel member, and the water channel member The dam plate 23 is fitted into each of the fitting grooves 187 of the upstream opening 10. The weir plate 23 is provided with an overflow notch 30 having the same configuration as described above.
[0121]
For convenience of explanation, FIGS. 52 and 51 showing the AA cross-sectional views of FIGS. 45 and 45, the seven dams fitted as described above are arranged in order from the top, the first dam plate 23E, 2 dam plate 23F, 3rd dam plate 23G, 4th dam plate 23H, 5th dam plate 23I, 6th dam plate 23J, and 7th dam plate 23K. In addition, the reservoirs raised by the second to seventh dams are arranged in order from the top, the first reservoir 39E, the second reservoir 39F, the third reservoir 39G, the fourth reservoir 39H, the fifth reservoir 39I, and the sixth reservoir 39J. The parts that store the water are referred to as a first reservoir 40E, a second reservoir 40F, a third reservoir 40G, a fourth reservoir 40H, a fifth reservoir 40I, and a sixth reservoir 40J.
[0122]
However, when the fish run-up structure 1 is used, the water level supplied to the paddy field 3a is raised by the first dam plate 23E and flows into the first reservoir 40E from the overflow notch 30. The water flowing into the first reservoir 40E is raised by the second barrier plate 23F and flows into the second reservoir 40F from the overflow notch 30. Similarly, the water flowing into the second reservoir 40F is raised by the third dam plate 23G, flows into the third reservoir 40G from the overflow notch 30, and flows into the third reservoir 40G. The water is raised by the fourth dam plate 23H and flows into the fourth reservoir 40H from the overflow notch 30. The water flowing into the fourth reservoir 40H is raised by the fifth dam plate 23I and The water flowing into the fifth reservoir 40I from the overflow notch 30 is raised by the sixth dam plate 23J and flows into the sixth reservoir 40J from the overflow notch 30J. The water flowing into the sixth reservoir 40J is raised by the seventh dam plate 23K and flows out from the overflow notch 30 into the drainage channel 2. In FIG. 52, a water level difference of about 50 to 150 mm, for example, a water level difference of about 100 mm, is provided between adjacent water levels of the stored water, and the water level of the paddy field 3a and the first water storage 39E. A similar water level difference is provided between the water level. And in the overflow part (overflow water depth is about 30-50 mm, for example) 24 as a lower end of each above overflow notch part 30, fish can go up.
[0123]
Therefore, when the fish run-up structure 1 according to the present invention is used, fish such as corals, corals, corals and the like enter the drainage channel 2 from rivers, lakes, etc., and the overflow notch 52 of the partition wall 50 is moved up. It can be made to the place where the said fishway 6 exists. Thereafter, the fishway 6 can be run up. Specifically, the sixth water storage 39J, the fifth water storage 39I, the fourth water storage 39H, the third water storage 39G, the second water storage 39F, and the first water storage 39E, whose water surfaces are stepped, are sequentially arranged in the overflow section 24. It is possible to go up to the paddy field 3a and lay eggs in the paddy field. And the water of a paddy field can be smoothly drained to the drainage channel 2 by removing each barrier plate 23.
[0124]
The configuration in which the downstream side of the overflow notch 30 of the dam plate 23 is formed in an arcuate surface and the fish guide string 67 is attached to the dam plate 23 is the same as in the above embodiment. . And a mud pool can be formed in the bottom part side of the channel member 7, and this can be functioned similarly to the said embodiment.
[0125]
The dam plate 23 is the same as in the above-described embodiment in order to be able to form an appropriate overflow portion 24 according to the difference between the water level of the drainage channel 2 and the water level of the paddy field 3a and the width of the ridge. More preferably, it is configured. That is, as the dam plate 23 located on the most upstream side, the first dam plate 23a shown in FIG. 22 having a configuration in which the required number of drop adjustment plates 86 having a required height are sequentially stacked in the mounting groove 92 is adopted. As the barrier plate 23, it is preferable to employ the second barrier plate 23b having the slide adjusting plate 99 as shown in FIG.
[0126]
[Third Embodiment]
53 to 54, the drainage channel 2 has a relatively small width (indicated by L1 in FIG. 54) of the heel part 5 between the paddy field 3a and the drainage channel 2 of the fish upstream structure 1 according to the present invention. It is possible to cope with a case where a drop (indicated by L2 in FIG. 58) between the water level in the reservoir 3 as the paddy field 3a and the water level in the reservoir 3 is relatively large. The bent fishway 6 is formed by using two kinds of waterway members, a first waterway member 7H having a cylindrical shape and a second waterway member 7I having a U-shaped groove, and joining these waterway members as required. To do. Assume that the width of the heel portion 5 is about 1700 mm and the drop between the water level of the drainage channel 2 and the water level of the paddy field 3a is about 580 mm.
[0127]
As shown in FIGS. 55 to 56, the first water channel member 7H is formed in a bottomed cylindrical box shape having an open upper end and closed by a circumferential wall portion 180, and has an inner diameter of about 900 mm in plan view. The vertical opening is formed to have a height of about 720 mm, and the upstream side opening 10 and the downstream side opening 11 are provided in the required part on the upstream side and the required part on the downstream side of the wall 180. In the present embodiment, the upstream side opening 10 and the downstream side opening 11 are formed as a rectangular opening having an upper end that is wider than the lower end, and the flow of water that passes through both the openings 10 and 11 is formed. It is provided so as to be bent at a substantially right angle. The upper end width of the upstream side opening 10 and the downstream side opening 11 is formed to about 610 mm, the depth of the upstream side opening 10 is formed to about 360 mm, and the depth of the downstream side opening 11 is larger than that. It is deep and formed to be about 560 mm.
[0128]
As shown in FIGS. 55 and 57, the second water channel member 7I is formed in a U-shaped groove. The upstream end of the water channel is the upstream opening 10 and the downstream end is downstream. A side opening 11 is provided. Further, in the upstream side portion and the downstream side portion of the inner surface of the water channel, insertion grooves 201 and 202 for continuously fitting the weir plate 23 for raising the water of the channel water are provided on the opposite side surfaces 197 and 197 and the bottom surface 199, respectively. Yes. In the present embodiment, the total length is set to about 600 mm and the water channel depth is set to about 500 mm.
[0129]
However, in order to construct the fish run-up structure 1 using the first and second water channel members 7H and 7I, as shown in FIGS. The first water channel member 7 </ b> H is disposed on the upstream side and the downstream side along the extending direction of 2. Then, the upstream side portion 203 of the second water channel member 7I installed in a substantially horizontal state on the downstream side is fitted in the downstream side opening 11 of the first water channel member 7H with an elastic water blocking material interposed therebetween. While being inserted into the combined state, the downstream opening 11 of the second water channel member 7I is communicated with the opening 38 provided in the water channel wall 44 of the drainage channel 2.
[0130]
Further, the adjacent first water channel members 7H, 7H are connected by the second water channel member 7I as a U-shaped groove. At this time, the downstream side portion 206 of the second water channel member 7I is While inserting an elastic water blocking material into the upstream opening 10 of the first water channel member 7H installed on the downstream side in a fitted state, the upstream portion 203 of the second water channel member 7I is An elastic water-stopping material is interposed in the downstream opening 11 of the first water channel member 7H installed on the upstream side and inserted into a fitted state. Similarly, the downstream portion 206 of the second water channel member 7I is inserted into the fitted state in the upstream opening 10 of the first water channel member 7H installed on the upstream side. And the upstream opening 10 of this 2nd waterway member 7I is connected to the paddy field 3a.
[0131]
Further, in each of the second water channel members 7I, the weir plates 23 and 23 are detachably fitted into the upstream insertion groove 201 and the downstream insertion groove 202, respectively. These dam plates 23 are provided with overflow notches 30.
[0132]
For convenience of explanation, in FIGS. 54 and 55 showing the BB cross-sectional views of FIGS. 54 and 54, the six dam plates fitted as described above are arranged in order from the top, the first dam plate 23L, 2 dam plate 23M, 3rd dam plate 23N, 4th dam plate 23P, 5th dam plate 23Q, and 6th dam plate 23R. Further, the water storage portions raised by the second to fifth barrier plates are referred to as a first water storage 39L, a second water storage 39M, a third water storage 39N, a fourth water storage 39P, and a fifth water storage 39Q in order from the top. The first reservoir 40K, the second reservoir 40L, the third reservoir 40M, the fourth reservoir 40N, and the fifth reservoir 40P are referred to as the first reservoir 40K, the second reservoir 40L, the third reservoir 40M, the fourth reservoir 40N, and the fifth reservoir 40P.
[0133]
However, when the fish run-up structure 1 is used, the level of the water supplied to the paddy field 3a is raised by the first dam plate 23L and flows into the first reservoir 40K from the overflow notch 30. The water flowing into the first reservoir 40K is raised by the second dam plate 23M and flows into the second reservoir 40L from the overflow notch 30. Similarly, the water flowing into the second reservoir 40L is raised by the third dam plate 23N, flows into the third reservoir 40M from the overflow notch 30, and flows into the third reservoir 40M. The water is raised by the fourth dam plate 23P and flows into the fourth reservoir 40N from the overflow notch 30. The water that has flowed into the fourth reservoir 40N is raised by the fifth dam plate 23Q and passed thereover. It flows into the fifth reservoir 40P from the flow cutout 30 and finally flows out into the drainage channel 2 from the fifth reservoir 40P. In FIG. 58, a water level difference of about 50 to 150 mm, for example, a water level difference of about 100 mm, is provided between adjacent water levels. And in the overflow part (overflow water depth is about 30-50 mm, for example) as a lower end of each above overflow notch part 30, fish can go up.
[0134]
Therefore, when the fish run-up structure 1 according to the present invention is used, fish such as corals, corals, corals and the like enter the drainage channel 2 from rivers, lakes, etc., and the overflow notch 52 of the partition wall 50 is moved up. It can be made to the place where the said fishway 6 exists. Thereafter, the fishway 6 can be run up. Specifically, the fifth water storage 39Q, the fourth water storage 39P, the third water storage 39N, the second water storage 39M, and the first water storage 39L, whose water surfaces are stepped, are sequentially moved up in the overflow section 24, 3a can be spawned in paddy fields. And the water of a paddy field can be smoothly drained by removing each barrier plate 23. FIG.
[0135]
The configuration in which the downstream side of the overflow notch 30 of the dam plate 23 is formed in an arcuate surface and the fish guide string 67 is attached to the dam plate 23 is the same as in the above embodiment. . And a mud pool can be formed in the bottom part side of the channel member 7, and this can be functioned similarly to the said embodiment.
[0136]
The dam plate 23 is the same as in the above-described embodiment in order to be able to form an appropriate overflow portion 24 according to the difference between the water level of the drainage channel 2 and the water level of the paddy field 3a and the width of the ridge. More preferably, it is configured. That is, as the dam plate 23 positioned on the most upstream side, the first dam plate 23a shown in FIG. 22 having a configuration in which the required number of drop adjustment plates 86 having a required height are sequentially stacked in the mounting groove 92 is adopted. As the barrier plate 23, it is preferable to employ the second barrier plate 23b having the slide adjusting plate 99 as shown in FIG.
[0137]
[Other Embodiments]
The present invention is by no means limited to that shown in the above-described embodiment, and various design changes can be made within the scope of the claims. One example is as follows.
[0138]
(1) The fish run-up structure according to the present invention is applied to reservoirs that require fish run-up, including fish ponds, reservoir ponds, water parks, etc. that use fallow fields in addition to the paddy fields described above. it can.
[0139]
(2) When the water channel member is configured in the U-shaped groove shape, the dam plate mounted on the downstream portion of the inner surface of the water channel is not necessarily mounted on the downstream end as shown in FIG. In some cases, it may be installed upstream of that.
[0140]
(3) FIG. 59 shows another embodiment of the channel member 7 having a U-shaped groove shape, and has a configuration bent in a dogleg shape. And the joint part 12 and the joint fitting part 13 are provided in the same manner as described above, and the joint part 12 is fitted into the joint fitting part 13 of the other water channel member 7A1 installed on the downstream side, The joint portion 12 of the other water channel member 7A2 installed on the upstream side is fitted into the joint fitting portion 13 of the doglegged water channel member 7. The U-shaped channel member 7 having such a configuration can be advantageously used when, for example, the ridge width is relatively small but the water level difference between the drainage channel and the paddy field is relatively large.
[0141]
(4) When the water channel member 7 is configured in a bottomed box shape that is open at the upper end and closed by the circumferential wall 180, the box shape is a rectangular box shape shown in FIG. The configuration is not limited to the cylindrical box shape shown in FIG.
[0142]
(5) When the water channel member 7 is formed in a U-shaped groove shape, one or more intermediate dam plates 23 for raising the water channel water are formed so as to partition the upstream side opening 10 and the downstream side opening 11. Sometimes it is detachably mounted.
[0143]
(6) When the water channel member 7 has a bottomed box shape that is open at the upper end and closed by a circumferential wall, in order to properly set the water level difference between adjacent water storage units, One or a plurality of intermediate dam plates for raising the channel water may be detachably mounted so as to partition the side opening and the downstream opening into a plurality.
For example, when the channel member 7 is configured in a rectangular parallelepiped box shape as shown in FIG. 51, a plurality of intermediate weir plates 23 for raising the channel water so as to partition the upstream opening 10 and the downstream opening 11 into a plurality of partitions. The sheet may be detachably mounted. In addition, when the water channel member is configured in a cylindrical box shape with a bottom as shown in FIG. 55, an intermediate weir plate for raising the water of the water channel so that the upstream side opening 10 and the downstream side opening 11 are partitioned into a plurality of parts. One or more sheets may be detachably mounted
[0144]
(7) When the water channel member 7 is configured in a box shape with a bottom, when the water level difference between the reservoir and the drain channel is relatively small, an intermediate weir plate 23 (for example, a water channel having a rectangular box shape shown in FIG. 51) The intermediate weir plate in the member may be omitted.
[0145]
(8) The upstream side opening 10 and the downstream side opening 11 of the water channel member that has a bottomed box shape that is open at the upper end and closed by the circumferential wall portion include, as shown in FIG. 11 is preferably provided on the wall so that the flow direction of the water passing through 11 is bent. However, the bent state is required in consideration of the width of the ridge, the difference in the water level between the drainage channel and the reservoir, and the like. Can be set.
[0146]
(9) In the case where the water channel member 7 is configured in a box shape with a bottom, the upstream side of the upstream side 10 and the downstream side opening 11 is detachably mounted with a dam plate that raises the water of the water channel. In addition to the case of being mounted on the inner surface of the opening 10 or the inner surface of the downstream opening 11, the case of being mounted on the vicinity of the upstream opening 10 or the vicinity of the downstream opening 11 is included.
[0147]
(10) In addition to being formed in a groove shape as described above, the guide portion for fitting the barrier plate is formed between the protruding portions spaced apart so as to sandwich the barrier plate on the opposite side. Also good.
[0148]
(11) A dam plate (for example, the dam plate 231 shown in FIG. 1 may be omitted) attached to the upstream portion of the water channel member installed on the most upstream side.
[0149]
(12) When the water level between the drainage channel and the reservoir is relatively large while the width of the buttocks or the like existing between the reservoir 3 and the drainage channel 2 is relatively small, the fishway 6 is indicated by a one-dot chain line in FIG. It may be provided diagonally.
[0150]
(13) When the water channel member 7 is configured in a U-shaped groove shape, the support base 17 protruding from the upstream water channel bottom portion 15 has a lower surface of the joint portion of the water channel member installed on the upstream side from below. It is not necessarily required to be provided over the entire width of the water channel bottom portion 15 as long as it can be stably supported.
Further, as shown in FIGS. 60 to 61, the support base 17 may be formed separately from the water channel member 7 and fixed to the bottom portion 15 of the water channel by means such as adhesion. Further, as shown in FIG. 62, the support base 17 may be configured to have a predetermined height by stacking a plurality of unit height support base pieces 207, for example. When the support base 17 is formed integrally with the bottom 15 of the water channel, and the height of the support base 17 is too low, a separate auxiliary support base 209 is attached to the support base 17 as shown in FIG. As a result, a support base having a required height may be formed.
FIG. 64 shows a configuration in which a plurality of support bases 17 project from the bottom portion 15 of the water channel at a required interval in the front and rear direction when viewed in the length direction of the water channel. In the figure, two support bases 17a and 17b are projected. In this case, the height of the support base 17a located on the upstream side is set lower than the height of the support base 17b located on the downstream side. If comprised in this way, according to the magnitude | size of the fish to go up, the fish can go up between the water level of the channel member installed in the upstream, and the water level of the channel member installed in the downstream. The required water level difference can be provided. When the fish going up is large in size, the water level difference can be set large. In this case, the fish stand-up structure can be configured by selecting the support stand 17b having a higher height. Thereby, there exists the economical efficiency which can reduce the use number of the waterway members which comprise the fishway 6. FIG.
[0151]
(14) The water channel member 7 constituting the fish run-up structure according to the present invention may be configured to have a pipe shape such as a resin, in addition to the above-described open top end. . Or the fish run-up structure may be comprised by the combination of the channel member which exhibits pipe shape, and the channel member which the upper end opened.
[0152]
(15) The configuration in which the dam plate is detachably attached to the water channel member is configured such that the dam plate can be fitted in the insertion groove as described above, and various configurations that can be detached so that the water can be raised. Can be adopted.
[0153]
(16) In addition, the dam plate 23 may not be provided with the overflow notch 30 as described above. However, when the overflow notch 30 is provided, the overflow notch is defined as the width of the dam plate. It is not restricted to what is provided in a direction center part. For example, as shown in FIG. 65, the overflow notch 30 may be brought close to the end of the dam plate 23, and the overflow notch portions of the dam plates arranged in parallel in the vertical direction may be provided in a staggered arrangement. When configured in this way, it is possible to form a stagnation portion 210 where fish can swim by meandering the flow of water in the fishway. In FIG. 65, the overflow notch 30 is hatched for convenience of explanation.
[0154]
(17) The overflow water depth is set according to the fish run-up condition, and if it is configured to ensure a overflow water depth of 30 to 50 mm, the necessary overflow water depth according to various fishes. Can be secured.
[0155]
(18) When chamfering the downstream side of the overflow section provided on the dam plate attached to the water channel member, the chamfer is formed as an arc surface in addition to the inclined surface in any of the above-described embodiments. it can.
This is the same when the overflow portion is formed as the upper end of the slide adjustment plate provided so as to cover the lower portion of the rectangular cutout portion provided in the dam plate. In this case, it is preferable to chamfer the edge portion of the cutout portion so as to expand toward the downstream side (chamfering such as an inclined surface or an arc surface).
[0156]
(19) When the downstream side of the overflow section provided in the partition wall is chamfered, in any of the above-described embodiments, the chamfer can be formed as an arc surface as well as an inclined surface.
This also applies to the case where the overflow portion is formed as the upper end of a slide type adjustment plate provided so as to cover the lower portion of the rectangular cutout portion provided in the partition wall. In this case, it is preferable to chamfer the edge portion of the notched portion so as to expand toward the downstream side (the chamfer such as an arc surface on the inclined surface).
[0157]
(20) When a notch is provided in the barrier plate or the partition wall and a slide adjusting plate or a slide type adjusting plate is attached to the notch to constitute a required overflow part, the notch is It is not limited to the rectangular cutout, and can be formed as a cutout having a trapezoidal shape, a V shape, an arc shape, or the like.
[0158]
(21) As described above, the means for providing the slide adjusting plate on the barrier plate so that the height can be adjusted and the means for providing the adjusting plate on the partition wall so that the height can be adjusted are as described above. In addition to means for inserting a bolt into an adjustment hole that is long in the vertical direction provided in the screw and screwing the bolt into the insert, various adjustment means known in the art can be used.
[0159]
(22) In the embodiment, the scouring prevention block is configured to cover both open ends with side plates and sandbags, but is configured to close both ends with side plates provided integrally with the bottom plate. May be.
[0160]
(23) As the drainage channel, those having various known structures can be adopted in addition to those assembled using the U-shaped frame.
[0161]
(24) The concept of the fish run-up structure shown in FIG. 27 in which pipe-like waterway members are joined to the upper and lower sides of the fishway main body constituted by joining U-shaped groove-like waterway members is a bottomed box shape. The present invention can also be applied to the fish run-up structure according to the second and third embodiments that are configured by using the present channel member.
[0162]
(25) When the fishway 6 is constructed by joining the pipe-shaped waterway member 7 to the fishway main body 121, the upper end of the pipe-shaped waterway member 7 may be partially exposed on the ground surface. FIG. 66 shows an example, and the pipe-shaped water channel member 7 can be detachably closed with a water channel member main body 220 having an open upper end formed in, for example, a U-shaped groove, and an upper end open portion 221 thereof. The lid plate 222 is configured, and the pipe-shaped water channel member 7 is formed by closing the lid plate 222. In this case, as shown in FIG. 66, the channel member body 220 is buried underground, the cover plate 222 is exposed to the ground surface, and the cover plate 222 is removed when necessary. The inside of the member 7 can be inspected and cleaned.
[0163]
(26) As shown in FIG. 1, the partition wall 50 is detachably attached to the U-shaped support frame 41 by inserting edge portions at both ends into an insertion groove 49 provided on the inner surface of the U-shaped support frame 41. In addition to being mounted, the U-shaped support frame 41 may be screwed to the upstream side surface.
[0164]
(27) When the scouring prevention block 156 is disposed in the drainage channel 2, the bottom plate 157 of the scouring prevention block can prevent scouring of the bottom of the drainage channel by falling water through the overflow portion 54. As long as it is provided, it may be provided only in the vicinity of the downstream side of the overflow section 54.
[0165]
(28) The prevention net 77 covering the upper side of the fishway 6 may be changed to a transparent covering material such as a transparent vinyl chloride sheet. The transparent coating material may be a colored transparent coating material as long as it allows fish to run up on the fishway.
[0166]
【The invention's effect】
The present invention has the following excellent effects.
(1) A fish run-up structure according to the present invention includes a drainage channel and a fishway for allowing fish to run up to a reservoir having a water level higher than the water level of the drainage channel. A plurality of water channel members are sequentially joined to each other, and a structure in which a dam plate is detachably attached to each water channel member is adopted, and the overflow portion of the dam plate is connected to the downstream water level with fish. Adopts a configuration in which the height is set to a height that can be run up.
Therefore, according to the invention, the required number of water channels according to the width between the reservoir and the drainage channel as viewed in plan (the width of the buttock etc.) and the difference between the water level of the drainage channel and the water level of the reservoir By joining the members in a straight line state and a required bent state sequentially, by setting the height of the overflow part of the weir plate attached to the water channel member and the overflow water depth in the overflow part to form a fishway, The fish can be moved up to the place where the fishway exists, by sequentially going up the overflow part of the partition wall provided in the drainage channel as necessary, and then the fish can be easily fed from the drainage channel to the reservoir. Can be run up
In the conventional system for forming a fishway between the drainage channel and the reservoir, the construction is mainly performed on-site according to each construction site, so that much labor is required for the construction. In addition to the problems of poor construction efficiency and increased construction costs, there were problems of prolonged construction period. In particular, when the fishway is formed in a bent state when the head is large, the on-site construction becomes very complicated and the workability is deteriorated, and the construction cost is further increased. Generated. In addition, when a fishway is to be formed using an integrally formed concrete fishway block having a length from the drainage channel to the reservoir, the fishway block is individually designed to a length corresponding to the construction site. In addition to the problem that the construction cost has to be significantly increased, the concrete fishway block is heavy, is not easy to transport to the construction site, and deteriorates the workability. There was also.
On the other hand, according to the present invention in which a plurality of water channel members are sequentially joined, in other words, a necessary number of water channel members are joined sequentially to constitute a fishway, such problems can be solved at once.
Moreover, since the said dam plate is detachable, by removing all the dam plates, the water of a reservoir can be discharged | emitted smoothly to a drainage channel, and the cleaning of a fishway is also easy.
[0167]
(2) When the upper end portion of the dam plate to be mounted on the water channel member is provided with an overflow notch having a trapezoidal shape, a U shape, a rectangular shape, a V shape, etc., the amount of water flowing through the fishway is not large. Sometimes, it is possible to secure the required water depth that allows fish to run up in the overflow notch.
[0168]
(3) When an intermediate dam plate that raises the channel water is detachably attached to the water channel member so as to partition the upstream side opening and the downstream side opening provided in the water channel member, the water level is set on the water channel by the intermediate dam plate. Since a difference can be formed, a fishway having an appropriate water level difference can be economically formed without increasing the number of water channel members used when the head between the drainage channel and the reservoir is large.
When a plurality of intermediate weir plates are mounted at a required interval, the water channel of the water channel member can be further divided, and a required water level difference can be formed between the intermediate weir plates.
[0169]
(4) In the case of using a channel member having a bottomed box shape that is open at the upper end and closed by a circumferential wall portion, the flow direction of water passing through both the opening and the downstream opening is defined as the upstream opening and the downstream opening. When the wall portion is bent so that the end portion of the other water channel member is inserted into the upstream side opening and the downstream side opening, the width of the flange portion, the water level of the reservoir and the drainage channel Therefore, it is possible to rationally construct an appropriate bent fishway according to the head to water level. For example, when the width of the buttocks or the like is small and the head is large, there is an advantage that it can be dealt with by bending the fishway even if it cannot be dealt with by a straight fishway.
[0170]
(5) A pipe-shaped channel member communicating with the drainage channel and buried underground is joined to the channel member located on the most downstream side of the fishway main body formed by sequentially joining a plurality of channel members, while the most upstream When adopting a structure that joins the end of the pipe-shaped channel member that is eventually communicated with the paddy field to the channel member located on the side, There is an advantage that unicycles and the like can be run without hindrance on the roads between them to facilitate the farm work.
In addition, such a configuration has a relatively small ridge width, and even when there is a large drop between the water level of the drainage channel and the water level of the reservoir, an appropriate overflow section and overflow depth can be set according to the drop. The fishway you have can be reasonably constructed. Furthermore, such a pipe-shaped water channel member can function as an evacuation site for fish, for example, in the daytime.
[0171]
(6) When a channel member having a bottomed box shape closed at the circumferential wall portion with the upper end open is formed into a bottomed cylindrical box shape with an upper end open, for example, a case of a rectangular box shape In contrast, since there are few positional restrictions when the upstream opening and the downstream opening are provided in the wall, when the flow direction of water passing through both openings is bent, the upstream opening and the downstream opening are There is an advantage that it can be easily formed according to the bending angle.
[0172]
(7) A joint fitting for forming the water channel member into a U-shaped groove shape having an open upper end, enlarging the water channel width of the upstream side portion thereof, and fitting a joint portion forming the downstream side portion of the water channel member. When a structure in which a support base that supports the lower surface of the joint portion from below is provided at the bottom of the water channel in the upstream portion of the water channel member, the following special effects are obtained. That is,
[0173]
{Circle around (1)} A stagnation place is formed on the bottom side of the water channel by the support base, and it can be used as a habitat for benthic organisms.
[0174]
{Circle around (2)} Also, the bottom side of the water channel formed by the support base becomes a mud pool, and fine soil such as sludge flowing through the fishway can be deposited. Thereby, organic substances such as fertilizer components can be precipitated. In addition, the growth of aquatic plants and the like from the sedimentary soil captures organic matter in the aqueduct water and purifies the water quality. Therefore, it can contribute to the prevention of river pollution by organic matter.
[0175]
(3) A gap can be formed below the joint inserted in the joint fitting part, and this gap can be used as a habitat for benthic organisms that prefer shade, and also as a refuge for fry. obtain. In particular, by making the surface side of the void part a surface on which natural stones are exposed, algae can be propagated to provide a good feeding ground for benthic organisms.
[0176]
(4) Since the support base can support the lower surface of the joint portion from below, it is easy to lay adjacent water channel members with a required step using the support base as a ruler.
[0177]
(8) When the support base is configured separately from the water channel member and the support base is retrofitted to the water channel member, the adjacent water channel is fixed by fixing the support base of the required height to the water channel member. There is an advantage that the laying step of the member can be adjusted as required. Further, the manufacturing cost of the water channel member can be reduced as compared with the case where the water channel members having different support base heights are integrally formed.
[0178]
(9) When the support base is formed integrally with the channel member, the auxiliary support base is stacked to form a support base of the required height, or a support base separate from the channel member is retrofitted to the channel member. When forming a support base by stacking a plurality of support base pieces, the following effects can be obtained. That is, when the fish going up the fishway is large, by increasing the height of the support base as a result of the stacking of the auxiliary support base, the laying step between adjacent waterway members can be increased, and accordingly By reducing the number of water channel members used, the fish run-up structure can be constructed economically.
For example, when there is a drop of about 600 mm between the drainage channel and the reservoir, if the distance between the lower surface of the water channel member and the upper surface of the support base is 150 mm, the water channel member must be installed in four stages. On the other hand, if this distance is 200 mm, it will be possible to cope with a three-stage water channel member.
[0179]
(10) Further, in the case where the support base is provided in this way, the support base is provided before and after the length direction of the water channel, and the support base positioned on the upstream side is configured to be lower than the support base positioned on the downstream side. In some cases, there is an advantage that the laying step of adjacent waterway members can be changed by selecting the support base.
[0180]
(11) By forming the bottom surface part of the water channel member, and further the side surface part on the surface where the natural stone is exposed, it becomes possible to breed algae on the natural stone surface, It can also serve as a feeding ground for small fish and benthic organisms.
[0181]
(12) When the dam plate is constituted by a dam plate body provided with a notch and a slide adjustment plate provided so as to cover the lower part of the notch, By adjusting the height in the vertical direction, the height of the overflow section as the upper end of the slide adjustment plate can be adjusted so that the fish relative to the downstream water level depends on the difference between the water level of the reservoir and the water level of the drainage channel. It is easy to set to an appropriate height that can be run up.
For example, as shown in FIG. 4, when the barrier plate is formed only with a plate body provided with a notch portion, the depth of the notch portion is increased by cutting with a cutter or the like. Although adjustment is required, when a slide adjustment plate is used, there is an advantage that the height adjustment of the overflow section can be easily and reliably performed without any such troublesome adjustment.
[0182]
(13) In the case where the water channel member is configured in a U-shaped groove shape, when the weir plate that is detachably attached to the downstream portion is formed so that the downstream surface thereof is flush with the lower end surface of the water channel member, It is possible to prevent the fish going up the fishway from being caught and damaged by the corner of the lower end of the waterway member.
[0183]
(14) When the partition wall to be detachably attached to the drainage channel is constituted by a partition wall body provided with a notch and a slide type adjustment plate attached so as to cover the lower part of the notch In addition, there is an advantage that the height of the overflow section that allows fish to run up can be easily and reliably adjusted according to the volume of the drainage channel.
[0184]
(15) In the case where a drainage hole is provided on the dam plate attached to the drainage channel below the overflow part, the overflow part is released by opening the drainage hole to release water. In addition to the falling water in the water, the release of water from the drain hole is added, so that it can be expected that the fish can be guided to the overflow part (overflow notch part) by feeling their flow.
[0185]
(16) When the partition provided in the drainage channel is constructed with the front plate of the scouring prevention block that is constructed by standing the front plate and the rear plate before and after the bottom plate, the overflow section (overflow notch) Even if the water falls through the part), the bottom of the drainage channel is protected by the bottom plate, so that scouring of the bottom of the channel can be prevented. In addition, since a deeper part where the water channel bottom is dug down is formed on the downstream side of the overflow notch, when the fish goes up the overflow notch, it is easy to add momentum depending on the depth. There is an advantage that you can go up. Furthermore, since the space between the front plate and the rear plate of the scouring prevention block is a mud pool, fine soil containing organic matter such as fertilizer components such as flowing into the drainage channel from the paddy field through the fishway It can be deposited to purify water. In this case, the water purification effect in the drainage channel can be improved by accommodating a filtering material such as straw or rice husk in the empty space.
[0186]
(17) In particular, when a scouring prevention block is installed on the downstream side of the fishway and a configuration is adopted in which the filter medium is accommodated in the empty space, organic substances such as fertilizer components that flow into the drainage channel from the paddy field through the fishway are removed. There is an advantage that the contained fine soil can be filtered with the filter medium, and the water quality of the drainage can be purified accordingly.
[0187]
(18) When the upper side of the fishway is covered with a prevention net or a transparent covering material as shown in FIG. 16, it is possible to prevent the fish going up the fishway from jumping out of the fishway, and the fish can be caught during Can be prevented from being preyed on.
[0188]
(19) If the downstream side of the overflow part of the weir plate is formed as an arc surface, or the downstream part is formed as an inclined surface inclined downward at an angle of 13 to 60 degrees, the notch It is possible to prevent fish traveling up the section from being caught and damaged by the corners of the overflow section. In this case, such a catch can be more effectively prevented by setting the inclination angle of the inclined surface to 35 to 45 degrees.
This means that when the notch provided in the dam plate is covered with a slide adjustment plate, the downstream edge portion of the notch and the downstream portion of the overflow section as the upper end of the slide adjustment plate are The same applies to the case of forming the same arc surface or inclined surface.
Furthermore, in the case where a partition wall is provided in the drainage channel, the downstream side portion of the overflow portion that forms the upper end of the partition wall is similarly formed, and the partition wall is provided with a notch, and the notch When the lower part of the cover is covered with a slide-type adjusting plate, the downstream part of the overflow section and the downstream edge part of the notch part that form the upper end of the adjusting plate are The same applies when formed on an inclined surface.
[0189]
(20) In the case where the upper end side of the fish-guided string drifting in the water flowing through the fishway is attached to the dam, there is an advantage that the fish going up the fishway can be effectively guided to the overflow notch. is there.
[0190]
(21) In addition, in the case where the aquatic laces are arranged at an appropriate interval in the width direction at the bottom of the drainage channel, a state in which aquatic plants grow on the bottom part of the drainage channel can be formed. The body can function as an aid for spawning and growing fish.
[Brief description of the drawings]
FIG. 1 is an overall perspective view showing a fish run-up structure according to the present invention.
FIG. 2 is a cross-sectional view thereof.
FIG. 3 is a plan view thereof.
FIG. 4 is a perspective view showing a water channel member used therewith together with a dam plate.
FIG. 5 is a perspective view showing the water channel member.
FIG. 6 is a plan view showing the water channel member.
FIG. 7 is a cross-sectional view showing a joined state of water channel members.
FIG. 8 is a cross-sectional view showing the configuration of the weir plate together with the overflow state.
FIG. 9 is a perspective view for explaining the action of the formed fishway.
FIG. 10 is a cross-sectional view for explaining the action of the formed fishway.
FIG. 11 is a partial perspective view illustrating the configuration of the drainage channel.
FIG. 12 is a partial perspective view illustrating another configuration of the drainage channel.
FIG. 13 is a cross-sectional view showing a fish-guide string in use.
FIG. 14 is a perspective view showing a string for guiding fish.
FIG. 15 is a perspective view showing a state in which the weir plate of the fishway is removed and the water in the paddy field is drained into the drainage channel.
FIG. 16 is a perspective view showing a state in which the fishway is covered with a prevention net.
FIG. 17 is a perspective view showing a water channel member and a support frame that supports a prevention net.
FIG. 18 is a cross-sectional view showing a state in which the support frame is attached to the water channel member.
FIG. 19 is a cross-sectional view showing another aspect of the fish run-up structure according to the present invention together with the action.
FIG. 20 is a cross-sectional view showing a joining state of a water channel member on the most upstream side and an intermediate water channel member.
FIG. 21 is a perspective view showing a water channel member and a dam plate attached to the water channel member.
FIG. 22 is an exploded perspective view showing a weir plate on the upstream end side of the water channel member on the most upstream side.
FIG. 23 is an exploded perspective view showing a dam plate mounted on the downstream side of the water channel member.
FIG. 24 is a perspective view showing an example of the height adjustment state of the slide adjustment plate in the dam plate mounted on the downstream side of the water channel member.
FIG. 25 is a perspective view showing another example of the height adjustment state of the slide adjustment plate in the dam plate mounted on the downstream side of the water channel member.
FIG. 26 is a cross-sectional view showing a mounting state of the dam plate with the slide adjustment plate removed.
FIG. 27 is a plan view showing another aspect of the fish run-up structure according to the present invention.
FIG. 28 is a cross-sectional view thereof.
FIG. 29 is a cross-sectional view showing a joining state of the water channel member on the most downstream side and the drainage channel in the fish upstream structure.
FIG. 30 is a perspective view for explaining a configuration on the most downstream side in the fish run-up structure.
FIG. 31 is a cross-sectional view illustrating the configuration of the most upstream side in the fish run-up structure.
FIG. 32 is a perspective view of the most upstream configuration of the fish run-up structure.
FIG. 33 is a plan view showing a fish run-up structure in which a partition wall is attached to the drainage channel.
FIG. 34 is a perspective view of the overflow portion of the partition wall in the fish upstream structure as viewed from the upstream side.
FIG. 35 is a perspective view of the overflow part of the partition wall in the fish run-up structure as seen from the downstream side.
FIG. 36 is an exploded perspective view showing the overflow part of the partition wall in the fish run-up structure.
FIG. 37 is a cross-sectional view showing a state where a weed-like string body is arranged at the bottom of the drainage channel.
FIG. 38 is a cross-sectional view showing a state in which a water drain hole provided in the partition wall of the drainage channel is closed.
FIG. 39 is a perspective view showing a state in which the partition wall of the drainage channel is configured using the scouring prevention block.
FIG. 40 is a cross-sectional view thereof.
FIG. 41 is a front view thereof.
FIG. 42 is a plan view thereof.
FIG. 43 is an overall perspective view illustrating another aspect of the fish upstream structure according to the present invention.
FIG. 44 is a cross-sectional view thereof.
FIG. 45 is a plan view thereof.
FIG. 46 is a perspective view showing a water channel member used therewith together with a weir plate.
FIG. 47 is a perspective view showing a water channel member used therewith together with a weir plate.
FIG. 48 is a cross-sectional view showing a communication state between a water channel member installed on the most downstream side and a drainage channel.
FIG. 49 is a cross-sectional view showing a joined state of an intermediate water channel member and a most downstream water channel member.
FIG. 50 is a cross-sectional view showing a joining state of the water channel member on the most upstream side and the intermediate water channel member.
FIG. 51 is a perspective view for explaining a formed fishway.
FIG. 52 is a cross-sectional view showing a use state of the formed fishway.
FIG. 53 is an overall perspective view showing another aspect of the fishway run-up structure according to the present invention.
FIG. 54 is a plan view thereof.
FIG. 55 is a perspective view showing a formed fishway.
FIG. 56 is a perspective view showing a water channel member constituting the same.
FIG. 57 is a perspective view showing a water channel member constituting the same together with a weir plate.
FIG. 58 is a cross-sectional view showing a use state of the formed fishway.
FIG. 59 is a plan view showing the U-shaped waterway member in its use state.
FIG. 60 is an exploded perspective view showing another aspect of the water channel member.
FIG. 61 is a partial cross-sectional view thereof.
FIG. 62 is a partial cross-sectional view showing another aspect of the water channel member.
FIG. 63 is a partial cross-sectional view showing another aspect of the water channel member.
FIG. 64 is a partial cross-sectional view showing another aspect of the water channel member.
FIG. 65 is a partial plan view showing a fishway having overflow overflow notches arranged in a staggered pattern.
FIG. 66 is a cross-sectional view showing another aspect of the pipe-shaped water channel member.
FIG. 67 is a perspective view showing a conventional fish run-up structure.
[Explanation of symbols]
1 Fish run-up structure
2 Drainage channel
3 reservoirs
5 Buttocks
6 Fishway
7 Channel members
9 waterway
10 upstream opening
11 Downstream opening
12 joints
13 Joint fitting part
17 Support stand
23 Barrage
24 overflow section
25 Insertion groove
29 Insertion groove
30 Overflow notch
50 Bulkhead
52 Overflow notch
54 Overflow section
67 String
76 Support frame
77 Prevention Net
85 Weir body
86 Drop adjustment plate
87 Rectangular cutout
92 Mounting groove
95 Inclined surface
97 Dam body
99 Slide adjustment plate
111 inserts
112 volts
113 Adjustment hole
143 insert
144 Adjustment hole
146 Drain hole
147 water channel bottom
150 String
151 weight
152 Float
153 String
154 hair
156 Scour prevention block
157 Bottom plate
159 Front plate
160 Rear plate
169 Rectangular cutout
170 insert
172 bolts
180 wall
187 Insertion groove
191 Insertion groove
201 Insertion groove
202 Insertion groove

Claims (45)

排水路と、該排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を含み、該魚道を、水路部材の複数を順次接合して構成した貯水池への魚類遡上構造であって、
前記水路部材は、その水路の上流側部と下流側部に、上流側開口と下流側開口を具え、上流側に設置された該水路部材の下流側開口が、下流側に設置された該水路部材の上流側開口に連通するように水路部材相互が接合されると共に、最上流側に設置された前記水路部材の上流側開口が前記貯水池に連通され、且つ最下流側に設置された前記水路部材の下流側開口が前記排水路に連通されており、又、前記水路部材の水路の下流側部位に、水路水を嵩上げする堰板が着脱可能に装着され、該堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とする魚類遡上構造。
A fish run-up structure to a reservoir comprising a drainage channel, and a fishway for allowing fish to run up in a reservoir having a higher water level than the drainage channel, wherein the fishway is constructed by sequentially joining a plurality of channel members Because
The water channel member is provided with an upstream side opening and a downstream side opening at the upstream side and the downstream side of the water channel, and the downstream side opening of the water channel member installed on the upstream side is the water channel installed on the downstream side. The water channel members are joined so as to communicate with the upstream side opening of the member, and the upstream side opening of the water channel member installed on the most upstream side is communicated with the reservoir and the water channel installed on the most downstream side A downstream opening of the member communicates with the drainage channel, and a dam plate for raising the channel water is detachably attached to a downstream side portion of the water channel of the water channel member, and an overflow portion of the dam plate is provided. The fish run-up structure is characterized in that it is set at a height that allows fish to run up from the downstream water level.
前記水路部材は、上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成されると共に、その上流側の水路幅が拡大され、該水路部材の下流側をなす接合部を嵌め入れるための接合嵌合部とされており、該接合部が該接合嵌合部に嵌め入れられた状態において、前記接合部の前記接合嵌合部に対する、水路部材の長さ方向で見た挿入量を調節可能となされ、又該水路部材の水路の下流側部位に、前記堰板を着脱可能に嵌め入れるためのガイド部が設けられており、上流側に設置された水路部材の前記接合部が、下流側に設置された水路部材の前記接合嵌合部に嵌め入れられると共に、前記ガイド部に前記堰板が嵌め入れられていることを特徴とする請求項1記載の魚類遡上構造。The water channel member is formed in a U-shaped groove shape having an open upper end and a continuous water channel from the upstream end to the downstream end. It is set as the joint fitting part for inserting a junction part, and the length direction of a channel member to the joint fitting part of the joint part in the state where the joint part was inserted in the joint fitting part The amount of insertion seen in the above can be adjusted, and a guide part for detachably fitting the dam plate is provided in the downstream part of the water channel of the water channel member, and the water channel member installed on the upstream side The fish according to claim 1, wherein the joint portion is fitted into the joint fitting portion of a water channel member installed on the downstream side, and the dam plate is fitted into the guide portion. Run-up structure. 前記水路部材の上流側の部分の水路の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台が突設されていることを特徴とする請求項2記載の魚類遡上構造。The support stand which supports the lower surface of the said junction part of the water channel member installed in the upstream from the bottom part of the water channel of the upstream part of the said water channel member is protrudingly provided. Fish run-up structure. 排水路と、該排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を含み、該魚道を、水路部材の複数を順次接合して構成した貯水池への魚類遡上構造であって、
前記水路部材は、上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成されると共に、その上流側の水路幅が拡大され、該水路部材の下流側をなす接合部を嵌め入れるための接合嵌合部とされており、又該水路部材の水路の下流側部位の対向側面と底面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられ、又、前記水路部材の上流側の部分の水路の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台が突設され、更に、前記水路部材の水路の上流側部位の対向側面と底面に、前記貯水池の水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられており、
上流側に設置された水路部材の前記接合部が、下流側に設置された水路部材の前記接合嵌合部に、該接合部を前記支持台に載せた状態で嵌め入れられると共に、最上流側に設置された前記水路部材の上流側開口が前記貯水池に連通され、且つ最下流側に設置された前記水路部材の下流側開口が前記排水路に連通されており、
又、前記各嵌入溝に嵌め入れられた堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とする魚類遡上構造。
A fish run-up structure to a reservoir comprising a drainage channel, and a fishway for allowing fish to run up in a reservoir having a higher water level than the drainage channel, wherein the fishway is constructed by sequentially joining a plurality of channel members Because
The water channel member is formed in a U-shaped groove shape having an open upper end and a continuous water channel from the upstream end to the downstream end, and the upstream water channel width is expanded to form the downstream side of the water channel member. Insertion groove for detachably inserting a weir plate for raising the channel water on the opposite side surface and bottom surface of the downstream channel portion of the channel of the channel member. And a support base that protrudes from below to support the lower surface of the joint portion of the water channel member installed on the upstream side at the bottom of the water channel on the upstream side of the water channel member. On the opposite side surface and bottom surface of the upstream portion of the water channel of the member, a fitting groove for detachably fitting a weir plate for raising the water of the reservoir is provided,
The joint portion of the water channel member installed on the upstream side is fitted into the joint fitting portion of the water channel member installed on the downstream side in a state where the joint portion is placed on the support base, and the most upstream side An upstream opening of the water channel member installed in the reservoir is communicated with the reservoir, and a downstream opening of the water channel member installed on the most downstream side is communicated with the drainage channel;
The fish upstream structure is characterized in that the overflow portion of the weir plate fitted in each of the insertion grooves is set to a height at which the fish can run up with respect to the downstream water level.
前記支持台は、前記水路部材の上流側の部分の水路の底部に、水路の長さ方向の前後に所要間隔を置いて突設されており、より上流側に位置する支持台が、その下流側に位置する支持台よりも低い高さに設定されていることを特徴とする請求項3又は4記載の魚類遡上構造。The support base protrudes from the bottom of the water channel in the upstream portion of the water channel member with a required interval in the longitudinal direction of the water channel, and the support base positioned on the upstream side is downstream of the support channel. The fish run-up structure according to claim 3 or 4, characterized in that it is set to a height lower than that of the support table located on the side. 前記支持台が前記水路部材と別体に形成され、該支持台が水路部材に後付けされることを特徴とする請求項3、4又は5記載の魚類遡上構造。The fish upstream structure according to claim 3, 4 or 5, wherein the support base is formed separately from the water channel member, and the support base is retrofitted to the water channel member. 前記後付けされる支持台は、所要高さの支持台片を複数段に積重して構成されることを特徴とする請求項6記載の魚類遡上構造。The fish upstream structure according to claim 6, wherein the support base to be retrofitted is configured by stacking support base pieces having a required height in a plurality of stages. 前記水路部材の水路の下流側部位に前記堰板を着脱可能に嵌め入れる際、該堰板の外周面の下流端側が、前記水路の下流端の内周面に当接し、該堰板の下流側の面が前記水路部材の下流端面と面一となるように構成されていることを特徴とする請求項2又は4記載の魚類遡上構造。When the dam plate is detachably fitted into the downstream portion of the water channel of the water channel member, the downstream end side of the outer peripheral surface of the dam plate abuts the inner peripheral surface of the downstream end of the water channel, and the downstream of the dam plate The fish upstream structure according to claim 2 or 4, wherein a side surface is configured to be flush with a downstream end surface of the water channel member. 排水路と、該排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を含み、該魚道を、水路部材の複数を順次接合して構成した貯水池への魚類遡上構造であって、
前記水路部材は、上端開放で且つ周方向の壁部で閉じられた有底の箱状に形成されると共に、該壁部の上流側部の所要部位と下流側部の所要部位に、上流側開口と下流側開口が設けられており、上流側に設置された水路部材の前記下流側開口が、下流側に設置された水路部材の前記上流側開口に連通するように水路部材相互が接合され、該両開口の連通部分に、水路水を嵩上げする堰板が着脱可能に装着されており、
又、最上流側に設置された前記水路部材の上流側開口が前記貯水池に連通され、且つ最下流側に設置された前記水路部材の下流側開口が前記排水路に連通されており、前記堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とする魚類遡上構造。
A fish run-up structure to a reservoir comprising a drainage channel, and a fishway for allowing fish to run up in a reservoir having a higher water level than the drainage channel, wherein the fishway is constructed by sequentially joining a plurality of channel members Because
The water channel member is formed in a box shape with a bottom that is open at the upper end and closed by a circumferential wall portion, and the upstream side of the required portion of the upstream side portion and the downstream side portion of the wall portion. An opening and a downstream opening are provided, and the water channel members are joined together so that the downstream opening of the water channel member installed on the upstream side communicates with the upstream opening of the water channel member installed on the downstream side. In addition, a dam plate for raising the water channel water is detachably attached to the communicating portion of both openings,
The upstream opening of the water channel member installed on the most upstream side communicates with the reservoir, and the downstream opening of the water channel member installed on the most downstream side communicates with the drainage channel, and the weir A fish run-up structure characterized in that the overflow section of the board is set at a height that allows fish to run up from the downstream water level.
上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材の前記上流側開口に、上流側に設置された前記水路部材の下流側部分が挿入され、その挿入量が調節可能となされると共に、前記水路部材の前記下流側開口に、下流側に設置された前記水路部材の上流側部分が挿入され、その挿入量が調節可能となされていることを特徴とする請求項9記載の魚類遡上構造。The downstream portion of the water channel member installed on the upstream side is inserted into the upstream side opening of the water channel member that has a bottomed box shape that is open at the top and closed by a circumferential wall, and the amount of insertion The upstream portion of the water channel member installed downstream is inserted into the downstream opening of the water channel member, and the insertion amount is adjustable. The fish run-up structure according to claim 9. 上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材の水路に、前記上流側開口と前記下流側開口間を仕切るように、水路水を嵩上げする中間の堰板が着脱可能に装着され、該中間の堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とする請求項9又は10記載の魚類遡上構造。An intermediate weir that raises the channel water so as to partition the upstream side opening and the downstream side opening into the channel of the channel member having a bottomed box shape that is open at the upper end and closed by a circumferential wall. The fish according to claim 9 or 10, wherein a plate is detachably mounted, and an overflow portion of the intermediate dam plate is set to a height at which the fish can run up with respect to a downstream water level. Run-up structure. 上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材の水路に、前記上流側開口と前記下流側開口間を複数に仕切るように、水路水を嵩上げする中間の堰板の複数が着脱可能に装着され、該各中間の堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とする請求項9又は10記載の魚類遡上構造。An intermediate for raising the water of the water channel so that the upstream side opening and the downstream side opening are divided into a plurality of channels in the water channel of the channel member having a bottomed box shape that is open at the upper end and closed by the circumferential wall portion. A plurality of the dam plates are detachably mounted, and the overflow portion of each intermediate dam plate is set to a height at which fish can run up with respect to the downstream water level. Or the fish run-up structure of 10. 上端開放で且つ周方向の壁部で閉じられた有底の箱状を呈する前記水路部材の前記上流側開口と下流側開口は、該両開口を通過する水の流れ方向が屈曲するように前記壁部に設けられていることを特徴とする請求項9、10、11又は12記載の魚類遡上構造。The upstream side opening and the downstream side opening of the water channel member that has a bottomed box shape that is open at the top and closed by a circumferential wall portion are arranged so that the flow direction of water passing through both the openings is bent. The fish run-up structure according to claim 9, wherein the fish run-up structure is provided on a wall portion. 前記堰板の、前記越流部の下流側が円弧面に形成されていることを特徴とする請求項1〜13のいずれかに記載の魚類遡上構造。The fish upstream structure according to any one of claims 1 to 13, wherein a downstream side of the overflow portion of the barrier plate is formed in an arc surface. 前記堰板の、前記越流部の下流側が13〜60度の角度で下方に傾斜する傾斜面に形成されていることを特徴とする請求項1〜13のいずれかに記載の魚類遡上構造。The fish upstream structure according to any one of claims 1 to 13, wherein the downstream side of the overflow section of the barrier plate is formed on an inclined surface inclined downward at an angle of 13 to 60 degrees. . 排水路と、該排水路の水位よりも高い水位を有する水田に魚類を遡上させるための魚道を含む魚類遡上構造であって、
該魚道は、水路部材の複数を、前記排水路と前記水田との間をなす畦部の延長方向に順次接合して魚道本体を形成すると共に、該魚道本体を構成するために最下流側に設置された水路部材に設けた下流側開口に、前記排水路に連通され且つ地下埋設されたパイプ状の水路部材の上流側の端部分が接合される一方、前記魚道本体を構成する最上流側に設置された水路部材の上流側開口に、水田に結果的に連通される水路部材の下流側の端部分が接合されており、又、前記魚道本体を構成する前記水路部材の夫々に、水路水を嵩上げする堰板が着脱可能に装着され、該堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とする魚類遡上構造。
A fish run-up structure including a drainage channel and a fishway for allowing fish to run up to a paddy field having a higher water level than the drainage channel,
The fishway forms a fishway body by sequentially joining a plurality of waterway members in the extending direction of the eaves part between the drainage channel and the paddy field, and on the most downstream side to constitute the fishway body. An upstream end portion of a pipe-shaped water channel member that communicates with the drainage channel and is buried underground is joined to a downstream side opening provided in the installed water channel member, while the most upstream side constituting the fishway body The downstream end portion of the water channel member that eventually communicates with the paddy field is joined to the upstream opening of the water channel member installed in the water channel member, and each of the water channel members that constitute the fishway body has a water channel A fish upstream structure characterized in that a dam plate for raising water is detachably mounted, and the overflow portion of the dam plate is set at a height that allows fish to run upstream relative to the downstream water level.
排水路と、該排水路の水位よりも高い水位を有する水田に魚類を遡上させるための魚道を含む魚類遡上構造であって、
該魚道は、水路部材の複数を、前記排水路と前記水田との間をなす畦部の延長方向に順次接合して魚道本体を形成すると共に、該魚道本体を構成するために最下流側に設置された水路部材に設けた下流側開口に、前記排水路に連通され且つ地下埋設されたパイプ状の水路部材の上流側の端部分が接合される一方、前記魚道本体を構成する最上流側に設置された水路部材の上流側開口に、水田に結果的に連通され且つ地下埋設されたパイプ状の水路部材の下流側の端部分が接合されており、又、前記魚道本体を構成する前記水路部材の夫々に、水路水を嵩上げする堰板が着脱可能に装着され、該堰板の越流部を、下流側の水位に対して魚類が遡上可能な高さに設定したことを特徴とすることを特徴とする魚類遡上構造。
A fish run-up structure including a drainage channel and a fishway for allowing fish to run up to a paddy field having a higher water level than the drainage channel,
The fishway forms a fishway body by sequentially joining a plurality of waterway members in the extending direction of the eaves part between the drainage channel and the paddy field, and at the most downstream side to constitute the fishway body. An upstream end portion of a pipe-shaped water channel member that communicates with the drainage channel and is buried underground is joined to a downstream side opening provided in the installed water channel member, while the most upstream side constituting the fishway body The downstream end portion of the pipe-shaped water channel member that is communicated with the paddy field and buried underground is joined to the upstream side opening of the water channel member installed in the water channel member, and constitutes the fishway body. Each of the water channel members is detachably mounted with a dam plate that raises the water of the water channel, and the overflow portion of the dam plate is set to a height that allows fish to run up to the downstream water level. A fish run-up structure characterized by
前記パイプ状水路部材は、略水平に配設されていることを特徴とする請求項16又は17記載の魚類遡上構造。The fish run-up structure according to claim 16 or 17, wherein the pipe-shaped channel member is disposed substantially horizontally. 前記堰板に、前記魚道を流れる水に漂う魚類誘導用の紐状物の上端側が取り付けられていることを特徴とする請求項1〜18のいずれかに記載の魚類遡上構造。The fish upstream structure according to any one of claims 1 to 18, wherein an upper end side of a string for guiding fish drifting in the water flowing through the fishway is attached to the dam plate. 前記堰板は、水路部材に着脱可能に装着される堰板本体と該堰板本体に付設されるスライド調整板とからなり、該堰板本体は、上端開放の切欠部が設けられると共に、前記スライド調整板は、前記切欠部の下側部分を覆うように前記堰板本体に当接状態に且つ上下方向でスライド可能に付設されるものであり、該スライド調整板の上端が前記越流部とされ、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該スライド調整板の上下方向のスライド状態を調整でき且つ該調整状態で該スライド調整板を前記堰板本体に固定可能としたことを特徴とする請求項1、2、4又は9、16又は17記載の魚類遡上構造。The dam plate comprises a dam plate body detachably attached to the water channel member and a slide adjustment plate attached to the dam plate body, and the dam plate body is provided with a notch portion having an open upper end, and The slide adjustment plate is attached to the main body of the barrier plate so as to be slidable in the vertical direction so as to cover the lower portion of the notch, and the upper end of the slide adjustment plate is the overflow portion The slide adjustment plate can be adjusted in a vertical sliding state so that the overflow portion has a height that allows fish to run up with respect to the downstream water level, and the slide adjustment plate can be adjusted in the adjusted state. The fish run-up structure according to claim 1, 2, 4 or 9, 16 or 17, characterized in that the fish can be fixed to the dam plate body. 前記魚道を遡上する魚類が魚道の外に飛び出すのを防止すると共に、遡上中の魚類が鳥類に捕食されるのを防止するために、魚道の上側を防止ネットや透明被覆材で覆うことを特徴とする請求項1、2、4、9、16又は17記載の魚類遡上構造。Covering the upper side of the fishway with a prevention net or transparent covering to prevent the fish going up the fishway from jumping out of the fishway and preventing the fish going up the fish from being preyed on by the birds The fish run-up structure according to claim 1, 2, 4, 9, 16, or 17. 前記防止ネット又は透明被覆材は、前記水路部材に立設状態に設けた支持枠に被せられて、前記魚道の上側を覆うことを特徴とする請求項21記載の魚類遡上構造。The fish upstream structure according to claim 21, wherein the prevention net or the transparent covering material is covered with a support frame provided in a standing state on the water channel member to cover the upper side of the fishway. 前記排水路に、該排水路を流れる水を嵩上げする隔壁が着脱可能に装着されており、該隔壁は、前記排水路に着脱可能に装着される隔壁本体と該隔壁本体に付設される調整板とからなり、該隔壁本体は、上端開放の切欠部が設けられると共に、前記調整板は、前記切欠部の下側部分を覆うように前記隔壁本体に当接状態に且つ上下方向でスライド可能に付設されるものであり、該調整板の上端が前記越流部とされ、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該調整板の上下方向のスライド状態を調整でき且つ該調整状態で該調整板を前記隔壁本体に固定可能としたことを特徴とする請求項1、2、4、9、16又は17記載の魚類遡上構造。A partition wall for raising water flowing through the drainage channel is detachably mounted on the drainage channel, and the partition wall is detachably mounted on the drainage channel, and an adjustment plate attached to the partition wall body The partition wall body is provided with a notch portion having an open upper end, and the adjusting plate is in contact with the partition wall body and slidable in the vertical direction so as to cover a lower portion of the notch portion. The upper end of the adjustment plate is the overflow section, and the upper and lower portions of the adjustment plate are arranged so that the overflow section is at a height that allows fish to run up to the downstream water level. The fish run-up structure according to claim 1, 2, 4, 9, 16, or 17, wherein the sliding state of the direction can be adjusted, and the adjusting plate can be fixed to the bulkhead body in the adjusted state. 前記排水路に、該排水路を流れる水を嵩上げする隔壁が装着されており、該隔壁は、前記排水路における水の流れ方向に延長し且つ前記排水路の幅に略等しい幅を有する底板の上流側の端部に前板が立設されると共に、該底板の下流側の端部に後板が立設されてなる洗掘防止ブロックの該前板を以って形成されており、該前板の一部分が、下流側の水位に対して魚類が遡上可能な高さに設定された越流部とされていることを特徴とする請求項1、2、4、9、16又は17記載の魚類遡上構造。A partition for raising water flowing through the drainage channel is attached to the drainage channel, and the partition wall is a bottom plate extending in the direction of water flow in the drainage channel and having a width substantially equal to the width of the drainage channel. A front plate is erected on the upstream end, and a rear plate is erected on the downstream end of the bottom plate. A part of the front plate is an overflow section that is set to a height that allows fishes to run upstream relative to the downstream water level. The fish ascending structure described. 前記隔壁となる前板は、その一部をなす隔壁本体と、該隔壁本体に付設される調整板とからなり、該隔壁本体は、上端開放の切欠部が設けられると共に、前記調整板は、前記切欠部の下側部分を覆うように前記隔壁本体に当接状態に且つ上下方向でスライド可能に付設されるものであり、該調整板の上端が前記越流部とされ、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該調整板の上下方向のスライド状態を調整でき且つ該調整状態で該調整板を前記隔壁本体に固定可能としたことを特徴とする請求項24記載の魚類遡上構造。The front plate to be the partition is composed of a partition main body forming a part of the front plate, and an adjustment plate attached to the partition main body. The partition main body is provided with a notch portion having an open upper end. The upper end of the adjustment plate is the overflow portion, and is attached to the partition body so as to cover the lower portion of the notch so as to be in contact with the partition wall body, and the overflow portion. However, it is possible to adjust the sliding state of the adjustment plate in the vertical direction so that the fish can move up to the downstream water level, and to fix the adjustment plate to the bulkhead body in the adjustment state. 25. The fish run-up structure according to claim 24. 前記排水路に、前記魚道の下流側に位置させて洗掘防止ブロックが配設され、該洗掘防止ブロックは、前記排水路における水の流れ方向に延長し且つ前記排水路の幅に略等しい幅を有する底板の上流側の端部に、該排水路を流れる水を嵩上げする隔壁として機能する前板が立設されると共に、該底板の下流側の端部に後板が立設されてなり、該前板の一部分が、下流側の水位に対して魚類が遡上可能な高さに設定された越流部とされ、且つ前記前板と後板との間をなす空所に濾過材が収容されていることを特徴とする請求項1、2、4、9、16又は17記載の魚類遡上構造。A scouring prevention block is disposed in the drainage channel at the downstream side of the fishway, and the scouring prevention block extends in the direction of water flow in the drainage channel and is substantially equal to the width of the drainage channel. A front plate functioning as a partition for raising the water flowing through the drainage channel is erected at the upstream end portion of the bottom plate having a width, and a rear plate is erected at the downstream end portion of the bottom plate. And a part of the front plate is an overflow section set at a height that allows fish to run up to the downstream water level, and is filtered into a space between the front plate and the rear plate. The fish upstream structure according to claim 1, 2, 4, 9, 16, or 17, wherein a material is accommodated. 前記越流部の下流側が円弧面に形成されていることを特徴とする請求項23、24、25又は26記載の魚類遡上構造。27. The fish upstream structure according to claim 23, 24, 25, or 26, wherein a downstream side of the overflow section is formed in an arc surface. 前記越流部の下流側が、13〜60度の角度で下方に傾斜する傾斜面に形成されていることを特徴とする請求項23、24、25又は26記載の魚類遡上構造。27. The fish upstream structure according to claim 23, 24, 25 or 26, wherein a downstream side of the overflow section is formed on an inclined surface inclined downward at an angle of 13 to 60 degrees. 前記切欠部の下流側の縁部分が円弧面に形成されていることを特徴とする請求項20記載の魚類遡上構造。21. The fish run-up structure according to claim 20, wherein an edge portion on the downstream side of the notch is formed in an arc surface. 前記切欠部の下流側の縁部分を、13〜60度の角度で拡大するように、下流側に向けて傾斜する傾斜面に形成されていることを特徴とする請求項20記載の魚類遡上構造。21. The fish run-up according to claim 20, wherein an edge portion on the downstream side of the notch portion is formed on an inclined surface inclined toward the downstream side so as to expand at an angle of 13 to 60 degrees. Construction. 前記切欠部の下流側の縁部分が円弧面に形成されていることを特徴とする請求項23又は25記載の魚類遡上構造。26. The fish run-up structure according to claim 23 or 25, wherein an edge portion on the downstream side of the notch is formed in an arc surface. 前記切欠部の下流側の縁部分が、13〜60度の角度で拡大するように、下流側に向けて傾斜する傾斜面に形成されていることを特徴とする請求項23又は25記載の魚類遡上構造。26. The fish according to claim 23 or 25, wherein an edge portion on the downstream side of the notch portion is formed on an inclined surface inclined toward the downstream side so as to expand at an angle of 13 to 60 degrees. Run-up structure. 前記隔壁の、前記越流部の下側に位置させて水抜き孔を設けたことを特徴とする請求項23、24又は25記載の魚類遡上構造。26. The fish run-up structure according to claim 23, 24 or 25, wherein a drainage hole is provided in the partition wall below the overflow section. 前記排水路に、該排水路を流れる水を嵩上げする隔壁が着脱可能に装着され、該隔壁は、その一部分が、下流側の水位に対して魚類が遡上可能な高さに設定された越流部とされており、該越流部の下側に位置させて水抜き孔を設けたことを特徴とする請求項1、2、4、9、16又は17記載の魚類遡上構造。A partition for raising the water flowing through the drainage channel is detachably attached to the drainage channel, and a part of the partition wall is set to a height that allows fish to run up to the downstream water level. 18. The fish run-up structure according to claim 1, wherein the fish upstream structure is a flow part, and is provided with a drainage hole located below the overflow part. 前記排水路に、その幅方向に適宜間隔で、産卵育成用の水草状紐体が配置されており、該水草状紐体は、紐状体の一端に重りが設けられると共に、その他端に浮きが設けられ、該紐状体は、紐片の周面に50〜100mm程度の長さを有する毛片が多数設けられており、前記重りが前記排水路の底部に設置されていることを特徴とする請求項1、2、4、9、16又は17記載の魚類遡上構造。In the drainage channel, aquatic laces for laying eggs are arranged at appropriate intervals in the width direction. The aquatic lace is provided with a weight at one end of the lace and floats at the other end. The string-like body is provided with a large number of hair pieces having a length of about 50 to 100 mm on the peripheral surface of the string piece, and the weight is installed at the bottom of the drainage channel. The fish run-up structure according to claim 1, 2, 4, 9, 16, or 17. 排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、
上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成されると共に、その上流側の水路幅が拡大され、その下流側をなす接合部の全部又は一部を嵌め入れるための接合嵌合部が形成されており、又前記水路の下流側部位に、水路水を嵩上げする堰板を着脱可能に嵌め入れるためのガイド部が設けられ、又、前記水路の上流側の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台が突設されていることを特徴とする魚類遡上構造に用いる水路部材。
A waterway member that constitutes a fishway for moving fish up a reservoir having a water level higher than the water level of the drainage channel,
The upper end is open and the U-shaped groove has a continuous water channel from the upstream end to the downstream end, and the width of the upstream water channel is enlarged, and all or part of the junction forming the downstream side is formed. A joint fitting part for fitting is formed, and a guide part for detachably fitting a weir plate for raising the channel water is provided in a downstream part of the channel, and an upstream of the channel A water channel member for use in a fish run-up structure, characterized in that a support base for supporting the lower surface of the joint portion of the water channel member installed on the upstream side from the lower side is projected from the bottom on the side.
排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、
上端開放で且つ上流端から下流端に向かう連続する水路を有したU字溝状に形成されると共に、その上流側の水路幅が拡大され、その下流側をなす接合部の全部又は一部を嵌め入れるための接合嵌合部が形成されており、又前記水路の下流側部位に、その対向側面と底面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられ、又、前記水路の上流側の底部に、上流側に設置された水路部材の前記接合部の下面を下方から支持する支持台が突設されていることを特徴とする魚類遡上構造に用いる水路部材。
A waterway member that constitutes a fishway for moving fish up a reservoir having a water level higher than the water level of the drainage channel,
The upper end is open and the U-shaped groove has a continuous water channel from the upstream end to the downstream end, and the width of the upstream water channel is enlarged, and all or part of the junction forming the downstream side is formed. A joint fitting portion for fitting is formed, and a fitting groove for detachably fitting a weir plate for raising the channel water is provided on the opposite side surface and bottom surface of the downstream portion of the water channel. In addition, it is used for a fish upstream structure characterized in that a support base is provided on the bottom of the upstream side of the water channel to support the lower surface of the joint portion of the water channel member installed on the upstream side from below. Waterway member.
排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、
上端開放で且つ周方向の壁部で閉じられ、その内部が水路とされた有底の箱状に形成されると共に、該壁部の上流側の所要部位と下流側の所要部位に、上流側開口と下流側開口が設けられ、該上流側開口と下流側開口の内面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるためのガイド部が設けられており、又、前記水路の内面に、前記上流側開口と下流側開口間を仕切るように、水路水を嵩上げする中間の堰板を着脱可能に嵌め入れるためのガイド部が設けられており、前記各堰板の越流部が、下流側の水位に対して魚類が遡上可能な高さに設定されていることを特徴とする魚類遡上構造に用いる水路部材。
A waterway member that constitutes a fishway for moving fish up a reservoir having a water level higher than the water level of the drainage channel,
The upper end is open and closed with a circumferential wall, and the inside of the wall is formed into a bottomed box shape, and the upstream side of the wall and the downstream side An opening and a downstream opening are provided, and a guide portion is provided on the inner surface of the upstream opening and the downstream opening for detachably fitting a weir plate for raising the channel water. In addition, a guide part for detachably fitting an intermediate dam plate for raising the water channel water is provided so as to partition the upstream side opening and the downstream side opening, and the overflow part of each dam plate includes A channel member for use in a fish run-up structure, wherein the fish is set at a height that allows the fish to run up with respect to a downstream water level.
排水路の水位よりも高い水位を有する貯水池に魚類を遡上させるための魚道を構成する水路部材であって、
上端開放で且つ周方向の壁部で閉じられ、その内部が水路とされた有底の箱状に形成されると共に、該壁部の上流側の所要部位と下流側の所要部位に、上流側開口と下流側開口が設けられ、該上流側開口と下流側開口の、対向側面と底面に、水路水を嵩上げする堰板を着脱可能に嵌め入れるための嵌入溝が設けられており、又、前記水路の、対向側面と底面に、前記上流側開口と下流側開口間を仕切るように、水路水を嵩上げする中間の堰板を着脱可能に嵌め入れるための嵌入溝が設けられており、前記各堰板の越流部が、下流側の水位に対して魚類が遡上可能な高さに設定されていることを特徴とする魚類遡上構造に用いる水路部材。
A waterway member that constitutes a fishway for moving fish up a reservoir having a water level higher than the water level of the drainage channel,
The upper end is open and closed with a circumferential wall, and the inside of the wall is formed into a bottomed box shape, and the upstream side of the wall and the downstream side An opening and a downstream opening are provided, and an insertion groove for detachably fitting a weir plate for raising water channel water is provided on the opposite side surface and bottom surface of the upstream opening and the downstream opening, and An insertion groove for detachably fitting an intermediate dam plate for raising the water channel water is provided on the opposite side surface and the bottom surface of the water channel so as to partition the upstream side opening and the downstream side opening. A waterway member used for a fish upstream structure, characterized in that the overflow part of each weir plate is set to a height at which the fish can run upstream relative to the downstream water level.
前記上流側開口と前記下流側開口間を複数に仕切るように、その対向側面と底面に、水路水を嵩上げする中間の堰板の複数を着脱可能に嵌め入れるためのガイド部が設けられており、前記各堰板の越流部が、下流側の水位に対して魚類が遡上可能な高さに設定されていることを特徴とする請求項38記載の魚類遡上構造に用いる水路部材。In order to partition the upstream side opening and the downstream side opening into a plurality, a guide portion for detachably fitting a plurality of intermediate weir plates for raising the channel water is provided on the opposite side surface and the bottom surface. 39. The water channel member used in the fish upstream structure according to claim 38, wherein the overflow portion of each dam plate is set to a height at which the fish can run upstream relative to the downstream water level. 前記上流側開口と前記下流側開口間を複数に仕切るように、その対向側面と底面に、水路水を嵩上げする中間の堰板の複数を着脱可能に嵌め入れるための嵌入溝が設けられており、前記各堰板の越流部が、下流側の水位に対して魚類が遡上可能な高さに設定されていることを特徴とする請求項39記載の魚類遡上構造に用いる水路部材。An insertion groove for detachably fitting a plurality of intermediate weir plates for raising water channel water is provided on the opposite side surface and bottom surface so as to divide the upstream opening and the downstream opening into a plurality. 40. The water channel member used in the fish upstream structure according to claim 39, wherein the overflow part of each dam plate is set to a height at which the fish can run up with respect to the downstream water level. 前記水路部材の前記上流側開口と前記下流側開口は、該両開口を通過する水の流れ方向が屈曲するように前記壁部に設けられていることを特徴とする請求項37、38又は39記載の魚類遡上構造に用いる水路部材。40. The upstream opening and the downstream opening of the water channel member are provided in the wall portion so that a flow direction of water passing through both the openings is bent. A waterway member used for the described fish run-up structure. 前記堰板の前記越流部の下流側が円弧面に形成されていることを特徴とする請求項36、37、38、39又は40記載の魚類遡上構造に用いる水路部材。41. The water channel member used for a fish upstream structure according to claim 36, 37, 38, 39 or 40, wherein a downstream side of the overflow portion of the dam plate is formed in an arc surface. 前記堰板の前記越流部の下流側が13〜60度の角度で下方に傾斜する傾斜面に形成されていることを特徴とする請求項36、37、38、39又は40記載の魚類遡上構造に用いる水路部材。41. The fish run-up according to claim 36, 37, 38, 39 or 40, wherein a downstream side of the overflow portion of the dam plate is formed on an inclined surface inclined downward at an angle of 13 to 60 degrees. Waterway member used for structure. 前記堰板は、水路部材に着脱可能に装着される堰板本体と該堰板本体に付設されるスライド調整板とからなり、該堰板本体は、上端開放の切欠部が設けられると共に、前記スライド調整板は、前記切欠部の下側部分を覆うように前記堰板本体に当接状態に且つ上下方向でスライド可能に付設されるものであり、該スライド調整板の上端が前記越流部とされ、該越流部が、下流側の水位に対して魚類が遡上可能な高さとなるように、該スライド調整板の上下方向のスライド状態を調整でき且つ該調整状態で該スライド調整板を前記堰板本体に固定可能としたことを特徴とする請求項36、37、38、39又は40記載の魚類遡上構造に用いる水路部材。The dam plate comprises a dam plate body detachably attached to the water channel member and a slide adjustment plate attached to the dam plate body, and the dam plate body is provided with a notch portion having an open upper end, and The slide adjustment plate is attached to the main body of the barrier plate so as to be slidable in the vertical direction so as to cover the lower portion of the notch, and the upper end of the slide adjustment plate is the overflow portion The slide adjustment plate can be adjusted in a vertical sliding state so that the overflow portion has a height that allows fish to run up with respect to the downstream water level, and the slide adjustment plate can be adjusted in the adjusted state. 41. The water channel member used in a fish run-up structure according to claim 36, 37, 38, 39 or 40, characterized in that can be fixed to the dam plate body.
JP2002282263A 2002-06-12 2002-09-27 Fish run-up structure and waterway member used therefor Expired - Lifetime JP3721455B2 (en)

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JP4758882B2 (en) * 2006-12-22 2011-08-31 ランデス株式会社 Revetment block with fishway and construction method of revetment surface with fishway using the same
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KR101854709B1 (en) * 2014-09-25 2018-06-20 민승기 A waterway equipped with a water supply line
JP5901040B1 (en) * 2015-10-27 2016-04-06 誠一郎 安村 Riverbed unit and riverbed structure
KR101929421B1 (en) * 2016-12-09 2018-12-14 조용성 Movable weir having fish way interlocked with rock gate
CN115419028B (en) * 2022-09-26 2023-08-11 浙江省水利河口研究院(浙江省海洋规划设计研究院) Tidal estuary fishway with sinking rest pool and design method thereof

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