【0001】
【発明の属する技術分野】
本発明は台木用苗及び穂木用苗の茎部を切断し、切断された台木の茎部と穂木の茎部とをその切断個所で接合固定させる接木装置に関する。
【0002】
【従来の技術】
例えば台木及び穂木搬送機構の搬送中に切断機構で所定部を切断して接木位置まで移動したときにクリップで接合固定する技術がある。(例えば特許文献1参照)
【0003】
【特許文献1】特開平5−23051
【0004】
【発明が解決しようとする課題】
しかし乍上記の如き切断機構などによる台木及び穂木の切断の場合、切断面は通常略平滑状のものとなって、接合後の活着性も悪い。
【0005】
【課題を解決するための手段】
したがって本発明は、穂木用苗の茎部をV字状に切断する穂木切断手段と、台木用苗の子葉展開部をY字状に切断する台木切断手段と、穂木用苗のV字形切断面と台木用苗のY字形切断面を接合固定させる接合固定手段とを設けて、穂木用苗のV字形切断面と台木用苗のY字形切断面を良好に接合させて、活着性を向上させるもので、台木用苗のY字形切断面の縦切り部で穂木接合時の穂木用苗挿入を容易とさせると共に、縦切り部を挿入する穂木用苗先端の逃がしとさせて穂木及び台木用苗の正確な接合を可能とさせるものである。
【0006】
また、2枚のカッタをV字形に組合わせて、穂木切断用のV字形切断刃を形成させて、一定角度を保った穂木茎部の正確なV字形切断を容易に可能とさせて、接木作業の能率向上化を図るものである。
【0007】
さらに、3枚のカッタをY字形に組合わせて、台木切断用のY字形切断刃を形成させて、常に形状を一定とさせた台木茎部の正確なY字形切断を容易に可能とさせて、接木作業の能率向上化を図るものである。
【0008】
また、穂木用苗の茎部を保持する苗保持溝と、V字形切断刃の進入溝を形成する苗切断台を設けて、穂木用苗の茎部中心に対し左右対称な正確なV字形切断を可能とさせて接木精度を向上させるものである。
【0009】
さらに、台木用苗の茎部を保持する苗保持溝と、Y字形切断刃の進入溝を形成する苗切断台を設けて、台木用苗の茎部中心に対し左右対称な正確なY字形切断を可能とさせて接木精度を向上させるものである。
【0010】
【発明の実施の形態】
以下、本発明の実施例を図面に基づいて詳述する。図1は全体の側面図、図2は同正面図、図3は同平面図であり、接木装置1は半自動形に設け、前処理で断根したキュウリ或いはカボチャなどのウリ科やナスビ或いはジャガイモなどのナス科の苗の穂木用苗2及び台木用苗3を挟持する上下1組の穂木ハンド4及び台木ハンド5と、穂木及び台木ハンド4・5を装備して回転させる上下の回転円板6・7と、上下の回転円板6・7間を連結させるロッド軸8と回転円板6・7を間欠回転させるモータ9とを備えている。そして図4の平面視に示す如く、穂木及び台木ハンド4・5に苗2・3を投入操作する作業者10の作業座席11前位置の苗投入部12に対し、反時計方向に円板6・7を90度回転させた位置に苗切断機構13を有する苗切断部14を、また苗切断部14よりさらに90度回転させた位置に苗接合機構15を有する苗接合部16を、さらに苗接合部16より90度回転させた位置を接木苗の払出部17に設けて、これら投入部12・切断部14・接合部16・払出部17の4つの工程で穂木及び台木ハンド4・5の回転を停止させる間欠駆動をモータ9で行うように構成している。
【0011】
図4乃至図6に示す如く、上下1組とする穂木及び台木ハンド4・5の先端側を円板6外周より外側に突出させて90度間隔で4組を円板6・7に装備させたもので、上部円板6に穂木ハンド4を直接的に取り付けると共に、穂木ハンド4より一定高さ下方にロッド軸8を介して、上下動自在に台木ハンド5を支持させている。図6、図8、図10、図11にも示す如く、前記穂木及び台木ハンド4・5は固定ハンド部18と、固定ハンド部18に開閉支点軸19を介し揺動自在に連結する揺動ハンド部20とを有し、円板6・7の回転で揺動ハンド部20一端に設ける開閉ローラ21が円筒形穂木及び台木用固定ドラム22・23外側面の開閉カム24・25に当接するとき、バネ26に抗して揺動ハンド部20を揺動させて、穂木及び台木ハンド4・5を開とさせるように構成している。
【0012】
また図11に示す如く、前記台木用固定ドラム23の上端面を昇降カム27に設けて、台木ハンド5の固定ハンド部18下側に設置する昇降ローラ28を昇降カム27上に転接させ、回転軸29を中心として円板6・7と一体的に台木ハンド5を回転させるとき、昇降カム27によって台木ハンド5を昇降させるように構成している。なお、昇降カム27で穂木ハンド4を昇降させても良い。
【0013】
図8、図12に示す如く、前記穂木ハンド4の固定ハンド部18に穂木用苗2の子葉2a展開位置を基準として切断高さと切断方向を決定する子葉胚軸ストッパ30と子葉方向安定棒31とを一体的に設けて、穂木用苗2を手に持ち2葉を左右方向に展開させてハンド部18・20間に挿入するとき、胚軸26をストッパ30に当て、子葉2a展開部がストッパ30に当たるまで引き下げて把持を行うように構成している。
【0014】
図13に示す如く、前記台木ハンド5は台木用苗3の子葉3a展開位置を基準として切断高さと切断方向を決定する子葉胚軸ストッパ32と子葉方向安定板39とを備え、台木用苗3を手に持ち2葉を穂木子葉2aと直交する前後方向にしてハンド18・20間に挿入するとき、胚軸3bをストッパ32に当て、子葉3a展開部がストッパ32に当たるまで引き下げて把持を行うもので、接木装置1の投入作業台34側方に設ける作業スイッチ35の操作で各ハンド4・5が反時計方向に回転し始める瞬間に、固定ハンド部18が胚軸下部を押すと同時にボールプランジャ36及びバネ37を介して胚軸上部を押す直立支持棒38を設けて苗3の良好な把持を行う。さらに台木ハンド5が回転するときプランジャ36が固定ハンド部18を乗り越えて支持棒38は初期位置に戻ると共に、回転方向側に配置するゴム吊れ40で2葉の方向が修正され台木用苗3の把持姿勢の適正化が図られる。
【0015】
図6、図7に示す如く、前記開閉カム24・25は固定ドラム22・23の払出部17と投入部12位置間を凸状カム面24a・25aに形成して、各ハンド4・5の払出部17と投入部12間では開とさせて、苗2・3の投入や接木苗41の払出(放出)を行うように構成している。
【0016】
上記からも明らかなように、穂木用苗2の茎部である胚軸2bと台木用苗3の茎部である胚軸2bとを切断して接合固定する接木装置において、穂木用苗2及び台起用苗3をそれぞれ挟持する穂木ハンド4及び台木ハンド5の上下2段を1組として縦軸である回転軸29回りに複数組配設させ、回転軸29を中心として各ハンド4・5を回転させて複数工程の作業を行うと共に、複数工程の同時作業を行うことによって、回転軸29を中心とした複数組のハンド4・5回転中に接木作業に必要な切断・接合など複数工程の一連の作業を順次且つそれぞれの位置で同時に行って接木作業の能率向上化を図ることができる。
【0017】
また、子葉2a展開位置を基準として切断高さと切断方向を決定する子葉胚軸ストッパ30と子葉方向安定棒31とを穂木ハンド4に一体的に設けたことによって、穂木ハンド4に対する穂木用苗2の投入供給を容易とさせると共に、常に正確に苗位置保持させて穂木用苗2の切断精度を向上させることができる。
【0018】
さらに、子葉3a展開位置を基準として切断高さと切断方向を決定する子葉胚軸ストッパ32と子葉方向安定板39及び苗直立支持棒38を台木ハンド5に備えたことによって、台木ハンド5に対する台木用苗3の投入供給を容易とさせると共に、常に正確に位置保持させて台木用苗3の切断精度を向上させることができる。
【0019】
また、穂木ハンド4及び台木ハンド5の回転でもってハンド4・5を開閉する開閉カム24・25を設けることによって、ハンド4・5を開閉するためのシリンダなど別途の駆動部材を用いることなく、ハンド4・5回転を利用して容易にハンド4・5を開閉させることができる。
【0020】
さらに、穂木ハンド4及び台木ハンド5の回転でもって穂木ハンド4或いは台木ハンド5を昇降させる昇降カム27を設けたことによって、穂木或いは台木ハンド4・5を昇降させるシリンダなどの別途の駆動部材を用いることなく、ハンド4・5の回転を利用して容易にハンド4・5の昇降を可能とさせることができる。
【0021】
図14乃至図17にも示す如く、前記切断部14の苗切断機構13は、穂木用苗2の胚軸2bをV字状(クサビ状)に切断する左右1対のV字形穂木切断刃42と、台木用苗3の胚軸3bの子葉3a展開部をY字状に切断するY字形台木切断刃43とを備えるもので、2枚のカッタ44をカッタホルダ45のV字形苗に合わせて取り付け、カッタ44先端のV字形下端を接触させた状態で蝶ネジ46によってホルダ45に固定させ、各カッタ44の先端上側を先鋭部44aとさせたクサビ形状でV形の内面を略20度に形成して、前方位置の穂木切断台47に保持される穂木用苗2の胚軸2bに対し切断刃42を前進させて、胚軸26の略中間部を切断し、V字形切断面2cを形成するように構成している。
【0022】
また、前記切断台47は胚軸26を案内する苗保持溝48と、V形カッタ44を侵入案内させるカッタ進入溝49とを設け、保持溝48によって穂木用苗切断時の中心ズレを補正し、カッタ44の進入切断時には進入溝49の案内で苗2の抵抗があっても広がることなく正確なV字形の切断を行うように構成している。
【0023】
図16,図17に示す如く、前記台木切断刃43は下端を接する2枚のV形カッタ50と、V形カッタ50間下側に配置させる1枚の縦切りカッタ51とを組み合わせて専用ホルダ52に蝶ネジ46を介し固定させ、側面視でV形カッタ50の先端上側を先鋭部50aに、縦切りカッタ51の先端下側を先鋭部51aに形成して、側面視で切断刃43先端部をV形状に形成し、V形カッタ50の内角を略40度に形成し、前方位置の台木切断台53に保持される台木用苗3の胚軸3bに対し切断刃43を前進させて、胚軸3bの子葉3a展開部をY字形に切断しY字形切断面3cを形成すると同時に生長点3dを除去するように構成している。
【0024】
また、前記縦切りカッタ51の上端はV形カッタ50の下端より略0.5mm上方に突出させる状態とさせてV形カッタ50の切れ残しを解消させ、また苗3に形成される苗縦切り部3eで穂木接合時の穂木用苗2の挿入を容易とさせると共に、縦切り部3eを挿入する穂木用苗2先端の逃がしとさせて穂木及び台木用苗2・3の正確な接合を可能とさせるものであり、ホルダ52下部に固定する胚軸押え54のカッタ溝55によって、縦切りカッタ51の逃げなど防止するように構成している。
【0025】
さらに、前記切断台53は子葉3aの上部を押さえ込む子葉押え56を上方に、また下方に縦切りカッタ51の進入案内用ガイド溝57を有する苗押え58を備え、切断台53には胚軸3bを案内する苗保持溝59と、縦切りカッタ51の進入溝60とを設けると共に、子葉押え56にはV形カッタ50の案内となるカッタ進入溝61を略内角40度で設けている。
【0026】
上記からも明らかなように、穂木用苗2の茎部2bをV字状に切断する穂木切断手段であるV字形切断刃42と、台木用苗3の子葉3a展開部をY字状に切断する台木切断手段であるY字形切断刃43と、穂木用苗2のV字形切断面2cと台木用苗3のY字形切断面3cを接合固定させる接合固定手段である接合機構15とを設けたことによって、穂木用苗2のV字形切断面2cと台木用苗3のY字形切断面3cを良好に接合させて、活着性を向上させることができるもので、台木用苗3のY字形切断面3cの縦切り部3eで穂木接合時の穂木用苗2挿入を容易とさせると共に、縦切り部3eを挿入する穂木用苗2先端の逃がしとさせて穂木及び台木用苗の正確な接合を可能とさせることができる。
【0027】
また、2枚のカッタ44をV字形に組み合わせて、穂木切断用のV字形切断刃42を形成させたことによって、一定角度を保った穂木胚軸2bの正確なV字形切断を容易に可能とさせて、接木作業の能率向上化を図ることができる。
【0028】
さらに、3枚のカッタ50・51をY字形に組み合わせて、台木切断用のY字形切断刃43を形成させたことによって、常に形状を一定とさせた台木胚軸3bの正確なY字形切断を容易に可能とさせて、接木作業の能率向上化を図ることができる。
【0029】
また、穂木用苗2の胚軸2bを保持する苗保持溝48と、V字形切断刃42の進入溝49を形成する苗切断台47を設けることによって、穂木用苗2の胚軸2b中心に対し左右対称な正確なV字形切断を可能とさせて接木精度を向上させることができる。
【0030】
さらに、台木用苗3の胚軸3bを保持する苗保持溝59と、Y字形切断刃43の進入溝60を形成する苗切断台53を設けたことによって、台木用苗3の胚軸3b中心に対し左右対称な正確なY字形切断を可能とさせて接木精度を向上させることができる。
【0031】
図18乃至図20に示す如く、穂木用苗2と台木用苗3とをスリーブ62で接合固定させる前記接合機構15には、一定長さにスリーブ62を切断して供給するスリーブ供給機構63と、供給されるスリーブ62をスリーブハンド64により押し広げて接木苗41に装着させるスリーブ装着機構64と、スリーブ62の装着時に台木用苗3の子葉3aを掻上げる掻上げ機構65とを備えるもので、前記供給機構63には連続成型でリール66に収納されたスリーブ62をスリーブガイド67に繰出す左右1対の送りローラ68と、スリーブ62の当接するストッパ69を有する旋回部材70と、スリーブ62の当接による旋回部材70の回転を検出する光電式スリーブセンサ71と、送りローラ68を回転させセンサ71によるスリーブ検出時に送りローラ68の回転を停止させる送りモータ72と、スリーブ62の送り停止時にスリーブ62を一定長さ(12mm)に切断するスリーブカッタ73とを設け、スリーブガイド67のガイド棒67aに沿って切欠き部67bまでスリーブ62が下動するときカッタ台74を前進させてカッタ73で一定長さにスリーブ62を切断するように構成している。
【0032】
また、前記スリーブ62は接木苗41の成長に伴い、自然脱落するためのスリット75と、スリット75を押し広げるための突起76とを有して、接木苗41の成長時には自然脱落すると共に、脱落後は数ヶ月で生分解する軟弾性のセルロースやトウモロコシなどの素材を用い、質量が軽く半透明に形成して、接合状態を外部からも容易に確認するように構成している。
【0033】
図9、図20に示す如く、前記スリーブ装着機構64は、スリーブ62の突起76を掴んで開閉する左右フック77aを有するスリーブハンド77、スリット75と反対側のスリーブ62外面を支えるプッシャ78と、スリーブハンド77を開閉させる開閉操作部79と、スリーブハンド77を前後進させる空圧式シリンダ80と、プッシャ78と前後進させる空圧式シリンダ81と、接木苗41の位置ズレなどを修正するストッパ82とを備えている。
【0034】
そして図21に示す如く、前記供給機構63で一定長さに切断されたスリーブに対し、フック77aを開いて接近させ、フック77aを閉じてプッシャ78を前進させるときフック77aをスリーブ62の突起76間に挿入させ、フック77aを開くときスリーブ62を押し広げて接木苗41に前進接近させ、ハンド77が接木苗41位置となりフック77aを閉じるとき苗41にスリーブ62を装着させ、プッシャ78を後退させフック77aをスリーブ62から離し、フック77aを開いてハンド77を接木苗41から後退させて苗41を解放することでスリーブ62の装着を完了させるように構成している。なお上述実施例にあってはフック77aのスリーブ62に対する挿脱時にはプッシャ78を前後進させる構成を示したが、ハンド77を後退或いは前進させて同様の操作を行う構成でも良い。
【0035】
図22に示す如く、前記掻上げ機構65は、接木苗41にスリーブ62装着時に台木用苗3の子葉3aを上方に掻上げる左右1対のローラ83と、ローラ83を左右方向に開閉する開閉部84と、ローラ83を昇降させる空圧式昇降シリンダ85と、ローラ83を前後進させる前後進シリンダ86とを備え、スリーブ62の装着時にローラ83を接木苗41位置まで接近させ、左右ローラ83を閉状態で上昇させるとき、ローラ83で子葉3aを上方に掻上げて、子葉3aを邪魔とさせることのない確実なスリーブ62の装着を行うように構成している。
【0036】
また図23に示す如く、苗接合部16と払出部17間の穂木及び台木ハンド4・5の移動径路中に、接木苗41の全長を一定長さに調整切断する調整カッタ87をカッタ台88を介し配設させて、払出直前で台木用苗3の胚軸3bを水平切断させ一定高さの接木苗41を生産して苗品質を向上させるように構成している。
【0037】
上記からも明らかなように、穂木用苗2のV字形切断面2cと台木用苗3のY字形切断面3cとを接合固定させる接ぎ具であるスリーブ62を設けると共に、接木及び台木用苗2・3に接ぎ具62装着時台木用苗3の子葉3aを掻上げる掻上げ部材であるローラ83を設けたことによって、スリーブ62装着時に台木用苗3の子葉3aを邪魔とさせることのない正確な装着作業を可能とさせて、スリーブ62の装着作業の効率向上化を図ることができる。
【0038】
また、円筒形のスリーブ62にスリット75を形成させると共に、スリーブ62をスリット75により押し広げる拡張部材であるスリーブハンド77を設けたことによって、スリーブ62を常に一定巾に押し広げて接木苗41に確実に装着可能とさせて、スリーブ62の装着性を向上させることができる。
【0039】
さらに、スリーブ62により接合させた穂木用苗2と台木用苗3の接木苗41を一定長さに調整切断する調整切断機構である調整カッタ87を設けたことによって、スリーブ62装着後の接木苗41の一定高さの調整が払出直前に容易に行われて苗品質を向上させることができる。
【0040】
また、穂木用苗2のV字形切断面2cと台木用苗3のY字形切断面3cとを接合固定さえるスリーブ62を設けると共に、スリーブ62に生分解可能な材料を用いたことによって、接木苗41の成長に伴ってスリーブ62が自然脱落しても、生分解によって自然消滅してスリーブ62の回収など不要とさせて作業の効率化を図ることができる。
【0041】
さらに、スリーブ62はスリット75を有する略円筒形状に形成させたことによって、スリーブ62の拡張を容易とさせると共に、育苗潅水時に水溜まりができウイルスが発生するなどの不都合を防止して接木苗41の成長を助長させることができる。
【0042】
また、スリット75にはスリーブ62を押し広げる突起76を形成させたことによって、別途脱着部材などを用いて突起76を掴んでのスリーブ62の容易な押し広げを可能とさせてスリーブ62の確実な装着を可能とさせることができる。
【0043】
以上のように半自動の接木作業を行って、穂木子葉2aと台木子葉3aの展開方向が直交状態(十字状)となるように確実に接木して、日陰を発生せず日照を均一とさせて接木苗2・3の成長を促進させるものであり、図24に示す如く作業座席1に最接近する穂木及び台木ハンド4・5が苗投入部12に位置するとき、前処理で断根した穂木及び台木用苗2・3をそれぞれ各ハンド4・5に投入して挟持させ、挟持後は切断・接合・払出の一連の接木作業を自動で行うもので、前記モータ9の駆動によって苗2・3を挟持するハンド4・5が苗切断部14まで移動したとき、穂木切断刃42によって穂木用苗2の胚軸3bがV字形に、台木切断刃43によって台木用苗3の胚軸3bがY字形に切断され、次にハンド4・5が苗接合部16まで移動するときには、台木用苗3を上昇させて穂木用苗2を挿入すると共に、穂木用苗2を抱き込んだ台木用苗3の外側をスリーブ62で固定して接木苗41を形成させ、ハンド4・5が払出部17まで移動するときハンド4・5を解放して接木苗41を放出或いは取出すものである。
【0044】
【発明の効果】
以上実施例から明らかなように本発明は、穂木用苗2の茎部2bをV字状に切断する穂木切断手段42と、台木用苗3の子葉3a展開部をY字状に切断する台木切断手段43と、穂木用苗2のV字形切断面2cと台木用苗3のY字形切断面3cを接合固定させる接合固定手段15とを設けたものであるから、穂木用苗2のV字形切断面2cと台木用苗3のY字形切断面3cを良好に接合させて、活着性を向上させることができるもので、台木用苗3のY字形切断面3cの縦切り部3eで穂木接合時の穂木用苗2挿入を容易とさせると共に、縦切り部3eを挿入する穂木用苗2先端の逃がしとさせて穂木及び台木用苗の正確な接合を可能とさせることができるものである。
【0045】
また、2枚のカッタ44をV字形に組合わせて、穂木切断用のV字形切断刃42を形成させたものであるから、一定角度を保った穂木茎部2bの正確なV字形切断を容易に可能とさせて、接木作業の能率向上化を図ることができるものである。
【0046】
さらに、3枚のカッタ50・51をY字形に組み合わせて、台木切断用のY字形切断刃43を形成させたものであるから、常に形状を一定とさせた台木茎部3bの正確なY字形切断を容易に可能とさせて、接木作業の能率向上化を図ることができるものである。
【0047】
また、穂木用苗2の茎部2bを保持する苗保持溝48と、V字形切断刃42の進入溝49を形成する苗切断台47を設けたものであるから、穂木用苗2の茎部2b中心に対し左右対称な正確なV字形切断を可能とさせて接木精度を向上させることができるものである。
【0048】
さらに、台木用苗3の茎部3bを保持する苗保持溝49と、Y字形切断刃43の進入溝60を形成する苗切断台53を設けたものであるから、台木用苗3の茎部3b中心に対し左右対称な正確なY字形切断を可能とさせて接木精度を向上させることができるものである。
【図面の簡単な説明】
【図1】全体の側面図。
【図2】全体の正面図。
【図3】全体の平面図。
【図4】作業部の平面説明図。
【図5】ハンド部の側面説明図。
【図6】カム部の平面説明図。
【図7】カムの平面図。
【図8】穂木及び台木ハンドの説明図。
【図9】スリーブハンドの説明図。
【図10】開閉カム部の説明図。
【図11】昇降カム部の説明図。
【図12】穂木ハンド部の説明図。
【図13】台木ハンド部の説明図。
【図14】V字形切断刃の説明図。
【図15】穂木切断台の説明図。
【図16】Y字形切断刃の説明図。
【図17】台木切断台の説明図。
【図18】スリーブ供給部の説明図。
【図19】スリーブの装着説明図。
【図20】スリーブハンド部の説明図。
【図21】スリーブの装着工程説明図。
【図22】掻上げ機構の説明図。
【図23】調整カッタ部の説明図。
【図24】接木作業順序を示す説明図。
【符号の説明】
2 穂木用苗
2b 胚軸(茎部)
2c 切断面
3 台木用苗
3a 子葉
3b 胚軸(茎部)
3c 切断面
3e 縦切り部
15 苗接合機構(接合固定手段)
42 切断刃(切断手段)
43 切断刃(切断手段)
44 カッタ
47 苗切断台
48 苗保持溝
49 進入溝
50 カッタ
51 カッタ
53 苗切断台
59 苗保持溝
60 進入溝[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a grafting device that cuts stems of rootstock seedlings and spikelet seedlings, and joins and fixes the cut rootstock stems and spikelet stems at the cut locations.
[0002]
[Prior art]
For example, there is a technique in which a predetermined mechanism is cut by a cutting mechanism during transport of a stock and a scion transport mechanism, and is joined and fixed by a clip when moving to a grafting position. (For example, see Patent Document 1)
[0003]
[Patent Document 1] JP-A-5-23051
[0004]
[Problems to be solved by the invention]
However, in the case of cutting stocks and scions by the above-described cutting mechanism or the like, the cut surfaces are usually substantially smooth, and the energetic properties after joining are poor.
[0005]
[Means for Solving the Problems]
Therefore, the present invention provides a scion cutting means for cutting a stem portion of a scion seedling into a V shape, a stock cutting means for cutting a cotyledon development portion of a stock for a rootstock in a Y shape, and a scion seedling. And a fixing means for joining and fixing the V-shaped cut surface of the seedling and the Y-shaped cut surface of the rootstock, so that the V-shaped cut surface of the seedling for the scion and the Y-shaped cut surface of the rootstock for the rootstock are satisfactorily bonded. In order to improve the vigor of the seedlings, it is easy to insert the seedlings for the scion at the time of joining the scion at the vertical section of the Y-shaped cut surface of the seedling for the stock, and for the scion to insert the vertical section. This allows the tip of the seedling to escape, thereby enabling accurate joining of the seedlings for the scion and rootstock.
[0006]
Also, by combining the two cutters into a V-shape to form a V-shape cutting blade for cutting the scion, it is possible to easily perform a precise V-shape cutting of the scion stalk with a fixed angle. It is intended to improve the efficiency of grafting work.
[0007]
Furthermore, by combining the three cutters in a Y-shape to form a Y-shape cutting blade for stock cutting, it is possible to easily perform accurate Y-shape cutting of a stock stem portion having a constant shape at all times. Thus, the efficiency of grafting work is improved.
[0008]
In addition, a seedling holding groove for holding the stem of the scion seedlings and a seedling cutting table for forming an entry groove for the V-shaped cutting blade are provided, and a precise V-shape with respect to the center of the stem of the scion seedlings is provided. It is intended to improve the accuracy of grafting by making it possible to perform character-shaped cutting.
[0009]
Further, a seedling holding groove for holding a stem portion of a rootstock seedling and a seedling cutting table for forming an entry groove for a Y-shaped cutting blade are provided. It is intended to improve the accuracy of grafting by making it possible to perform character-shaped cutting.
[0010]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is an overall side view, FIG. 2 is a front view thereof, and FIG. 3 is a plan view thereof. A pair of upper and lower scion hands 4 and a scrub hand 5 for holding the scion seedlings 2 and the stock seedlings 3 of the solanaceae seedlings, and the scion and the stock hand 4.5 are rotated. There are provided upper and lower rotating disks 6,7, a rod shaft 8 for connecting the upper and lower rotating disks 6,7, and a motor 9 for intermittently rotating the rotating disks 6,7. Then, as shown in the plan view of FIG. 4, the worker 10 who inserts the seedlings 2.3 into the scion and the stocker hands 4.5 circulates counterclockwise with respect to the seedling insertion part 12 in front of the work seat 11. A seedling cutting part 14 having a seedling cutting mechanism 13 at a position where the plates 6 and 7 are rotated by 90 degrees, and a seedling bonding part 16 having a seedling joining mechanism 15 at a position further rotating the seedling cutting part 90 by 90 degrees. Further, a position rotated by 90 degrees from the seedling joint portion 16 is provided in the dispensing portion 17 of the grafted seedling, and the scion and rootstock hand are processed in the four steps of the input portion 12, the cutting portion 14, the joining portion 16, and the dispensing portion 17. The motor 9 is configured to perform intermittent driving for stopping the rotation of 4.5.
[0011]
As shown in FIGS. 4 to 6, the tips of the scion and rootstock hands 4.5, which constitute one pair of upper and lower parts, project outward from the outer periphery of the disk 6, and the four pairs are formed into the disks 6, 7 at 90-degree intervals. The mounting hand 4 is directly attached to the upper disk 6, and the stock hand 5 is supported to be vertically movable via the rod shaft 8 below the height of the holding hand 4 by a certain height. ing. As shown in FIGS. 6, 8, 10 and 11, the scion and rootstock hands 4 and 5 are swingably connected to the fixed hand unit 18 via the opening and closing fulcrum shaft 19. An opening / closing roller 21 provided at one end of the swinging hand unit 20 by the rotation of the disks 6 and 7 is provided with an opening / closing cam 24 on the outer surface of the fixed drums 22 and 23 for the cylindrical scion and rootstock. When abutting against the spring 25, the swing hand unit 20 is swung against the spring 26 to open the scion and the stock hand 4.
[0012]
As shown in FIG. 11, the upper end surface of the rootstock fixed drum 23 is provided on an elevating cam 27, and an elevating roller 28 installed below the fixed hand part 18 of the rootstock hand 5 is rolled on the elevating cam 27. When the root hand 5 is rotated integrally with the disks 6 and 7 about the rotation shaft 29, the root hand 5 is raised and lowered by the lifting cam 27. The hog hand 4 may be moved up and down by the elevating cam 27.
[0013]
As shown in FIGS. 8 and 12, the cotyledon hypocotyl stopper 30 and the cotyledon direction stable which determine the cutting height and the cutting direction in the fixed hand portion 18 of the scion hand 4 based on the deployed position of the cotyledon 2 a of the seedling 2 for scion. The rod 31 is provided integrally, and when the two leaves are expanded in the left-right direction and inserted between the hand parts 18 and 20 while holding the seedling 2 for hand scions, the hypocotyl 26 is brought into contact with the stopper 30 and the cotyledon 2a It is configured so that the grip is performed by pulling down the developing unit until it reaches the stopper 30.
[0014]
As shown in FIG. 13, the rootstock hand 5 includes a cotyledon hypocotyl stopper 32 and a cotyledon direction stabilizing plate 39 for determining a cutting height and a cutting direction with reference to a deployed position of the cotyledon 3a of the rootstock 3. When holding the seedling 3 in the hand and inserting the two leaves between the hands 18 and 20 in the front-rear direction perpendicular to the scion cotyledons 2a, hit the hypocotyl 3b against the stopper 32 and pull down the cotyledon 3a until the developing portion contacts the stopper 32. At the moment when each of the hands 4 and 5 starts to rotate in the counterclockwise direction by operating a work switch 35 provided on the side of the loading work table 34 of the grafting device 1, the fixed hand portion 18 moves the lower part of the hypocotyl. An upright support rod 38 for pressing the upper part of the hypocotyl via the ball plunger 36 and the spring 37 at the same time as the pressing is provided, so that the seedling 3 can be gripped well. Further, when the rootstock hand 5 rotates, the plunger 36 gets over the fixed hand portion 18 and the support rod 38 returns to the initial position, and the direction of the two leaves is corrected by the rubber suspension 40 arranged on the rotation direction side, so that the rootstock seedlings are removed. The holding posture of No. 3 is optimized.
[0015]
As shown in FIGS. 6 and 7, the opening / closing cams 24 and 25 are formed with convex cam surfaces 24 a and 25 a between the dispensing portion 17 and the loading portion 12 of the fixed drums 22 and 23, respectively. Opening is provided between the dispensing section 17 and the input section 12, so that the introduction of the seedlings 2 and 3 and the dispensing (release) of the grafted seedling 41 are performed.
[0016]
As is clear from the above, in the grafting apparatus for cutting and joining and fixing the hypocotyl 2b, which is the stem of the seedling 2 for scion, and the hypocotyl 2b, which is the stem of the seedling 3 for rootstock, A plurality of sets of upper and lower two stages of the scion hand 4 and the stock hand 5 that respectively hold the seedling 2 and the root raising seedling 3 are arranged around a rotation axis 29 which is a vertical axis. By rotating the hands 4 and 5 to perform a plurality of steps of work and simultaneously performing a plurality of steps of work, cutting and cutting necessary for grafting work during rotation of a plurality of sets of hands 4.5 around the rotating shaft 29 is performed. A series of operations of a plurality of steps such as joining can be performed sequentially and simultaneously at each position to improve the efficiency of grafting operation.
[0017]
In addition, since the cotyledon hypocotyl stopper 30 and the cotyledon direction stabilizing bar 31 for determining the cutting height and the cutting direction based on the cotyledon 2a deployment position are integrally provided on the scion hand 4, the scion with respect to the scion hand 4 is provided. In addition to facilitating the feeding and supply of the seedlings 2, the cutting accuracy of the scionling seedlings 2 can be improved by always keeping the seedling positions accurately.
[0018]
Furthermore, by providing the cotyledon hypocotyl stopper 32, the cotyledon direction stabilizing plate 39, and the seedling upright support rod 38, which determine the cutting height and cutting direction based on the cotyledon 3a deployment position, on the stock hand 5, In addition to facilitating the feeding and supply of the rootstock seedlings 3, it is possible to improve the cutting accuracy of the rootstock seedlings 3 by always keeping the position accurately.
[0019]
Further, by providing opening and closing cams 24 and 25 for opening and closing the hands 4.5 by rotating the scion hand 4 and the stock hand 5, it is possible to use a separate driving member such as a cylinder for opening and closing the hands 4.5. In addition, the hands 4.5 can be easily opened and closed using the rotation of the hands 4.5.
[0020]
Further, by providing the elevating cam 27 for raising and lowering the scion hand 4 or the scaffold hand 5 by rotating the scion hand 4 and the scaffold hand 5, a cylinder or the like for elevating the scion or the scaffold hand 4.5 is provided. It is possible to easily raise and lower the hands 4 and 5 using the rotation of the hands 4 and 5 without using a separate driving member.
[0021]
As shown in FIGS. 14 to 17, the seedling cutting mechanism 13 of the cutting section 14 is a pair of left and right V-shaped cuttings for cutting the hypocotyl 2b of the seedlings 2 for cutting in a V shape (wedge shape). A blade 42 and a Y-shaped rootstock cutting blade 43 for cutting the cotyledon 3a development portion of the hypocotyl 3b of the rootstock 3 into a Y-shape. The two cutters 44 are V-shaped seedlings of a cutter holder 45. The cutter 44 is fixed to the holder 45 with a thumbscrew 46 in a state where the V-shaped lower end of the tip of the cutter 44 is in contact with the V-shaped inner surface in a wedge shape in which the upper end of each cutter 44 is a sharpened portion 44a. The cutting blade 42 is advanced to the hypocotyl 2b of the scion seedling 2 formed at 20 degrees and held by the scion cutting table 47 at the front position, and cuts a substantially middle portion of the hypocotyl 26, It is configured to form a V-shaped cut surface 2c.
[0022]
Further, the cutting table 47 is provided with a seedling holding groove 48 for guiding the hypocotyl 26 and a cutter entry groove 49 for guiding the V-shaped cutter 44 to intrude. When the cutter 44 enters and cuts off, the guide groove 49 guides the seedlings 2 to perform accurate V-shaped cutting without spreading even if there is resistance.
[0023]
As shown in FIGS. 16 and 17, the stock cutting blade 43 is a combination of two V-shaped cutters 50, the lower ends of which are in contact with each other, and one vertically-cut cutter 51 disposed below the V-shaped cutter 50. The upper end of the V-shaped cutter 50 is fixed to the sharpened portion 50a and the lower end of the longitudinally cut cutter 51 is formed to the sharpened portion 51a in a side view. The tip portion is formed in a V shape, the inner angle of the V-shaped cutter 50 is formed to approximately 40 degrees, and the cutting blade 43 is attached to the hypocotyl 3b of the seedling 3 for the rootstock held by the rootstock cutting table 53 at the front position. By moving the cotyledon 3a forward, the developed part of the cotyledon 3a of the hypocotyl 3b is cut into a Y-shape to form a Y-shaped cut surface 3c and at the same time remove the growing point 3d.
[0024]
Further, the upper end of the vertical cutter 51 is made to protrude approximately 0.5 mm above the lower end of the V-shaped cutter 50 so as to eliminate the uncut portion of the V-shaped cutter 50 and to cut the seedling vertically formed in the seedling 3. The section 3e facilitates the insertion of the scion seedlings 2 at the time of joining the scion, and allows the tip of the scion seedling 2 into which the longitudinally cut section 3e is inserted to escape so that the scion and rootstock seedlings 2.3 can be removed. This enables accurate joining, and is configured to prevent the longitudinal cutter 51 from escaping by the cutter groove 55 of the hypocotyl retainer 54 fixed to the lower portion of the holder 52.
[0025]
Further, the cutting table 53 is provided with a seedling presser 58 having a guide groove 57 for guiding the vertical cutter 51 to enter, above the cotyledon presser 56 for pressing the upper part of the cotyledon 3a. Of the seedling holding groove 59 and an entry groove 60 for the vertical cutting cutter 51, and a cutter entry groove 61 serving as a guide for the V-shaped cutter 50 is provided in the cotyledon presser 56 at a substantially inner angle of 40 degrees.
[0026]
As is apparent from the above description, the V-shaped cutting blade 42, which is a scion cutting means for cutting the stem 2b of the seedling 2 for cutting into a V shape, and the cotyledon 3a development portion of the seedling 3 for cutting are Y-shaped. A Y-shaped cutting blade 43 which is a rootstock cutting means for cutting into a shape, a V-shaped cut surface 2c of the seedling 2 for scion and a Y-shaped cut surface 3c of the rootstock 3 for joining and fixing. By providing the mechanism 15, the V-shaped cut surface 2c of the seedling 2 for the scion and the Y-shaped cut surface 3c of the seedling 3 for the rootstock can be satisfactorily joined to improve the vigor. The vertical cutting part 3e of the Y-shaped cut surface 3c of the rootstock seedling 3 facilitates the insertion of the scion seedling 2 at the time of joining the scion, and the tip of the scion seedling 2 into which the vertical cutting part 3e is inserted is released. Thus, it is possible to accurately join the seedlings for the scion and rootstock.
[0027]
Also, by combining the two cutters 44 into a V-shape to form the V-shaped cutting blade 42 for cutting the scion, accurate V-shape cutting of the scion hypocotyl 2b at a constant angle can be easily performed. As a result, the efficiency of grafting work can be improved.
[0028]
Further, by combining the three cutters 50 and 51 into a Y-shape to form a Y-shape cutting blade 43 for cutting the rootstock, an accurate Y-shape of the stock shaft hypocotyl 3b having a constant shape at all times. Cutting can be easily performed, and the efficiency of grafting work can be improved.
[0029]
In addition, by providing a seedling holding groove 48 for holding the hypocotyl 2b of the scion seedling 2 and a seedling cutting table 47 for forming the entry groove 49 of the V-shaped cutting blade 42, the hypocotyl 2b of the scion seedling 2 is provided. Accurate grafting accuracy can be improved by enabling accurate V-shaped cutting symmetrical with respect to the center.
[0030]
Furthermore, by providing a seedling holding groove 59 for holding the hypocotyl 3b of the rootstock seedling 3 and a seedling cutting table 53 for forming the entry groove 60 of the Y-shaped cutting blade 43, the hypocotyl of the rootstock seedling 3 is provided. Accurate grafting can be improved by enabling accurate Y-shaped cutting symmetrical with respect to the center of 3b.
[0031]
As shown in FIG. 18 to FIG. 20, the joining mechanism 15 for joining and fixing the seedlings 2 for the scion and the seedlings 3 for the rootstock with the sleeve 62 is provided with a sleeve supply mechanism that cuts the sleeve 62 to a fixed length and supplies the cut. 63, a sleeve mounting mechanism 64 that spreads the supplied sleeve 62 by the sleeve hand 64 and mounts the sleeve 62 on the grafted seedling 41, and a scraping mechanism 65 that scrapes the cotyledons 3 a of the rootstock seedling 3 when the sleeve 62 is mounted. The supply mechanism 63 includes a pair of left and right feed rollers 68 for feeding a sleeve 62 housed in a reel 66 by continuous molding to a sleeve guide 67, and a turning member 70 having a stopper 69 with which the sleeve 62 abuts. , A photoelectric sleeve sensor 71 for detecting the rotation of the turning member 70 due to the contact of the sleeve 62, and a sleeve detection by the sensor 71 by rotating the feed roller 68. A feed motor 72 for stopping the rotation of the feed roller 68 and a sleeve cutter 73 for cutting the sleeve 62 to a fixed length (12 mm) when the feed of the sleeve 62 is stopped are provided, and cut along the guide rod 67 a of the sleeve guide 67. When the sleeve 62 moves down to the notch 67b, the cutter table 74 is advanced and the cutter 73 cuts the sleeve 62 to a predetermined length.
[0032]
Further, the sleeve 62 has a slit 75 for dropping off naturally as the grafted seedling 41 grows, and a projection 76 for pushing and expanding the slit 75. After that, using a material such as soft elastic cellulose or corn which biodegrades in a few months, it is formed to be light and translucent in mass, so that the joined state can be easily checked from the outside.
[0033]
As shown in FIGS. 9 and 20, the sleeve mounting mechanism 64 includes a sleeve hand 77 having left and right hooks 77a that open and close by gripping a projection 76 of the sleeve 62, a pusher 78 for supporting the outer surface of the sleeve 62 on the side opposite to the slit 75, An opening / closing operation section 79 for opening and closing the sleeve hand 77, a pneumatic cylinder 80 for moving the sleeve hand 77 back and forth, a pneumatic cylinder 81 for moving the pusher 78 back and forth, and a stopper 82 for correcting a displacement of the grafted seedling 41 and the like. It has.
[0034]
As shown in FIG. 21, the hook 77a is opened to approach the sleeve cut to a predetermined length by the supply mechanism 63, and when the hook 77a is closed to push the pusher 78 forward, the hook 77a When the hook 77a is opened, the sleeve 62 is pushed out and expanded to approach the grafted seedling 41, and the hand 77 comes to the grafted seedling 41 position, and when the hook 77a is closed, the sleeve 62 is attached to the seedling 41 and the pusher 78 is retracted. Then, the hook 77a is separated from the sleeve 62, the hook 77a is opened, the hand 77 is retracted from the grafted seedling 41, and the seedling 41 is released, thereby completing the mounting of the sleeve 62. In the above-described embodiment, the pusher 78 is moved forward and backward when the hook 77a is inserted into and removed from the sleeve 62. However, the same operation may be performed by moving the hand 77 backward or forward.
[0035]
As shown in FIG. 22, when the sleeve 62 is attached to the grafted seedling 41, the scraping mechanism 65 opens and closes the pair of rollers 83 that lifts the cotyledons 3a of the rootstock seedlings 3 upward, and the rollers 83 in the horizontal direction. An opening / closing unit 84, a pneumatic lifting / lowering cylinder 85 for raising / lowering the roller 83, and a forward / backward moving cylinder 86 for moving the roller 83 back and forth are provided. When the sleeve 62 is mounted, the roller 83 is brought close to the grafted seedling 41 position. When the is lifted in the closed state, the cotyledons 3a are lifted up by the rollers 83, and the sleeve 62 is securely mounted without disturbing the cotyledons 3a.
[0036]
Further, as shown in FIG. 23, an adjusting cutter 87 for adjusting and cutting the entire length of the grafted seedling 41 to a predetermined length is provided on the moving path of the scion and the stocker hands 4.5 between the seedling joining part 16 and the dispensing part 17. Arranged via a stand 88, the hypocotyl 3b of the seedling 3 for rootstock is cut horizontally just before dispensing to produce a grafted seedling 41 of a certain height to improve seedling quality.
[0037]
As is apparent from the above description, the sleeve 62 is provided as a joining tool for joining and fixing the V-shaped cut surface 2c of the seedling 2 for the scion and the Y-shaped cut surface 3c of the seedling 3 for the rootstock. The provision of the rollers 83, which are members for raising the cotyledons 3a of the rootstock seedlings 3 when the connecting tools 62 are attached to the seedlings 2, 3, disturbs the cotyledons 3a of the rootstock seedlings 3 when the sleeve 62 is attached. It is possible to perform an accurate mounting operation without causing the sleeve 62 to be mounted more efficiently.
[0038]
In addition, a slit 75 is formed in the cylindrical sleeve 62, and a sleeve hand 77, which is an expansion member for expanding the sleeve 62 by the slit 75, is provided. The sleeve 62 can be reliably mounted, and the mounting of the sleeve 62 can be improved.
[0039]
Further, by providing an adjusting cutter 87 which is an adjusting cutting mechanism for adjusting and cutting the grafted seedling 41 of the scion seedling 2 and the rootstock seedling 3 joined to each other by the sleeve 62 to a fixed length, Adjustment of the fixed height of the grafted seedling 41 can be easily performed immediately before dispensing, and the seedling quality can be improved.
[0040]
Also, by providing the sleeve 62 for joining and fixing the V-shaped cut surface 2c of the seedling 2 for the scion and the Y-shaped cut surface 3c of the seedling 3 for the rootstock, and by using a biodegradable material for the sleeve 62, Even if the sleeve 62 falls off naturally as the grafted seedling 41 grows, the sleeve 62 naturally disappears due to biodegradation, and the collection of the sleeve 62 becomes unnecessary, so that work efficiency can be improved.
[0041]
Further, since the sleeve 62 is formed in a substantially cylindrical shape having a slit 75, the expansion of the sleeve 62 is facilitated, and at the same time, the inconvenience such as the formation of water and the generation of virus during irrigation of the seedling is prevented, so that the grafted seedling 41 can be formed. Can encourage growth.
[0042]
Further, the projections 76 for pushing and spreading the sleeve 62 are formed in the slit 75, so that the sleeve 62 can be easily pushed and spread by grasping the projections 76 by using a detachable member or the like, so that the sleeve 62 can be surely spread. Mounting can be enabled.
[0043]
The semi-automatic grafting work is performed as described above, and the graft is securely grafted so that the deployment directions of the scion cotyledons 2a and the cotyledons 3a are orthogonal (cross-shaped), and the sunshine is uniform without shading. 24 to promote the growth of the grafted seedlings 2 and 3. When the scion and the stocking hands 4.5 that are closest to the work seat 1 are located in the seedling input section 12, as shown in FIG. The rooted shoots and rootstock seedlings 2 and 3 are put into the respective hands 4 and 5 to be clamped, and after clamping, a series of cutting, joining and dispensing grafting operations are automatically performed. When the hands 4.5 holding the seedlings 2.3 are moved to the seedling cutting part 14 by driving, the hypocotyl 3b of the seedling 2 for scion is formed into a V shape by the cutting blade 42, and The hypocotyl 3b of the tree seedling 3 is cut into a Y-shape, and then the hands 4.5 are connected to the seedling junction 16 by cutting. When moving, the rootstock seedlings 3 are raised to insert the scion seedlings 2, and the outside of the rootstock seedlings 3 embracing the scion seedlings 2 is fixed with a sleeve 62 to transfer the grafted seedling 41. When the hands 4.5 are moved to the payout section 17, the hands 4.5 are released to release or take out the grafted seedling 41.
[0044]
【The invention's effect】
As is clear from the above examples, the present invention provides a scion cutting means 42 for cutting the stem 2b of the scion seedling 2 into a V-shape, and a Y-shape for the cotyledon 3a development portion of the stock 3 for the stock. Since a stock cutting means 43 for cutting and a fixing means 15 for joining and fixing the V-shaped cut surface 2c of the seedling for seedling 2 and the Y-shaped cut surface 3c of the seedling for seedling 3 are provided. The V-shaped cut surface 2c of the tree seedling 2 and the Y-shaped cut surface 3c of the rootstock seedling 3 can be satisfactorily joined to improve the vigor, and the Y-shaped cut surface of the rootstock seedling 3 can be improved. 3c facilitates the insertion of the scion seedlings 2 at the time of joining the scion, and allows the tip of the scion seedlings 2 into which the longitudinal cuts 3e are inserted to be released, so that the cuttings of the scion and rootstock can be removed. It is possible to make accurate joining possible.
[0045]
In addition, since the two cutters 44 are combined in a V-shape to form the V-shaped cutting blade 42 for cutting the scion, an accurate V-shape cutting of the scion stalk 2b at a constant angle is performed. Can be easily performed, and the efficiency of grafting work can be improved.
[0046]
Furthermore, since the three cutters 50 and 51 are combined in a Y-shape to form a Y-shaped cutting blade 43 for cutting the rootstock, the exact shape of the rootstock stem 3b, which is always in a fixed shape, is obtained. This makes it possible to easily perform Y-shaped cutting, thereby improving the efficiency of grafting work.
[0047]
Further, since the seedling holding groove 48 for holding the stem portion 2b of the seedling 2 and the seedling cutting table 47 for forming the entry groove 49 of the V-shaped cutting blade 42 are provided, It is possible to improve the grafting accuracy by enabling accurate V-shaped cutting symmetrical to the center of the stem 2b.
[0048]
Further, since the seedling holding groove 49 for holding the stem portion 3b of the rootstock seedling 3 and the seedling cutting table 53 for forming the entry groove 60 of the Y-shaped cutting blade 43 are provided, the rootstock seedling 3 It is possible to improve the grafting accuracy by enabling accurate Y-shaped cutting symmetrical with respect to the center of the stem 3b.
[Brief description of the drawings]
FIG. 1 is an overall side view.
FIG. 2 is an overall front view.
FIG. 3 is an overall plan view.
FIG. 4 is an explanatory plan view of a working unit.
FIG. 5 is an explanatory side view of a hand unit.
FIG. 6 is an explanatory plan view of a cam portion.
FIG. 7 is a plan view of a cam.
FIG. 8 is an explanatory view of a scion and a stock hand.
FIG. 9 is an explanatory view of a sleeve hand.
FIG. 10 is an explanatory diagram of an opening / closing cam unit.
FIG. 11 is an explanatory diagram of a lifting cam unit.
FIG. 12 is an explanatory diagram of a hand hand unit.
FIG. 13 is an explanatory diagram of a stock hand unit.
FIG. 14 is an explanatory view of a V-shaped cutting blade.
FIG. 15 is an explanatory view of a scion cutting table.
FIG. 16 is an explanatory view of a Y-shaped cutting blade.
FIG. 17 is an explanatory view of a stock cutting table.
FIG. 18 is an explanatory diagram of a sleeve supply unit.
FIG. 19 is an explanatory view of mounting a sleeve.
FIG. 20 is an explanatory diagram of a sleeve hand unit.
FIG. 21 is an explanatory diagram of a mounting process of a sleeve.
FIG. 22 is an explanatory view of a scraping mechanism.
FIG. 23 is an explanatory diagram of an adjustment cutter unit.
FIG. 24 is an explanatory diagram showing a grafting work order.
[Explanation of symbols]
2 Seedling 2b for hypocotyl (hypocotyl (stem))
2c Cutting surface 3 Seedling for rootstock 3a Cotyledon 3b Hypocotyl (stem)
3c Cutting surface 3e Vertical cut 15 Seedling joining mechanism (joining fixing means)
42 Cutting blade (cutting means)
43 Cutting blade (cutting means)
44 cutter 47 seedling cutting table 48 seedling holding groove 49 entry groove 50 cutter 51 cutter 53 seedling cutting table 59 seedling holding groove 60 entry groove
