JP3821439B2 - Boat fishing weight and stabilizing member - Google Patents

Description

ＭＵ：復元モーメント（重心Ｇより上部の投影面積の一次モーメント）
ＡＵ：重心Ｇより上部の船釣り用オモリの投影面積の総和
ＬＵ：ＡＵの図心の位置
【００５０】
また同様に、重心Ｇより下の部分の船釣り用オモリの投影面積の総和をＡＤとし、そのＡＤの図心の位置を置ＬＤとすると、船釣り用オモリ１０の回転モーメントＭＤ（重心Ｇより下部の投影面積の一次モーメント）は、以下の式（３）にて表される。
【数３】

ＭＤ：回転モーメント（重心Ｇより下部の投影面積の一次モーメント）
ＡＤ：重心Ｇより下部の船釣り用オモリの投影面積の総和
ＬＤ：ＡＤの図心の位置
【００５１】
ここで、回転モーメントＭＤは、船釣り用オモリ１０が水中を降下する際の水流の作用により、船釣り用オモリ１０の軸線Ｃを鉛直方向と異なる方向に回転させる力を発するモーメントである。
【００５２】
逆に、先の復元モーメントＭＵは、船釣り用オモリ１０が水中を降下する際の水流の作用により、船釣り用オモリ１０の軸線Ｃを鉛直方向と同じ方向に戻す力を発するモーメントである。
【００５３】
ここで、復元モーメントＭＵと回転モーメントＭＤの比をｋ＝ＭＵ／ＭＤとする。ｋの値を大きくすることができれば、船釣り用オモリ１０が水中を降下する際に、軸線Ｃが鉛直方向（重力方向）へ復元するモーメントが常に働くことになる。すると、鉛直方向と船釣り用オモリ１０の軸線Ｃとの角度差（オモリ角度）が、常に０度付近に復元する作用が働くので、船釣り用オモリ１０は抗力の少ない姿勢で安定して降下するという効果を奏することになる。
【００５４】
ところが、ｋの値が大きければ大きいほど、全ての性能面において船釣り用オモリとしてのよい結果が得られるかと言うとそうではなく、ｋの値が大きくなりすぎると一般に投影面積自体も大きくなる傾向があるために、船釣り用オモリが水中を降下する際に潮流に流され易くなってしまう。すると、狙った位置に船釣り用オモリが降下しにくくなるという不具合を生ずる。その結果、魚群の存在する位置とは異なる位置に船釣り用オモリ１０が流されて行ってしまうので、漁獲高が減少してしまうと言う不具合を生ずる。
【００５５】
そこで実物において実験を繰り返したところ、船釣り用オモリ１０のｋの値が式（４）を満たす形状を有する場合に、おおむね目的を達成することができることがわかった。
【数４】
２．３≦ｋ≦５．０…（４）
【００５６】
なお、船釣り用オモリ１０が水中を降下する際に、鉛直方向と船釣り用オモリ１０の軸線Ｃとの角度差（オモリ角度）を全ての方向について常に０度付近に復元させて、抗力と揚力とが少ない状態で水中を降下させるためには、船釣り用オモリ１０の軸線Ｃに対して平行であって、互いに直角な任意の２つの投影面において、上式（４）の要件を満たす必要がある。
【００５７】
図２（ａ）及び図２（ｂ）は、本発明に係る船釣り用オモリの第２の実施例を示す図である。
図２（ａ）は船釣り用オモリ１０Ａの平面図であり、図２（ｂ）は船釣り用オモリ１０Ａの正面図である。
【００５８】
同図に示す船釣り用オモリ１０Ａには吊環２０が設けられている。同図に示す例では、船釣り用オモリ１０Ａの上部には羽形状の羽２２Ａが４枚軸線Ｃに対して放射状に構成されている。
【００５９】
この羽２２Ａの働きによって、船釣り用オモリ１０Ａの重心より上部の投影面積の一次モーメントＭＵと、重心より下部の投影面積の一次モーメントＭＤの比をｋ＝ＭＵ／ＭＤとした場合に、ｋ＝２．５となり、船釣り用オモリ１０Ａが水中を降下する際に、鉛直方向と船釣り用オモリ１０Ａの軸線Ｃとの角度差（オモリ角度）を常に０度付近に復元させて、抗力と揚力とが少ない状態で水中を降下させることが可能となる。
【００６０】
また、同図に示す羽２２Ａの構成を用いることによって、軸線Ｃに対して平行であって、互いに直角な任意の２つの投影面において、ｋ≧２．３の要件を効果的に満たすことが可能となる。
【００６１】
なお、同図に示す例では、羽２２Ａを４枚設けた例で説明したが、本発明は羽の枚数を限定しているものではなく、羽の枚数は１枚であっても、その羽を軸線Ｃと平行に曲げる形状とすること等によって、船釣り用オモリの軸線Ｃに対して平行であって、互いに直角な任意の２つの投影面において、２．３≦ｋ≦５．０を満たせば、船釣り用オモリが水中を降下する際に、鉛直方向と船釣り用オモリ１０の軸線Ｃとの角度差（オモリ角度）を全ての方向について常に０度付近に復元させて、抗力と揚力とが少ない状態で水中を降下させることが可能となる。同様に、羽の枚数は２枚であっても、３枚であっても、５以上であっても、スプライン形状であってもよいが、オモリが水中を降下する際に、オモリが蛇行や回転しないようなバランスの取れた形状が好ましい。
【００６２】
一般に船釣り用オモリの素材は、比重の大きな鉛を用いることが多い。鉛は柔らかい素材であるので、船釣り用オモリが細長い形状である場合には、操業時や待機時等にて力が加わった際にオモリ自体が曲がってしまうという不具合を生ずる可能性がある。
【００６３】
ところが、羽２０Ａは体積の割に表面積が大きいので、同図に示すように船釣り用オモリ１０Ａに羽２２Ａを設けることによって、船釣り用オモリ１０Ａを短く形成しつつ、復元力を大きくすることが可能となる。したがって、操業時や待機時等にオモリに力が加わった場合であっても、オモリ自体が曲がってしまうという不具合の発生を減少させることが可能となる。
【００６４】
図３（ａ）及び図３（ｂ）は、本発明に係る船釣り用オモリの第３の実施例であり、ｋ＝３．１の場合を示す図である。
【００６５】
図４（ａ）及び図４（ｂ）は、本発明に係る船釣り用オモリの第４の実施例であり、ｋ＝３．６の場合を示す図である。
【００６６】
図５（ａ）及び図５（ｂ）は、本発明に係る船釣り用オモリの第５の実施例であり、ｋ＝４．０の場合を示す図である。
【００６７】
図６（ａ）及び図６（ｂ）は、本発明に係る船釣り用オモリの第６の実施例である。
【００６８】
同図に示すように、船釣り用オモリ１０Ｅには吊環２０が設けられている。また、船釣り用オモリ１０Ｅには、質量と重力加速度によって水中にて船釣り用オモリ１０Ｅを降下させる力を発生させるためのオモリ部材１２Ｅと、船釣り用オモリ１０Ｅの重心より上部の投影面積の一次モーメントＭＵを大きくさせる機能を有する別体の安定化部材１４Ｅと、オモリ部材１２Ｅと安定化部材１４Ｅとが分離しないように固定、又は装着するピン２４とが設けられている。
【００６９】
同図に示すように安定化部材１４Ｅには、オモリ部材１２Ｅと接触しつつオモリ部材１２Ｅに装着する装着部が設けられている。オモリ部材１２Ｅに装着した安定化部材１４Ｅは、船釣り用オモリ１０Ｅの落下方向と軸線Ｃとが傾いた際に揚力又は抗力を発生する形状を有している。
【００７０】
したがって、船釣り用オモリ１０Ｅが水中を降下する際に、安定化部材１４Ｅにより発生する揚力又は抗力の働きによって、鉛直方向と船釣り用オモリ１０Ｅの軸線Ｃとの角度差（オモリ角度）を常に０度付近に復元させて、船釣り用オモリ１４Ｅ全体の抗力と揚力とが少ない状態を維持して水中を降下させることが可能となる。
【００７１】
同図に示す例では、安定化部材１４Ｅは羽形状を有しており、軸線Ｃに対して４枚の羽が放射状に構成されるようになっている。この安定化部材１４Ｅの働きによって、船釣り用オモリ１０Ｅの重心より上部の投影面積の一次モーメントＭＵと、重心より下部の投影面積の一次モーメントＭＤの比ｋが２．３≦ｋ≦５．０を満たすことが可能となる。
【００７２】
同図に示す例では、安定化部材１４Ｅは羽形状を有しているが、本発明は羽形状に限定されるものではなく、船釣り用オモリ１０Ｅの重心より上部の投影面積の一次モーメントＭＵを増大させる機能を奏する形状であればよく、例えば羽の有無等は関係ない。
【００７３】
また、安定化部材１４Ｅは船釣り用オモリ１０Ｅの上部に設けられているので、オモリ部材１０Ｅよりも比重の小さな物性を有する素材（例えば樹脂、アルミニウムなどの軽金属など）を用いることが好ましい。船釣り用オモリ１０Ｅの重心位置を下げることが可能だからである。
【００７４】
また比重の小さな素材を用いることによって、船釣り用オモリ１０Ｅの全長を短く形成しつつ、復元力を大きくすることが可能となるので、操業性の良好な船釣り用オモリを提供することが可能となる。
【００７５】
また、安定化部材１４Ｅを羽形状にする場合であって、羽が薄く長い場合には、操業時や待機時等にて力が加わった際に羽形状の部分が曲がってしまったり、折れてしまう可能性がある。したがって、あまり薄い形状にしない、あまり軸線Ｃに対して放射状に細長い羽形状にはしない、曲がりにくい素材を選択する、又はゴムなどの曲がっても破損せずに元に戻る素材を選択するなどの配慮を行うとよい。
【００７６】
また、オモリ部材１２Ｅと安定化部材１４Ｅとを別体とすることによって、従来の船釣り用オモリのように、オモリ自体にはオモリ角度０°付近にて復元力がないオモリであっても、後から安定化部材１４Ｅを装着することによって、その従来のオモリに対して復元力を発生させることが可能となる。そして従来のオモリを用いた場合であっても、短時間に所定の深度まで降下せることが可能となる。
【００７７】
また、オモリ部材１２Ｅと安定化部材１４Ｅとが分離しないように固定、又は装着する手法として、図６に示す実施例ではピン２４を用いているが、固定手法はピン２４に限定されるものではなく、螺子等の結合部材を用いて固定するようにしてもよいし、勘合部を設けて固定するようにしてもよいし、螺子部を設けて固定するようにしてもよい。
【００７８】
更に、安定化部材１４Ｅをゴムや柔らかめの樹脂等の弾力性のある素材で構成しておき、オモリ部材１２Ｅに対してサックをかぶせるように構成するとともに、安定化部材１４Ｅの弾力性（復元性）によってオモリ部材１２Ｅと固定、又は、オモリ部材１２Ｅに装着するように構成しても、本発明の目的を達成することが可能となる。
【００７９】
図７（ａ）及び図７（ｂ）は、本発明に係る船釣り用オモリの第７の実施例である。
同図に示すように、船釣り用オモリ１０Ｆには吊環２０が設けられている。また、船釣り用オモリ１０Ｆには、質量と重力加速度によって水中にて船釣り用オモリ１０Ｆを降下させる力を発生させるためのオモリ部材１２Ｆと、船釣り用オモリ１０Ｆの重心より上部の投影面積の一次モーメントＭＵを大きくさせる機能を有する別体の安定化部材１４Ｆと、オモリ部材１２Ｆと安定化部材１４Ｆとが分離しないように結合する螺子２６（結合部材の一形態）並びに勘合部２８が設けられている。
【００８０】
なお同図では、螺子２６及び勘合部２８との両方を備えている実施例で示してあるが、いずれか一方のみを備えた構成であってもよいし、オモリ部材１２Ｆと安定化部材１４Ｆとが分離しないように接着や溶着、鮫歯状の結合部を有する勘合等の方法を用いてもよい。
【００８１】
同図に示す例では、安定化部材１４Ｆは羽形状を有しており、軸線Ｃに対して４枚の羽が放射状に構成されるようになっている。この安定化部材１４Ｆの働きによって、船釣り用オモリ１０Ｆの重心より上部の投影面積の一次モーメントＭＵと、重心より下部の投影面積の一次モーメントＭＤの比ｋが２．３≦ｋ≦５．０を満たすことが可能となる。
【００８２】
そして、船釣り用オモリ１０Ｆが水中を降下する際に、鉛直方向と船釣り用オモリ１０Ｆの軸線Ｃとの角度差（オモリ角度）を常に０度付近に復元させて、抗力と揚力とが少ない状態で水中を降下させることが可能となる。
【００８３】
同図に示す例では、安定化部材１４Ｆは羽形状を有しているが、本発明は羽形状に限定されるものではなく、船釣り用オモリ１０Ｆの重心より上部の投影面積の一次モーメントＭＵを増大させる機能を奏する形状であればよく、例えば羽の枚数等には関係がない。
【００８４】
また、安定化部材１４Ｆは船釣り用オモリ１０Ｆの上部に設けられているので、オモリ部材１０Ｆよりも比重の小さな物性を有する素材（例えば樹脂、アルミニウムなどの軽金属など）を用いることが好ましい。
【００８５】
また比重の小さな素材を用いることによって、船釣り用オモリ１０Ｆの全長を短く形成しつつ、復元力を大きくすることが可能となるので、操業性の良好な船釣り用オモリを提供することが可能となる。
【００８６】
また、安定化部材１４Ｆを羽形状にする場合であって、羽が薄く長い場合には、操業時や待機時等にて力が加わった際に羽形状の部分が曲がってしまったり、折れてしまう可能性がある。したがって、あまり薄い形状にしない、あまり軸線Ｃに対して放射状に細長い羽形状にはしない、塑性変形しにくい素材を選択する、又はゴムなどの曲がっても破損せずに元に戻る素材を選択するなどの配慮を行うとよい。
【００８７】
また、同図に示す例では、吊環２０はオモリ部材１２Ｆに固定されている実施例で示してあるが、本発明はこれに限定されるものではなく、安定化部材１４Ｆに吊環２０が固定されていてもよい。
【００８８】
図８（ａ）及び図８（ｂ）は、本発明に係る船釣り用オモリの第８の実施例である。
【００８９】
同図に示すように、船釣り用オモリ１０Ｇには吊環２０が設けられている。また、船釣り用オモリ１０Ｇには、質量と重力加速度によって水中にて船釣り用オモリ１０Ｇを降下させる力を発生させるためのオモリ部材１２Ｇと、船釣り用オモリ１０Ｇの重心より上部の投影面積の一次モーメントＭＵを大きくさせる機能を有する別体の安定化部材１４Ｇとが設けられている。
【００９０】
オモリ部材１２Ｇと安定化部材１４Ｇとは、吊環軸２０Ａ（軸材）を介して分離しないように結合されている。
【００９１】
同図に示す例では、安定化部材１４Ｇは羽形状を有しており、軸線Ｃに対して４枚の羽が放射状に構成されるようになっている。この安定化部材１４Ｇの働きによって、船釣り用オモリ１０Ｇの重心より上部の投影面積の一次モーメントＭＵと、重心より下部の投影面積の一次モーメントＭＤの比ｋが２．３≦ｋ≦５．０を満たすことが可能となる。
【００９２】
そして、船釣り用オモリ１０Ｇが水中を降下する際に、鉛直方向と船釣り用オモリ１０Ｇの軸線Ｃとの角度差（オモリ角度）を常に０度付近に復元させて、抗力と揚力とが少ない状態で水中を降下させることが可能となる。
【００９３】
同図に示す例では、安定化部材１４Ｇは羽形状を有しているが、本発明は羽形状に限定されるものではなく、船釣り用オモリ１０Ｇの重心より上部の投影面積の一次モーメントＭＵを増大させる機能を奏する形状であればよく、例えば羽の枚数等には関係がない。
【００９４】
また、図９（ａ）及び図９（ｂ）に示すように、羽を設けない形状で安定化部材１４Ｈを構成して、ｋが２．３≦ｋ≦５．０を満たすようにしても本発明の目的を達成することが可能となる。
【００９５】
また、安定化部材１４Ｇは船釣り用オモリ１０Ｇの上部に設けられているので、オモリ部材１０Ｇよりも比重の小さな物性を有する素材（例えば樹脂、アルミニウムなどの軽金属など）を用いることが好ましい。船釣り用オモリ１０Ｇの重心位置を下げることが可能だからである。
【００９６】
また比重の小さな素材を用いることによって、船釣り用オモリ１０Ｇの全長を短く形成しつつ、復元力を大きくすることが可能となるので、操業性の良好な船釣り用オモリを提供することが可能となる。
【００９７】
また、安定化部材１４Ｇを羽形状にする場合であって、羽が薄く長い場合には、操業時や待機時等にて力が加わった際に羽形状の部分が曲がってしまったり、折れてしまう可能性がある。
【００９８】
したがって、あまり薄い形状にしない、あまり軸線Ｃに対して放射状に細長い羽形状にはしない、曲がりにくい素材を選択する、又はゴムなどの曲がっても破損せずに元に戻る素材を選択するなどの配慮を行うとよい。
【００９９】
図８及び図９に示す実施例では、安定化部材１４Ｇ又は安定化部材１４Ｈを吊環２０に結合する例で示したが、本発明はこれに限定されるものではない。したがって、安定化部材１４Ｇ又は安定化部材１４Ｈを、吊環２０近傍のテグス糸に結合するようにしても、以下のように本発明の目的を達成することが可能となる場合もある。
【０１００】
テグス糸に結合された安定化部材は、降下中に姿勢に応じた抗力又は揚力を発生する。テグス糸に結合された安定化部材は、テグス糸を介して船釣り用オモリに接続されているので、船釣り用オモリには、軸線Ｃを降下方向に戻す方向に復元力が働く。したがって、船釣り用オモリ自体には復元力がない場合であっても、船釣り用オモリに対して復元力を発生させることが可能となる場合がある。
【０１０１】
図１０（ａ）及び図１０（ｂ）は、本発明に係る船釣り用オモリの第１０の実施例である。
同図に示す実施例は、図７に示した実施例において、羽を設けない形状で安定化部材１４Ｊを構成して、ｋが２．３≦ｋ≦５．０を満たすようにした実施の形態である。
【０１０２】
同図に示すように、船釣り用オモリ１０Ｊには吊環２０が設けられている。また、船釣り用オモリ１０Ｊには、質量と重力加速度によって水中にて船釣り用オモリ１０Ｊを降下させる力を発生させるためのオモリ部材１２Ｊと、船釣り用オモリ１０Ｊの重心より上部の投影面積の一次モーメントＭＵを大きくさせる機能を有する別体の安定化部材１４Ｊと、オモリ部材１２Ｊと安定化部材１４Ｊとが分離しないように結合する螺子部３０が設けられている。
【０１０３】
なお同図では、螺子部３０を設けることによってオモリ部材１２Ｊと安定化部材１４Ｊとを螺合して双方が分離しないように結合する実施例を示しているが、螺子、ピン等の結合部材によって結合されていてもよいし、勘合によって結合されていてもよい。また、安定化部材１４Ｊは、船釣り用オモリ１０Ｊに対するキャップ形状のものであってもよい。
【０１０４】
同図に示す例では、安定化部材１４Ｊの働きによって、船釣り用オモリ１０Ｊの重心より上部の投影面積の一次モーメントＭＵと、重心より下部の投影面積の一次モーメントＭＤの比ｋを好ましい値に設定することが可能となる。
【０１０５】
そして、船釣り用オモリ１０Ｊが水中を降下する際に、鉛直方向と船釣り用オモリ１０Ｊの軸線Ｃとの角度差（オモリ角度）を常に０度付近に復元させて、抗力と揚力とが少ない状態で水中を降下させることが可能となる。
【０１０６】
同図に示す実施例では羽を設けていないために船釣り用オモリ１０Ｊの形状を、抗力の少ない流線型に形成することが可能であるという利点がある。例えば、完全な流線型とはいえない図１７に示す胴突きオモリの形状を有する場合であっても、オモリ角度が０°〜１０°の範囲では抗力が０．２５（Ｎ）〜０．３７（Ｎ）程度と小さい。このように、安定化部材１４Ｊの部分を、軸線Ｃに対して略線対称な形状としても本発明の目的を達成することが可能である。
【０１０７】
上記のように、所定のｋの値を得るために安定化部材１４Ｊに比重の小さな素材を用いることにより、船釣り用オモリ１０Ｊの比重が多少小さくなった場合であっても、抗力が少ないことによって船釣り用オモリ１０Ｊの降下速度を上げることが可能となり、短時間に所定の深度まで降下させることが可能となる。
【０１０８】
また、安定化部材１４Ｊをオモリ部材１２Ｊと別体に構成することによって、降下速度が速く降下時間の短い船釣り用オモリを安価にて供給することが可能となる。
【０１０９】
図１１の図表に、各種船釣り用オモリのＭＵ値とＭＤ値との算出結果と、重心周りのモーメントが０となる角度等の算出結果を示す。
【０１１０】
同図表の最下段に示すように、ＡＳ型の船釣り用オモリの上部に羽を設けた例で、ＭＵ／ＭＤ＝３．１の場合には、重心周りのモーメントが０となる角度が０°となっている。したがって、この場合に船釣り用オモリは、常にオモリ角度が０°になるように復元しながら水中を降下することが予想される。
【０１１１】
図１２に、ｋ＝２．５の場合のＡＳ羽付の型のオモリについて流体解析を行った際の、オモリ角度と抗力、揚力、重心周りのモーメントの調査結果を示す。同図に示すように、オモリ角度が０度から微小角増大した場合には、重心周りのモーメントが負の値（オモリの傾きを復元する方向に回転モーメントが働く）を示していることが読み取れる。この場合に船釣り用オモリは、常にオモリ角度が０°になるように復元しながら水中を降下することが予想される。したがって、抗力が小さい状態で落下するものと予想される。
【０１１２】
図１３に、ＡＳ羽付のオモリを実際に制作して、オモリの降下実験を行った結果の「経過時間−瞬間速度線図」を示す。
なお、オモリの降下実験は、図１５及び図１６と同一の条件で行った結果である。
【０１１３】
同図に示すように、ＡＳ羽付のオモリは、水中に投入直後は瞬間速度が約６７０（ｃｍ／ｓ）に達しているとともに速度の変動がなく安定して降下していることが読み取れる。
【０１１４】
更に、降下時間は２５．７（秒）であり、従来の最良であったＡＳ型と比較して約６％短縮されている。これは実験用の太いテグスを使用した場合であり、通常の細いテグスを使用した場合、更にその差が大きくなるのは明白である。
【０１１５】
図１４に、樹脂製の１／２スケール模型による降下軌跡観察実験の結果を示す。
ＡＳ型並びにＡＳ羽付のオモリの模型の素材は、観察を容易にするために降下速度を落とす目的で比重１．２の光硬化樹脂を用いている。降下軌跡観察実験に用いた水槽の側面はガラス製であり、模型の降下軌跡の観察を行うことが容易となっている。なお、同図に示す数値の単位は（ｃｍ）である。
【０１１６】
ＡＳ型の模型の重心周りのモーメントが０になる角度は４５°であり、そのときの抗力は６．８（Ｎ）である。
一方のＡＳ羽付の模型の重心周りのモーメントが０になる角度は０°であり、そのときの抗力は１．４（Ｎ）である。
【０１１７】
樹脂製の模型による降下軌跡観察実験の結果、ＡＳ型の模型は、垂直の状態で降下開始後、少し鉛直方向に降下した後に、約４５°傾き、そこから傾きを増減させながら降下した。
【０１１８】
一方のＡＳ羽付の模型は、少し振れながらほぼまっすぐに降下した。この観察結果は、復元性のシミュレーション結果とよく合っており、推察が正しいことが確かめられた。
【０１１９】
請求項１に記載した発明によれば、船釣り用オモリの降下時において、その船釣り用オモリが本来降下するべき方向である鉛直方向と、船釣り用オモリの軸線との角度差（オモリ角度）が、常に０度付近に復元するような復元モーメントを発生させることが可能となる。また、船釣り用オモリが水中を降下する際の落下姿勢を抗力の小さい向きに安定させることが可能となる。これにより、所定の深度まで短時間に降下させることができる。
【０１２０】
請求項１〜６に記載の発明で得られる上記共通の効果に加え、各請求項に記載した発明によれば次の効果を得ることができる。
請求項２に記載した発明によれば、船釣り用オモリが本来降下するべき方向である鉛直方向と、オモリの軸線との角度差（オモリ角度）が、常に０度付近に復元するような復元モーメントを発生させることが可能となる。また、船釣り用オモリが水中を降下する際の落下姿勢を抗力の小さい向きに安定させることが可能となる。
【０１２１】
請求項３に記載した発明によれば、船釣り用オモリが本来降下するべき方向である鉛直方向と、船釣り用オモリの軸線との角度差（オモリ角度）が、常に０度付近に復元するような復元モーメントを発生させることが可能となる。また、船釣り用オモリが水中を降下する際の落下姿勢を抗力の小さい向きに安定させることが可能となる。
また、従来の船釣り用オモリの降下速度で漁を行ううえで不具合が生じていない場合には、船釣り用オモリの重さを従来のものと比較して軽くすることが可能となり、操業時の作業性を向上させることが可能となる。
【０１２２】
請求項４に記載した発明によれば、船釣り用オモリの重心位置を下げることが可能であり、また、比重の小さな素材を用いることによって、船釣り用オモリの全長を短く形成しつつ、復元力を大きくすることが可能となるので、操業性の良好な船釣り用オモリを提供できる。
【０１２３】
請求項５に記載した発明によれば、船釣り用オモリが水中を降下する際の落下姿勢を抗力の小さい向きに安定させることが可能となる。
【０１２４】
請求項６に記載した発明によれば、船釣り用オモリに安定化部材を装着して水中を降下させる際に、船釣り用オモリが本来降下するべき方向である鉛直方向と、船釣り用オモリの軸線との角度差（オモリ角度）が、常に０度付近に復元するような復元モーメントを発生させることが可能となる。また、船釣り用オモリが水中を降下する際の落下姿勢を抗力の小さい向きに安定させることが可能となる。
【０１２５】
したがって本発明に係る船釣り用オモリ並びに安定化部材によれば、オモリを抗力の少ない姿勢で安定して水中を降下せることが可能となる。
【０１２６】
また本発明に係る船釣り用オモリ並びに安定化部材によれば、オモリが水中を降下する際の姿勢を安定させて蛇行を防ぐことによって、オモリの走行距離を短くし、短時間に所定の深度まで降下させることが可能となる。
【０１２７】
また本発明に係る船釣り用オモリ並びに安定化部材によれば、オモリが水中を降下する際の落下姿勢を抗力の小さい向きに安定させることが可能となり、オモリを短時間に所定の深度まで降下させることが可能となる。
【０１２８】
また本発明に係る船釣り用オモリ並びに安定化部材によれば、潮流に流されにくく、狙った場所に短時間に降下させ易い船釣り用オモリを提供することが可能となる。これによって、漁獲効率を向上させることが可能となる。
【０１２９】
本発明で示したように、船釣り用オモリの重心より上部の投影面積の一次モーメントＭＵと、重心より下部の投影面積の一次モーメントＭＤの比をｋ＝ＭＵ／ＭＤとした場合に、２．３≦ｋ≦５．０を満たすような形状設計を行うことによって、比較的短時間で最適な船釣り用オモリの形状設計が可能となる。
【図面の簡単な説明】
【図１】 （ａ）は、本発明に係る船釣り用オモリ１０の平面図であり、（ｂ）は船釣り用オモリ１０の正面図である。
【図２】 （ａ）は、本発明に係る船釣り用オモリ１０Ａの平面図であり、（ｂ）は船釣り用オモリ１０Ａの正面図である。
【図３】 （ａ）は、本発明に係る船釣り用オモリ１０Ｂの平面図であり、（ｂ）は船釣り用オモリ１０Ｂの正面図である。
【図４】 （ａ）は、本発明に係る船釣り用オモリ１０Ｃの平面図であり、（ｂ）は船釣り用オモリ１０Ｃの正面図である。
【図５】 （ａ）は、本発明に係る船釣り用オモリ１０Ｄの平面図であり、（ｂ）は船釣り用オモリ１０Ｄの正面図である。
【図６】 （ａ）は、本発明に係る船釣り用オモリ１０Ｅの平面図であり、（ｂ）は船釣り用オモリ１０Ｅの正面図である。
【図７】 （ａ）は、本発明に係る船釣り用オモリ１０Ｆの平面図であり、（ｂ）は船釣り用オモリ１０Ｆの正面図である。
【図８】 （ａ）は、本発明に係る船釣り用オモリ１０Ｇの平面図であり、（ｂ）は船釣り用オモリ１０Ｇの正面図である。
【図９】 （ａ）は、本発明に係る船釣り用オモリ１０Ｈの平面図であり、（ｂ）は船釣り用オモリ１０Ｈの正面図である。
【図１０】 （ａ）は、本発明に係る船釣り用オモリ１０Ｊの平面図であり、（ｂ）は船釣り用オモリ１０Ｊの正面図である。
【図１１】 各種船釣り用オモリのＭＵ値とＭＤ値との算出結果と、重心周りのモーメントが０となる角度等の算出結果を示す図表である。
【図１２】 本発明に係るＡＳ羽付の型のオモリについて流体解析を行った結果を示す図である。
【図１３】 ＡＳ羽付のオモリを実際に制作して、オモリの降下実験を行った結果の「経過時間−瞬間速度線図」を示す図である。
【図１４】 樹脂製の模型による降下軌跡観察実験の結果を示す図である。
【図１５】 現在市販されている胴突き型のオモリについて測定した「経過時間−瞬間速度線図」を示す図である。
【図１６】 現在市販されているＡＳ型のオモリについて測定した「経過時間−瞬間速度線図」を示す図である。
【図１７】 現在市販されている胴突き型のオモリについて流体解析を行った結果を示す図である。
【図１８】 現在市販されているＡＳ型のオモリについて流体解析を行った結果を示す図である。
【符号の説明】
１０…船釣り用オモリ
１２…オモリ部材
１４…安定化部材
２０…吊環
２２…羽
２４…ピン
２６…螺子
２８…勘合部
３０…螺子部[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a boat fishing weight and a stabilizing member.
[0002]
[Prior art]
Conventionally, it is a steel molded product formed by forging a steel material, has a round head at the other end, and gradually reduces the diameter of the circular cross section at the neck root of the round head toward the one end. Symmetrical shape that has a streamlined shape with a small diameter, and is forged integrally with the outer surface of the vicinity of the one end in the axial direction from the one end to the other end 2. Description of the Related Art A steel forged weight for fishing is known that has a pair of anti-rotation blades (see claim 2 of Patent Document 1).
[0003]
According to the steel forged weight for fishing described in Patent Document 1 below, the anti-rotation wings allow the angler to glide with good direction stability toward the target position that the angler wants to throw in, and twisting of the fishing line. It is stated that it can be prevented. (See Patent Document 1).
[0004]
Conventionally, in a body weight used for fishing, a weight is known in which a flat surface is formed in the lower portion, the flat surface is formed inwardly inclined with respect to the axis, and a lower end portion is formed in a curved shape. (See Patent Document 2).
[0005]
In the trunk weight described in Patent Document 2 below, by forming the lower end portion of the trunk weight into a curved surface, the flow of water at the time of sedimentation becomes smooth, and a large sedimentation speed can be obtained. The effect that there is an effect that contributes to the improvement of is described. (For example, refer to Patent Document 2).
[0006]
In addition, hitoris having various shapes such as a barrel type, a BR type, a hexagonal type, and an eggplant type have been sold.
[0007]
[Patent Document 1]
Japanese Patent Laid-Open No. 11-289939 (Claim 2, page 1-3, FIG. 1)
[Patent Document 2]
JP 2002-223865A (Page 1-3, FIG. 1)
[0008]
[Problems to be solved by the invention]
In the steel forged weight for fishing described in Patent Document 1, it is possible to glide with good direction stability toward the target position that the angler wants to throw by the action of the anti-rotation wing (paragraph number [0019] of Patent Document 1). , [0023], and the description that it is possible to prevent twisting of the fishing line.
[0009]
However, in the steel forged weight for fishing described in Patent Document 1, since the wings exist only in one plane, when the weight descends underwater (particularly parallel to the surface of the wings), There is a problem that the running distance of the weight becomes longer. In addition, since the weight of the weight tends to be inclined in a plane parallel to the wing, the resistance of the weight increases, and there is a problem that the weight cannot be lowered to a predetermined depth in a short time.
[0010]
According to the barrel weight described in Patent Document 2, by forming the lower end portion of the barrel weight in a curved surface, the flow of water at the time of sedimentation becomes smooth, so-called separation phenomenon does not occur, and vortex flow does not occur (paragraph). No. [0013] (see description of number). For this reason, no negative pressure is generated at the upper end portion of the trunk weight, and the resistance of water is small, so that a large sedimentation speed can be obtained, and the weight settles quickly. Thereby, it is described that there is an effect that contributes to the improvement of fishing efficiency.
[0011]
However, in the trunk weight described in Patent Document (2), the weights meander when the weights descend in the water, so that the weight of the weights increases or the resistance of the weights increases as the weights tilt. , There was a problem that the weight could not be lowered to a predetermined depth in a short time.
[0012]
In addition, when a traditionally sold weight having various shapes, such as a barrel type, BR type, hexagonal type, eggplant type, AS type, is used for actual fishing, it reaches a predetermined depth after being dropped into water. It has been empirically known that the time until is different.
[0013]
Therefore, the relationship between the instantaneous speed and the elapsed time when the weights are dropped after various kinds of weights are dropped into the water is shown in the No. 150 (0.563 kg) cylinder thrust type, BR type, hexagonal type, eggplant Experiments were conducted on various types of AS-type and AS-type weights. Of the results, “elapsed time-instantaneous velocity diagrams” for the barrel thrust type and the AS type are shown in FIGS. 15 and 16.
[0014]
In addition, the descent experiment was carried out by the following method.
The electric reel was loaded with a No. 10 tegus (diameter 0.5 mm), which was thicker than the tegus normally used, and a weight was attached to the end of the tegus via untwisting.
A black mark with a length of 2 (cm) was put in every 48 (cm) with 50 (cm) as one unit.
Tegs was allowed to pass through the light sensor and collected the signal when the black mark passed through the light sensor. In the experiment, the state where the weights landed on the sea surface was taken as the experiment start position, the stopper of the electric reel was removed, the weights were allowed to fall naturally, and the time and signal until the 90 (m) Tegs were unfolded were measured. is there.
As described above, the reason for using a thicker teg than a commonly used teg is based on the width of the “black mark” that can be detected by the optical sensor for measuring the teg feed amount. In this experiment, a thicker gutter than usual is used, so it is considered that the descent time of the weight is taking longer due to the resistance of the water on the surface of the gutter than when using a normal thin gutter.
[0015]
As a result, the fluctuations in the instantaneous speed of the weight are large in the first few seconds of the elapsed time immediately after being put into the water in all the weights of the barrel thrust type, BR type, hexagonal type, eggplant type, and AS type. It has been found that there is a problem that the descent speed is not so high.
[0016]
As the depth of the newt increases, the length of the thread running in the water increases, so the resistance including the newt and the thread increases, and it is inevitable that the lowering speed of the newt will be reduced to some extent. It is speculated that the speed of descent of the newt in the shallow range with low resistance can be made faster.
[0017]
For example, as shown in FIG. 15, after a barrel-type type weight is thrown into water, the maximum instantaneous speed (about 370 cm / s) is reached in about 0.5 seconds, and then the instantaneous speed decreases rapidly, and then the instantaneous speed is reached. The fact that the increase and decrease is repeated was considered.
[0018]
The resistance of the water (drag) can vary greatly depending on the angle difference between the direction of descent of the weight and the axis of the weight, which is the direction in which the weight should descend (hereinafter referred to as “the weight angle”). There is sex. Therefore, the weight angle increases as a result of a drastic change in the descent posture of the weight, and the drag force of the weight increases rapidly, so the instantaneous speed of the weight decreases rapidly, and the instantaneous speed increases or decreases. I guessed that it was repeated.
[0019]
Therefore, fluid analysis (simulation) was performed on the weights of various types of commercially available No. 150 (0.563 kg) barrel thrust type, BR type, hexagonal type, eggplant type, and AS type, and the angle We investigated the drag, lift and moment around the center of gravity. Among these results, “Omitted angle-drag, lift, moment diagram around the center of gravity and fluid analysis result diagram” for the barrel thrust type and AS type are shown in FIGS. 17 and 18. The drag is calculated as a drag (N) at 4 (m / s), which is regarded as a general descent speed.
[0020]
As a result of fluid analysis of various types of weights, such as a barrel thrust type, BR type, hexagonal type, eggplant type, and AS type, when the weight angle increases slightly from 0 degree, the moment around the center of gravity is positive. It was found to show a value (rotational moment works in a direction that promotes the inclination of the weight).
[0021]
The moment around the center of gravity does not generate a restoring force unless the weight angle is 45 degrees or more even if the AS type weight shows the best value (the moment around the center of gravity does not become a negative value). ) Also turned out.
[0022]
This means that there is a high possibility that even an AS type weight having the best restoration performance will descend underwater based on a posture having a weight angle of 45 degrees.
[0023]
In addition, AS type weights have a resistance at the weight angle where the moment around the center of gravity is zero, which is about 7 (N), which is the highest compared to other barrel-type, BR-type, hexagonal and eggplant-type types. Shows less drag.
[0024]
Furthermore, an experimental result was obtained that the time to reach a predetermined depth was the shortest (27.3 seconds) among various weights of various types such as a barrel type, BR type, hexagonal type, eggplant type, and AS type. This means that the results are consistent with each other and both are reliable.
[0025]
Further, according to the results of the fluid analysis shown in FIGS. 17 and 18, in the vicinity of the weight angle at which the moment around the center of gravity becomes zero (in the example shown in FIG. 17, about 82 degrees), the weight has an increase in the weight angle. Accordingly, lift (lateral force transverse to the descending direction) is generated.
[0026]
Therefore, when a weight angle occurs in the falling weight, it is predicted that the weight meanders. Thus, if meandering occurs when the weight is descending, the traveling distance of the weight is significantly increased, so that it is predicted that a problem that the time until it reaches a predetermined depth will be increased.
[0027]
Therefore, in view of the above-described conventional situation, the present invention provides a restoring moment that always restores the angle difference (the weight angle) between the vertical direction in which the weight should descend and the weight axis always around 0 degrees. It is an object of the present invention to provide a boat fishing weight and a stabilizing member having a generated shape or structure.
[0028]
Another object of the present invention is to provide a boat fishing weight and a stabilizing member that can stably descend underwater in a posture with less drag.
[0029]
Further, the present invention provides a boat fishing weight that can shorten the traveling distance of the weight and lower it to a predetermined depth in a short time by stabilizing the posture when the weight descends underwater and preventing meandering. The object is to provide a stabilizing member.
[0030]
The present invention also provides a boat fishing weight and a stabilizing member that can be lowered to a predetermined depth in a short time by stabilizing the falling posture when the weight descends underwater in a direction with a small drag. The purpose is that.
[0031]
Another object of the present invention is to provide a boat fishing weight and a stabilizing member that are less likely to be swept away by a tidal current and that can be easily lowered to a target location.
Another object of the present invention is to provide a boat fishing weight and a stabilizing member capable of improving fishing efficiency.
[0032]
On the other hand, in the conventional boat fishing weight development and design process, the shape of the boat fishing weight is determined based on the intuition and experience of the weight designer. Further, based on the shape of the boat fishing weight as considered by the designer, the design work proceeds by a method of determining the final shape of the boat fishing weight by trial and error such as fluid analysis and numerous experiments. It was done. Therefore, there has been a problem that a great deal of time and labor is required until the shape of the boat fishing weight is finally determined.
[0033]
In designing the shape of a boat fishing weight, the present invention sets the ratio of the primary moment MU of the projected area above the center of gravity of the boat fishing weight and the primary moment MD of the projected area below the center of gravity to k = MU / An object of the present invention is to provide a weight design method capable of designing an optimum weight shape in a relatively short time by designing so that the value of k falls within a predetermined range when MD is used.
[0034]
The boat fishing weight according to claim 1 is a projection above the center of gravity in each of any two projection planes that are parallel to and perpendicular to an axis passing through the center of gravity or in the vicinity of the center of gravity. When the ratio of the primary moment MU of the area and the primary moment MD of the projected area below the center of gravity is k = MU / MD, the shape satisfies 2.3 ≦ k ≦ 5.0.
[0035]
According to the above configuration, in each of any two projection planes passing through the center of gravity or parallel to an axis where the center of gravity exists in the vicinity and perpendicular to each other, a primary moment MU above the center of gravity, When the ratio of the primary moment MD below the center of gravity is k = MU / MD, the shape satisfies 2.3 ≦ k ≦ 5.0. It is possible to generate a restoring moment so that the angle difference (the weight angle) between the vertical direction in which the fishing weight should originally descend and the axis of the boat fishing weight is always restored to around 0 degrees. . In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag. Thereby, it can fall to a predetermined depth for a short time.
[0036]
Further, according to the present invention, when the ratio of the primary moment MU of the projected area above the center of gravity of the boat fishing weight and the primary moment MD of the projected area below the center of gravity is k = MU / MD, the value of k Since the shape of the boat fishing weight is designed so as to fall within a predetermined range, an appropriate shape of the weight can be designed in a relatively short time.
[0037]
The fishing weight described in claim 2 has a plurality of wings that increase the primary moment MU of the projected area above the center of gravity described in claim 1 within a range satisfying 2.3 ≦ k ≦ 5.0. It is characterized by being formed on the top.
[0038]
According to the above configuration, a restoring moment is generated such that the angle difference (the weight angle) between the vertical direction in which the boat fishing weight should originally descend and the weight axis always recovers near 0 degrees. It becomes possible. In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag.
[0039]
The boat fishing weight according to claim 3 has a function of increasing the primary moment MU of the projected area above the center of gravity according to claim 1 or 2 within a range satisfying 2.3 ≦ k ≦ 5.0. A separate stabilization member provided is provided on the top of the weight member.
[0040]
According to the above configuration, the restoring moment that the angle difference (the weight angle) between the vertical direction in which the boat fishing weight should originally descend and the axis line of the boat fishing weight is always restored to around 0 degrees. Can be generated. In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag.
[0041]
A boat fishing weight according to a fourth aspect is characterized in that the stabilizing member according to the third aspect is formed of a material having a specific gravity smaller than that of the weight member.
According to this configuration, it is possible to lower the center of gravity position of the boat fishing weight, and by using a material having a small specific gravity, it is possible to increase the restoring force while shortening the overall length of the boat fishing weight. Therefore, it is possible to provide a boat fishing weight with good operability.
[0042]
The boat fishing weight according to claim 5 is characterized in that the stabilizing member according to claim 3 or 4 is formed of an elastic material and is mounted by covering the weight member.
[0043]
According to said structure, it becomes possible to stabilize the fall attitude | position at the time of the ship fishing descent descending underwater in the direction where resistance is small.
[0044]
The stabilizing member to be mounted on the boat fishing weight according to claim 6 is provided on each of any two projection planes that are parallel to an axis passing through the center of gravity or in the vicinity of the center of gravity and perpendicular to each other. When the ratio of the primary moment MU of the projected area above the center of gravity and the primary moment MD of the projected area below the center of gravity is k = MU / MD, the shape satisfies 2.3 ≦ k ≦ 5.0. The structure includes a mounting portion for mounting on the boat fishing weight, and the primary moment MU of the projected area above the center of gravity is within a range satisfying 2.3 ≦ k ≦ 5.0. It has a function to enlarge.
[0045]
According to the above configuration, when the stabilization member is attached to the boat fishing weight and descends the water, the vertical direction that the boat fishing weight should originally descend and the axis of the boat fishing weight are It is possible to generate a restoring moment such that the angle difference (the weight angle) is always restored to around 0 degrees. In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag.
[0046]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail.
[0047]
Fig.1 (a) and FIG.1 (b) are figures which show the 1st Example of the boat fishing weight based on this invention.
FIG. 1A is a plan view of the boat fishing weight 10, and FIG. 1B is a front view of the boat fishing weight 10.
As shown in the figure, the fishing rod 10 for fishing is provided with a hanging ring 20 that links the weight to the teg string.
[0048]
As shown in FIG. 1B, the boat fishing weight 10 has an axis C parallel to the direction in which the boat fishing weight should originally descend. In general, the center of gravity G of the weight exists on the axis C or in the vicinity thereof. Here, assuming a projection plane existing in a direction parallel to the axis C of the boat fishing weight 10, the projected area of the boat fishing weight 10 is expressed by the following equation (1).
[Expression 1]
ΔA = XZ × ΔZ (1)
ΔA: Minute projection area at a position separated from the center of gravity by a distance Z along the axis C
XZ: Average width in the direction perpendicular to the axis C in the portion of the minute area ΔA
ΔZ: Minute width parallel to the axis C
[0049]
Next, assuming that the sum of the projected areas of the boat fishing weight above the center of gravity G is AU and the position of the centroid of the AU is LU, the restoring moment MU (above the center of gravity G above the center of gravity G) The first moment of the projected area is expressed by the following equation (2).
[Expression 2]

MU: Restoring moment (primary moment of the projected area above the center of gravity G)
AU: Total projected area of boat fishing weight above center of gravity G
LU: AU centroid position
[0050]
Similarly, assuming that the total projected area of the boat fishing weight below the center of gravity G is AD and the position of the centroid of the AD is LD, the rotational moment MD of the boat fishing weight 10 (from the center of gravity G) The first moment of the lower projected area is expressed by the following equation (3).
[Equation 3]

MD: Rotational moment (primary moment of the projected area below the center of gravity G)
AD: Total projected area of boat fishing weight below center of gravity G
LD: AD centroid position
[0051]
Here, the rotational moment MD is a moment that generates a force for rotating the axis C of the boat fishing weight 10 in a direction different from the vertical direction by the action of a water flow when the boat fishing weight 10 descends underwater.
[0052]
Conversely, the previous restoring moment MU is a moment that generates a force that returns the axis C of the boat fishing weight 10 in the same direction as the vertical direction due to the action of the water flow when the boat fishing weight 10 descends underwater.
[0053]
Here, the ratio of the restoring moment MU and the rotational moment MD is k = MU / MD. If the value of k can be increased, a moment for restoring the axis C in the vertical direction (gravity direction) always works when the fishing net 10 descends underwater. Then, the angle difference (the weight angle) between the vertical direction and the axis C of the boat fishing weight 10 always restores to around 0 degrees, so the boat fishing weight 10 descends stably with a low drag posture. The effect of doing.
[0054]
However, the larger the value of k, the better the results for boat fishing weights in all aspects of performance. However, if the value of k is too large, the projected area itself generally tends to increase. For this reason, when a boat fishing weight descends underwater, it tends to be washed away by the tide. Then, the problem that it becomes difficult for the boat fishing weight to descend to the target position occurs. As a result, the boat fishing weight 10 is washed away at a position different from the position where the school of fish is present, which causes a problem that the catch is reduced.
[0055]
Then, when the experiment was repeated on the actual product, it was found that the purpose can be generally achieved when the value of k of the fishing weight 10 has a shape satisfying the equation (4).
[Expression 4]
2.3 ≦ k ≦ 5.0 (4)
[0056]
When the boat fishing weight 10 descends underwater, the angular difference (the weight angle) between the vertical direction and the axis C of the boat fishing weight 10 is always restored to around 0 degrees in all directions, In order to descend underwater with low lift, the requirement of the above formula (4) is satisfied on any two projection planes that are parallel to the axis C of the boat fishing weight 10 and are perpendicular to each other. There is a need.
[0057]
2 (a) and 2 (b) are views showing a second embodiment of the boat fishing weight according to the present invention.
2A is a plan view of the boat fishing weight 10A, and FIG. 2B is a front view of the boat fishing weight 10A.
[0058]
A fishing ring 10A shown in the figure is provided with a suspension ring 20. In the example shown in the figure, wing-shaped wings 22A are radially formed with respect to the four axis C on the upper part of the boat fishing weight 10A.
[0059]
When the ratio of the primary moment MU of the projected area above the center of gravity of the boat fishing weight 10A and the primary moment MD of the projected area below the center of gravity is k = MU / MD by the action of the wing 22A, k = MU / MD When the boat fishing weight 10A descends underwater, the angle difference (the weight angle) between the vertical direction and the axis C of the boat fishing weight 10A is always restored to around 0 degrees, and the drag and lift It is possible to descend underwater in a state where there is little.
[0060]
In addition, by using the configuration of the wing 22A shown in the figure, the requirement of k ≧ 2.3 can be effectively satisfied in any two projection planes parallel to the axis C and perpendicular to each other. It becomes possible.
[0061]
In the example shown in the figure, an example in which four wings 22A are provided has been described. However, the present invention does not limit the number of wings. In a shape that bends in parallel with the axis C, and so on, in any two projection planes that are parallel to the axis C of the fishing rod and are perpendicular to each other, 2.3 ≦ k ≦ 5.0 If it satisfies, when the boat fishing weight descends underwater, the angle difference (weight angle) between the vertical direction and the axis C of the boat fishing weight 10 is always restored to around 0 degrees in all directions, It is possible to descend underwater with little lift. Similarly, the number of wings may be two, three, five or more, or a spline shape. A balanced shape that does not rotate is preferred.
[0062]
In general, the weight of boat fishing weights is often lead with a large specific gravity. Since lead is a soft material, when the boat fishing weight has an elongated shape, there is a possibility that the weight itself bends when a force is applied during operation or standby.
[0063]
However, since the wing 20A has a large surface area for its volume, as shown in the figure, the wing 22A is provided on the boat fishing weight 10A to shorten the boat fishing weight 10A and increase the restoring force. Is possible. Therefore, even when force is applied to the weight during operation or standby, it is possible to reduce the occurrence of a problem that the weight itself bends.
[0064]
FIG. 3A and FIG. 3B are diagrams showing a third embodiment of the boat fishing weight according to the present invention and showing a case where k = 3.1.
[0065]
4 (a) and 4 (b) show a fourth embodiment of the boat fishing weight according to the present invention, and shows a case where k = 3.6.
[0066]
5 (a) and 5 (b) are diagrams showing a fifth embodiment of the boat fishing weight according to the present invention and showing a case where k = 4.0.
[0067]
6 (a) and 6 (b) is a sixth embodiment of a boat fishing weight according to the present invention.
[0068]
As shown in the figure, a hanging ring 20 is provided on the boat fishing weight 10E. Further, the boat fishing weight 10E has a projected area above the center of gravity of the weight member 12E for generating a force for lowering the boat fishing weight 10E in water by mass and gravitational acceleration, and the center of gravity of the boat fishing weight 10E. A separate stabilization member 14E having a function of increasing the primary moment MU, and a pin 24 to be fixed or attached so as not to separate the weight member 12E and the stabilization member 14E are provided.
[0069]
As shown in the figure, the stabilization member 14E is provided with a mounting portion that is mounted on the weight member 12E while being in contact with the weight member 12E. The stabilization member 14E attached to the weight member 12E has a shape that generates lift or drag when the falling direction of the boat fishing weight 10E and the axis C are inclined.
[0070]
Therefore, when the boat fishing weight 10E descends underwater, the angle difference (the weight angle) between the vertical direction and the axis C of the boat fishing weight 10E is always set by the action of lift or drag generated by the stabilizing member 14E. It is possible to descend the water while restoring the vicinity of 0 degrees and maintaining a state where the drag and lift of the boat fishing weight 14E are small.
[0071]
In the example shown in the figure, the stabilizing member 14E has a wing shape, and four wings are configured radially with respect to the axis C. By the action of the stabilizing member 14E, the ratio k between the primary moment MU of the projected area above the center of gravity of the fishing weight 10E and the primary moment MD of the projected area below the center of gravity is 2.3 ≦ k ≦ 5.0. It becomes possible to satisfy.
[0072]
In the example shown in the figure, the stabilizing member 14E has a wing shape, but the present invention is not limited to the wing shape, and the primary moment MU of the projected area above the center of gravity of the fishing rod 10E. Any shape can be used as long as it has a function of increasing the number of wings.
[0073]
Further, since the stabilizing member 14E is provided on the upper part of the boat fishing weight 10E, it is preferable to use a material having physical properties with a specific gravity smaller than that of the weight member 10E (for example, a light metal such as resin or aluminum). This is because it is possible to lower the position of the center of gravity of the boat fishing weight 10E.
[0074]
In addition, by using a material having a small specific gravity, it is possible to increase the restoring force while shortening the overall length of the boat fishing weight 10E, so that it is possible to provide a boat fishing weight with good operability. It becomes.
[0075]
In addition, when the stabilizing member 14E has a wing shape, and the wing is thin and long, the wing-shaped portion is bent or broken when a force is applied during operation or standby. There is a possibility. Therefore, do not make the shape too thin, do not make the wing shape elongated radially with respect to the axis C, select a material that is difficult to bend, or select a material that returns to its original state without being damaged even if it is bent, such as rubber. Consideration should be given.
[0076]
Further, by separating the weight member 12E and the stabilization member 14E, even if the weight itself has no restoring force in the vicinity of the weight angle 0 °, like the conventional fishing weight, By attaching the stabilizing member 14E later, it is possible to generate a restoring force for the conventional weight. Even when a conventional weight is used, it is possible to descend to a predetermined depth in a short time.
[0077]
Further, in the embodiment shown in FIG. 6, the pin 24 is used as a method for fixing or mounting so that the weight member 12 </ b> E and the stabilization member 14 </ b> E are not separated from each other, but the fixing method is not limited to the pin 24. Instead, it may be fixed using a connecting member such as a screw, may be fixed by providing a fitting portion, or may be fixed by providing a screw portion.
[0078]
Further, the stabilizing member 14E is made of an elastic material such as rubber or soft resin so that the weight member 12E is covered with a sack, and the elasticity (restoration) of the stabilizing member 14E. The object of the present invention can be achieved even if it is fixed to the weight member 12E or attached to the weight member 12E.
[0079]
7 (a) and 7 (b) is a seventh embodiment of a boat fishing weight according to the present invention.
As shown in the figure, a hanging ring 20 is provided on the boat fishing weight 10F. Also, the boat fishing weight 10F includes a weight member 12F for generating a force for lowering the boat fishing weight 10F in water by mass and gravitational acceleration, and a projected area above the center of gravity of the boat fishing weight 10F. A separate stabilizing member 14F having a function of increasing the primary moment MU, a screw 26 (one form of a coupling member) and a fitting portion 28 that are coupled so that the weight member 12F and the stabilizing member 14F are not separated from each other are provided. ing.
[0080]
In addition, in the same figure, although shown in the Example provided with both the screw 26 and the fitting part 28, the structure provided only with either one may be sufficient, and the weight member 12F and the stabilization member 14F are In order to prevent separation, a method such as adhesion, welding, or fitting having a toothed joint may be used.
[0081]
In the example shown in the figure, the stabilizing member 14F has a wing shape, and four wings are configured radially with respect to the axis C. By the action of the stabilizing member 14F, the ratio k between the primary moment MU of the projected area above the center of gravity of the fishing weight 10F and the primary moment MD of the projected area below the center of gravity is 2.3 ≦ k ≦ 5.0. It becomes possible to satisfy.
[0082]
When the boat fishing weight 10F descends underwater, the angle difference (the weight angle) between the vertical direction and the axis C of the boat fishing weight 10F is always restored to around 0 degrees, so that there is little drag and lift. It is possible to descend underwater in the state.
[0083]
In the example shown in the figure, the stabilizing member 14F has a wing shape, but the present invention is not limited to the wing shape, and the primary moment MU of the projected area above the center of gravity of the fishing rod 10F. As long as the shape has a function of increasing the number of wings, it is not related to the number of wings, for example.
[0084]
Further, since the stabilizing member 14F is provided on the upper part of the boat fishing weight 10F, it is preferable to use a material having physical properties smaller in specific gravity than the weight member 10F (for example, a light metal such as resin or aluminum).
[0085]
Further, by using a material having a small specific gravity, it is possible to increase the restoring force while shortening the overall length of the boat fishing weight 10F, so that it is possible to provide a boat fishing weight with good operability. It becomes.
[0086]
In addition, when the stabilizing member 14F has a wing shape, and the wing is thin and long, the wing-shaped portion may be bent or broken when force is applied during operation or standby. There is a possibility. Therefore, a material that is not so thin, that is not formed into a long and narrow wing shape radially with respect to the axis C, a material that is difficult to be plastically deformed, or a material that returns to its original state without being damaged even when bent, such as rubber, is selected. It is good to consider such things.
[0087]
Moreover, in the example shown in the figure, although the hanging ring 20 is shown in the Example fixed to the weight member 12F, this invention is not limited to this, The hanging ring 20 is fixed to the stabilization member 14F. It may be.
[0088]
8 (a) and 8 (b) is an eighth embodiment of a boat fishing weight according to the present invention.
[0089]
As shown in the figure, a hanging ring 20 is provided on the boat fishing weight 10G. Further, the boat fishing weight 10G includes a weight member 12G for generating a force for lowering the boat fishing weight 10G in water by mass and gravitational acceleration, and a projected area above the center of gravity of the boat fishing weight 10G. A separate stabilization member 14G having a function of increasing the primary moment MU is provided.
[0090]
The weight member 12G and the stabilization member 14G are coupled so as not to be separated via the suspension ring shaft 20A (shaft member).
[0091]
In the example shown in the figure, the stabilizing member 14G has a wing shape, and four wings are configured radially with respect to the axis C. By the action of the stabilizing member 14G, the ratio k between the primary moment MU of the projected area above the center of gravity of the fishing weight 10G and the primary moment MD of the projected area below the center of gravity is 2.3 ≦ k ≦ 5.0. It becomes possible to satisfy.
[0092]
When the boat fishing weight 10G descends underwater, the angle difference (the weight angle) between the vertical direction and the axis C of the boat fishing weight 10G is always restored to around 0 degrees, so that there is little drag and lift. It is possible to descend underwater in the state.
[0093]
In the example shown in the figure, the stabilizing member 14G has a wing shape, but the present invention is not limited to the wing shape, and the primary moment MU of the projected area above the center of gravity of the fishing rod 10G. As long as the shape has a function of increasing the number of wings, it is not related to the number of wings, for example.
[0094]
Further, as shown in FIGS. 9A and 9B, the stabilizing member 14H is formed in a shape without providing wings so that k satisfies 2.3 ≦ k ≦ 5.0. The object of the present invention can be achieved.
[0095]
Further, since the stabilization member 14G is provided on the upper part of the boat fishing weight 10G, it is preferable to use a material having physical properties with a specific gravity smaller than that of the weight member 10G (for example, a light metal such as resin or aluminum). This is because the position of the center of gravity of the boat fishing weight 10G can be lowered.
[0096]
Further, by using a material with a small specific gravity, it is possible to increase the restoring force while shortening the overall length of the boat fishing weight 10G, and therefore it is possible to provide a boat fishing weight with good operability. It becomes.
[0097]
In addition, when the stabilizing member 14G has a wing shape, and the wing is thin and long, the wing-shaped portion is bent or broken when a force is applied during operation or standby. There is a possibility.
[0098]
Therefore, do not make the shape too thin, do not make the wing shape elongated radially with respect to the axis C, select a material that is difficult to bend, or select a material that returns to its original state without being damaged even when bent, such as rubber. Consideration should be given.
[0099]
In the embodiment shown in FIGS. 8 and 9, the example in which the stabilizing member 14 </ b> G or the stabilizing member 14 </ b> H is coupled to the suspension ring 20 is shown, but the present invention is not limited to this. Therefore, even when the stabilizing member 14G or the stabilizing member 14H is coupled to the Tegg yarn near the suspension ring 20, the object of the present invention may be achieved as follows.
[0100]
The stabilizing member coupled to the Tegs yarn generates a drag force or a lift force according to the posture during the descent. Since the stabilizing member coupled to the Tegs yarn is connected to the boat fishing weight via the Tegs yarn, a restoring force acts on the boat fishing weight in a direction to return the axis C to the descending direction. Therefore, even when the boat fishing weight itself does not have a restoring force, it may be possible to generate a restoring force with respect to the boat fishing weight.
[0101]
10 (a) and 10 (b) is a tenth embodiment of a boat fishing weight according to the present invention.
The embodiment shown in the figure is the embodiment shown in FIG. 7 in which the stabilizing member 14J is formed in a shape without providing wings so that k satisfies 2.3 ≦ k ≦ 5.0. It is a form.
[0102]
As shown in the figure, a hanging ring 20 is provided on the boat fishing weight 10J. The boat fishing weight 10J includes a weight member 12J for generating a force for lowering the boat fishing weight 10J in water by mass and gravitational acceleration, and a projected area above the center of gravity of the boat fishing weight 10J. A separate stabilizing member 14J having a function of increasing the primary moment MU, and a screw portion 30 that is coupled so that the weight member 12J and the stabilizing member 14J are not separated are provided.
[0103]
In the figure, an embodiment is shown in which the thread member 30 is provided so that the weight member 12J and the stabilization member 14J are screwed together so that they are not separated from each other. They may be combined or may be combined by fitting. The stabilizing member 14J may have a cap shape with respect to the boat fishing weight 10J.
[0104]
In the example shown in the figure, by the action of the stabilizing member 14J, the ratio k of the primary moment MU of the projected area above the center of gravity of the fishing rod 10J and the primary moment MD of the projected area below the center of gravity is set to a preferable value. It becomes possible to set.
[0105]
Then, when the boat fishing weight 10J descends underwater, the angle difference (the weight angle) between the vertical direction and the axis C of the boat fishing weight 10J is always restored to near 0 degrees, and the drag and lift are small. It is possible to descend underwater in the state.
[0106]
In the embodiment shown in the figure, since no wings are provided, there is an advantage that the shape of the boat fishing weight 10J can be formed into a streamlined shape with less drag. For example, even in the case of having the shape of the barrel butt weight shown in FIG. 17 which cannot be said to be a perfect streamline type, the drag force is 0.25 (N) to 0.37 (N ) About small. As described above, the object of the present invention can be achieved even when the stabilizing member 14J has a substantially line-symmetric shape with respect to the axis C.
[0107]
As described above, even when the specific gravity of the boat fishing weight 10J is somewhat reduced by using a material having a small specific gravity for the stabilizing member 14J in order to obtain a predetermined value of k, the drag is low. This makes it possible to increase the descending speed of the boat fishing weight 10J, and to descend to a predetermined depth in a short time.
[0108]
Further, by configuring the stabilizing member 14J separately from the weight member 12J, it is possible to supply a boat fishing weight having a high descent speed and a short descent time at a low cost.
[0109]
The chart of FIG. 11 shows the calculation results of the MU value and the MD value of various boat fishing weights, and the calculation results of the angle at which the moment around the center of gravity is zero.
[0110]
As shown at the bottom of the chart, in the case where wings are provided on the upper part of the AS type fishing rod, when MU / MD = 3.1, the angle at which the moment around the center of gravity is 0 is 0. It is °. Therefore, in this case, it is expected that the boat fishing weight will descend underwater while being restored so that the weight angle is always 0 °.
[0111]
FIG. 12 shows the survey results of the weight angle, drag force, lift force, and moment around the center of gravity when fluid analysis is performed on the AS winged type weight when k = 2.5. As shown in the figure, it can be seen that when the weight angle increases slightly from 0 degree, the moment around the center of gravity shows a negative value (rotation moment works in the direction to restore the weight inclination). . In this case, the boat fishing weight is expected to descend underwater while being restored so that the weight angle is always 0 °. Therefore, it is expected to fall with a low drag.
[0112]
FIG. 13 shows an “elapsed time-instantaneous velocity diagram” as a result of actually producing a weight with AS feathers and conducting a weight decrease experiment.
The weight drop experiment is the result of the same conditions as in FIGS. 15 and 16.
[0113]
As shown in the figure, it can be seen that the AS with wings has an instantaneous velocity of about 670 (cm / s) immediately after being introduced into the water, and is falling stably with no fluctuation in velocity.
[0114]
Furthermore, the descent time is 25.7 (seconds), which is about 6% shorter than the conventional best AS type. This is a case where a thick test piece is used, and it is obvious that the difference becomes larger when a normal thin test piece is used.
[0115]
FIG. 14 shows the results of a descent trajectory observation experiment using a resin half scale model.
The AS-type and AS-winged weight model material uses a photocuring resin having a specific gravity of 1.2 for the purpose of reducing the descent speed in order to facilitate observation. The side surface of the water tank used for the descent trajectory observation experiment is made of glass, making it easy to observe the descent trajectory of the model. In addition, the unit of the numerical value shown in the figure is (cm).
[0116]
The angle at which the moment around the center of gravity of the AS model is zero is 45 °, and the drag at that time is 6.8 (N).
The angle at which the moment around the center of gravity of one AS-winged model becomes 0 is 0 °, and the drag at that time is 1.4 (N).
[0117]
As a result of the observation experiment of the descent trajectory using the resin model, the AS type model descended in the vertical direction and then descended in the vertical direction, then tilted about 45 °, and then descended while increasing / decreasing the tilt.
[0118]
One AS winged model descended almost straight, with a slight swing. This observation result was in good agreement with the resilience simulation result, confirming that the inference was correct.
[0119]
According to the first aspect of the present invention, when the boat fishing weight is lowered, the angle difference between the vertical direction in which the boat fishing weight should originally descend and the axis of the boat fishing weight (the weight angle). However, it is possible to generate a restoring moment that always restores to around 0 degrees. In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag. Thereby, it can fall to a predetermined depth for a short time.
[0120]
In addition to the common effects obtained by the inventions according to claims 1 to 6, the invention described in each claim can obtain the following effects.
According to the invention described in claim 2, the angle difference (the weight angle) between the vertical direction in which the boat fishing weight should originally descend and the weight axis is always restored to around 0 degrees. A moment can be generated. In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag.
[0121]
According to the third aspect of the present invention, the angle difference (the weight angle) between the vertical direction in which the boat fishing weight should originally descend and the axis of the boat fishing weight is always restored to around 0 degrees. Such a restoring moment can be generated. In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag.
In addition, if there are no problems with fishing at the speed at which the conventional boat fishing weight descends, the weight of the boat fishing weight can be reduced compared to the conventional one. It is possible to improve the workability.
[0122]
According to the invention described in claim 4, it is possible to lower the center of gravity position of the boat fishing weight, and by using a material having a small specific gravity, the entire length of the boat fishing weight is shortened and restored. Since it is possible to increase the force, it is possible to provide a boat fishing weight with good operability.
[0123]
According to the fifth aspect of the present invention, it is possible to stabilize the dropping posture when the boat fishing weight descends underwater in a direction with a small drag.
[0124]
According to the invention described in claim 6, when the stabilizing member is attached to the boat fishing weight and the water is lowered, the vertical direction in which the boat fishing weight should originally descend, and the boat fishing weight It is possible to generate a restoring moment so that the angle difference (a new angle) with respect to the axis always restores to around 0 degrees. In addition, it is possible to stabilize the falling posture when the boat fishing weight descends underwater in a direction with a small drag.
[0125]
Therefore, according to the boat fishing weight and the stabilizing member according to the present invention, it is possible to stably descend the water in a posture with less drag.
[0126]
Further, according to the boat fishing weight and the stabilizing member according to the present invention, the posture when the weight descends underwater is stabilized to prevent meandering, thereby shortening the traveling distance of the weight and shortening the predetermined depth in a short time. It is possible to descend to.
[0127]
Further, according to the boat fishing weight and the stabilizing member according to the present invention, it is possible to stabilize the falling posture when the weight descends in the water in a direction with a small drag, and the weight is lowered to a predetermined depth in a short time. It becomes possible to make it.
[0128]
Further, according to the boat fishing weight and the stabilizing member according to the present invention, it is possible to provide a boat fishing weight that is less likely to be washed away by a tidal current and can be easily lowered to a target location in a short time. This makes it possible to improve fishing efficiency.
[0129]
As shown in the present invention, when the ratio of the primary moment MU of the projected area above the center of gravity of the boat fishing weight and the primary moment MD of the projected area below the center of gravity is k = MU / MD, By designing the shape so as to satisfy 3 ≦ k ≦ 5.0, it is possible to design the optimum shape of the fishing boat weight in a relatively short time.
[Brief description of the drawings]
FIG. 1 (a) is a plan view of a boat fishing weight 10 according to the present invention, and FIG. 1 (b) is a front view of the boat fishing weight 10;
2A is a plan view of a boat fishing weight 10A according to the present invention, and FIG. 2B is a front view of the boat fishing weight 10A.
3A is a plan view of a boat fishing weight 10B according to the present invention, and FIG. 3B is a front view of the boat fishing weight 10B.
4 (a) is a plan view of a boat fishing weight 10C according to the present invention, and FIG. 4 (b) is a front view of the boat fishing weight 10C.
5A is a plan view of a boat fishing weight 10D according to the present invention, and FIG. 5B is a front view of the boat fishing weight 10D.
6A is a plan view of a boat fishing weight 10E according to the present invention, and FIG. 6B is a front view of the boat fishing weight 10E.
7 (a) is a plan view of a boat fishing weight 10F according to the present invention, and FIG. 7 (b) is a front view of the boat fishing weight 10F.
8A is a plan view of a boat fishing weight 10G according to the present invention, and FIG. 8B is a front view of the boat fishing weight 10G.
9A is a plan view of a boat fishing weight 10H according to the present invention, and FIG. 9B is a front view of the boat fishing weight 10H.
10A is a plan view of a boat fishing weight 10J according to the present invention, and FIG. 10B is a front view of the boat fishing weight 10J.
FIG. 11 is a chart showing calculation results of MU values and MD values of various fishing boat weights, and calculation results of angles at which moments around the center of gravity are zero.
FIG. 12 is a diagram showing the result of fluid analysis of an AS winged type weight according to the present invention.
FIG. 13 is a view showing an “elapsed time-instantaneous velocity diagram” as a result of actually producing a weight with AS feathers and conducting a weight descending experiment.
FIG. 14 is a diagram showing the results of a descent trajectory observation experiment using a resin model.
FIG. 15 is a diagram showing an “elapsed time-instantaneous velocity diagram” measured with respect to a barrel-type type weight currently on the market.
FIG. 16 is a diagram showing an “elapsed time-instantaneous velocity diagram” measured for AS type weights currently on the market.
FIG. 17 is a diagram showing the result of fluid analysis performed on a cylindrical thruster currently on the market.
FIG. 18 is a diagram showing the results of fluid analysis of an AS-type weight currently on the market.
[Explanation of symbols]
10 ... Boat fishing weights
12 ... weight member
14 ... Stabilizing member
20 ... Hanging ring
22 ... feathers
24 ... pin
26 ... Screw
28 ... Fitting part
30 ... Screw part

Claims (6)

The first moment MU of the projected area above the center of gravity and the projection below the center of gravity on each of any two projection planes that pass through the center of gravity or are parallel to an axis in the vicinity of the center of gravity and perpendicular to each other. A boat fishing weight characterized by having a shape satisfying 2.3 ≦ k ≦ 5.0 when the ratio of the primary moment MD of the area is k = MU / MD. The boat fishing according to claim 1, wherein a plurality of wings are formed on the upper portion to increase the primary moment MU of the projected area above the center of gravity within a range satisfying 2.3 ≦ k ≦ 5.0. Forts. A separate stabilizing member having a function of increasing the primary moment MU of the projected area above the center of gravity within a range satisfying 2.3 ≦ k ≦ 5.0 is provided above the weight member. The weight for boat fishing according to claim 1 or 2 . The boat fishing weight according to claim 3, wherein the stabilizing member is formed of a material having a specific gravity smaller than that of the weight member . The boat fishing weight according to claim 3 or 4, wherein the stabilizing member is formed of an elastic material and is mounted by covering the stabilizing member . The first moment MU of the projected area above the center of gravity and the projection below the center of gravity on each of any two projection planes that pass through the center of gravity or are parallel to an axis in the vicinity of the center of gravity and perpendicular to each other. When the ratio of the primary moment MD of the area is k = MU / MD, the stabilizing member is attached to the boat fishing weight having a shape satisfying 2.3 ≦ k ≦ 5.0,
With a mounting portion for mounting on the boat fishing weight,
A stabilizing member to be mounted on a fishing rod , which has a function of increasing a primary moment MU of a projected area above the center of gravity within a range satisfying 2.3 ≦ k ≦ 5.0 .

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