JP3834674B2 - Optical disc driving device, optical information recording device, optical information reproducing device, and disc cartridge used therefor - Google Patents

Description

【００７１】
（表１）にて分かるように、本実施形態の構成では面ぶれの最大幅が略１１μｍであって、面ぶれのばらつきの３σが３μｍ程度となる好結果を得られた。
【００７２】
本実施形態の安定化ガイド部材８は、装置本体ケースに設置しても、カートリッジ内に内設しても、いずれの場合にも前記のような良好な面ぶれ安定化が得られた。
【００７３】
そして、前記構成の本実施形態によるディスクシステムを波長４０５ｎｍ、かつＮＡ０．９の光ピックアップを用いて記録再生を行った。例えば光ディスクにおける記録位置は半径４５ｍｍとし、最短記録ビット長を０．１２μｍ、かつランダムなデジタルデータを１−７ＲＬＬで変調して記録した。
【００７４】
そして、記録線速度は１０ｍ／ｓ，記録ピークパワーは５ｍＷ，消去パワーは２．６ｍＷ，記録ボトムパワーは０．１ｍＷの３値変調，再生は０．２５ｍＷで行ったとき、基本クロックと記録信号との間のジッターは８％未満であった。さらに記録信号のエンベロープの乱れもなく、安定したフォーカスおよびトラッキングが行われていた。記録再生ともフォーカスの残留エラーを測定したが、デフォーカス量は±０．１２μｍ以下になっていた。０．８以上の高いＮＡでは、デフォーカスマージンがきわめて狭く、ＤＶＤなどに比べて数分の１しかなく、デフォーカス量を±０．２μｍ以下にすることが必須である。その意味において本実施形態では十分なフォーカス安定化が行われていたといえる。
【００７５】
また、線速度を２０ｍ／ｓに上げて再生を行ってデフォーカスを評価したが、その量は前記と同様に±０．１２μｍ以下であった。従来の高剛性ディスクでは、線速度を上げると、共振などの作用のために面ぶれが増え、デフォーカス量が増えるのに比べると良い結果が得られた。これは、本実施形態において、空気力安定化を用いているために高線速になるほど安定化させる力が大きくなるからである。
【００７６】
本実施形態において、空気力安定化を効果的に得るためには各部材における動作タイミングを考慮する必要がある。本実施形態における記録／再生時の動作を図６に示すフローチャートを参照して説明する。
【００７７】
すなわち、図示しない中央演算処理回路にスタート信号が入力することによって、スピンドルモータ４が始動して光ディスク１を回転させ（Ｓ１）、所定の回転数に達したときに（Ｓ２のＹＥＳ）、安定化ガイド部材８を光ディスク１に対する所定の接近位置まで移動させる（Ｓ３）。ここでレーザ変位計などを用いて面ぶれの測定を行って所定の面ぶれ安定範囲に入ったときに（Ｓ４のＹＥＳ）、光ピックアップ６を光ディスク１に対する所定の接近位置まで移動させ（Ｓ５）、この時点で記録／再生を開始する（Ｓ６）。
【００７８】
そして、安定化ガイド部材８を安定化ガイド用位置決め機構９により、また光ピックアップ６をピックアップ用位置決め機構７により連動して、光ピックアップ６と安定化ガイド部材８とが互いに対向するように光ディスク１の半径方向に移動させ（Ｓ７）、全信号の記録／再生が終了するまで継続する（Ｓ８）。
【００７９】
安定化ガイド部材８の形状としては、前記形状のものが基本的なものであるが、図７に示す安定化ガイド部材２５のように形成することによって、より面ぶれを安定化させることができた。図７に示す安定化ガイド部材２５において、光ディスク１が進入する側を凸形状をなす正圧発生部２５ａとし、この正圧発生部２５ａにより突入する空気によって圧縮されて大気圧に比して圧力が高まるため、安定化ガイド部材２５と光ディスク１の間に反発力が生じる。また、安定化ガイド部材２５の光ディスク１が排出する側を凹形状をなす負圧発生部２５ｂとし、この負圧発生部２５ｂにより流れる空気が急激に膨張して大気圧に比して負圧となるため、安定化ガイド部材２５と光ディスク１の間に吸着力が働くようになる。
【００８０】
このように安定化ガイド部材２５と光ディスク１との間におけるベルヌーイの法則による空気圧の差により生じる吸着力と反発力のバランスのみで光ディスク１の面ぶれを安定化させることができることになる。
【００８１】
さらに、安定化ガイド部材２５における正圧発生部２５ａと負圧発生部２５ｂとの境目（ガイド面曲率境界線）に平坦部２５ｃを設けることにより、面ぶれ安定領域の広がりを大きく取れるようにしている。このように安定化ガイド部材２５において、反発力と吸着力との両方を発生させて、これらの作用力によって光ディスク１と安定化ガイド部材２５との距離を安定化させることができる。
【００８２】
なお、安定化ガイド部材８（２５）は、図８に示すように、光ディスク１に対向させて周方向に複数箇所に設置することによって、光ディスク１あるいは装置の設計，仕様に適応した光ディスク１の安定状態を適宜設定することが考えられる。
【００８３】
本実施形態では、空気力によって面ぶれあるいはチルトを補正することから、必然的に光ディスク１は柔らかく可撓性を有していなければならない。その結果として、安定化ガイド部材で安定化していない領域では、光ディスク１には、ＣＤなどの通常のディスク材料のものに比べて大きな面ぶれが生じ、０．５ｍｍ程度までの面ぶれは容易に発生する。この面ぶれを、光ピックアップ６周辺の安定化ガイド部材で一気に５μｍ以下に収束することは場合によっては困難である。
【００８４】
そこで本実施形態では、図８〜図１０に示すように、安定化ガイド部材８を、光ディスク１の周方向で、かつ光ピックアップ６の周辺から離した位置にも複数個設置することにより、光ディスク１全体を粗安定化し、主安定面（光ピックアップ６付近）で更なる安定化を図るようにすることにより、装置システム設計のマージンを向上することができた。
【００８５】
図８に示すように、光ピックアップ６に対向設置される安定化ガイド部材８を主安定化ガイド部材８ａとし、光ピックアップ６から離れて設置された安定化ガイド部材８を副安定化ガイド部材８ｂとすると、粗安定化のために設置される副安定化ガイド部材８ｂは、安定化作用においてはそれほどの精密さがある必要はない。０．５ｍｍほどに達する大きな面ぶれを取ればよいので、形状も主として反発力を発生させればよく、単純な球面状の凸形状の作用で十分である。むしろ摺動を発生させない設置構成にすることが必要である。これは、摺動で不要な振動を引き起こさないほうが好ましいからである。このため、粗安定化のための補助ガイドとしての副安定化ガイド部材８ｂは、光ピックアップ６近傍の主ガイドとしての主安定化ガイド部材８ａよりも形状の大きい方が、浮上量が大きくなって好ましい。すなわち、ガイド形状の大きい方（高い，大面積）が浮上量は大きくなる傾向にあるからである。
【００８６】
例えば、図９に示すように、主ガイドとしての主安定化ガイド部材８ａを直径Ｄ₁（＝約１０ｍｍ）の円柱状のものとし、補助ガイドとしての副安定化ガイド部材８ｂの直径Ｄ₂を主安定化ガイド部材８ａよりも大きい直径２０ｍｍの円柱とすれば、浮上量は補助ガイドのほうが大きくなる。あるいは、図１０に示すように、光ディスク１の設置基準面（図１に示すスピンドルモータ４のスピンドルシャフト２と光ディスク１のハブ３とにおけるチャッキング位置の水平延長線）と両安定化ガイド部材８ａ，８ｂ間の距離Ｌ₁，Ｌ₂を、主安定化ガイド部材８ａの距離Ｌ１よりも副安定化ガイド部材８ｂの距離Ｌ２の方を長くすることによって、浮上量は補助ガイドの方が大きくなる。このようにしたことによって、副安定化ガイド部材８ｂにおけるディスク摺動の発生の頻度を小さくすることができる。
【００８７】
また、安定化ガイド部材８の形状が、円柱であり、かつ先端が半球形状をしている場合、光ディスク１に平行な断面部位における面積と浮上量とは比例関係がある。そのため前記補助ガイドが大きければ浮上量は大きいところで安定することになる。
【００８８】
図１に示す第１実施形態では、安定化ガイド部材８および安定化ガイド用位置決め機構９を装置本体１０内における上部に設置している。したがって、使用者は、光ディスク１をカートリッジなしの裸の状態で取り扱うことができる。
【００８９】
この場合、光ディスク１は薄いシート１枚であるため、例えば袋に入れて取り扱い、使用するときに取り出して、スピンドルシャフト２にセットして使うようにすることにより、安価な光学的情報記録媒体とすることができる。
【００９０】
図１１は本発明の第２実施形態を説明するための光学的情報記録／再生装置の概略構成図であり、第２実施形態が第１実施形態と異なる構成は、１枚の光ディスク１を開口窓２６，２６を設けたディスクカートリッジ２７に内蔵し、このディスクカートリッジ２７を装置内の所定の位置にセットし、図示しない操作手段によってシャッタ２８，２８を移動させ、開放された開口窓２６，２６に安定化ガイド部材８と光ピックアップ６を挿入するように移動して、記録／再生が可能な状態にするようにした点である。
【００９１】
ディスクカートリッジ２７としては、一般的な構成のものを採用することができるため、コストアップを伴うことはない。
【００９２】
図１２は本発明の第３実施形態を説明するための光学的情報記録／再生装置の概略構成図であり、第３実施形態では、安定化ガイド部材３０をディスクカートリッジ３１の内部に設置したものである。この場合、安定化ガイド部材３０は、図１３に示すように、光ディスク１における径方向に延在させる横長形状であって、第１，第２実施形態のような安定化ガイド用位置決め機構９を不要にしている。この安定化ガイド部材３０の作用によって光ディスク１の面ぶれ安定化が第１実施形態にて説明したと同様に生じるようになっており、安定化ガイド部材３０によって、最も光ディスク１の面ぶれを安定化することができる領域が、光ピックアップ６の集光点に位置するように安定化ガイド部材３０が設置されている。
【００９３】
第３実施形態においても、図示しない操作手段によってシャッタ２８を移動させ、開放された開口窓２６に光ピックアップ６を挿入するように移動して、記録／再生が可能な状態にする。
【００９４】
第３実施形態では、安定化ガイド部材３０がディスクカートリッジ３１に内蔵されるために、装置の全体構成としては剛体基板の光ディスクを用いる従来の装置の構成と略同一にすることができるため、このような剛体基板を用いる光ディスクのシステムとの互換性を取ることが容易になる。
【００９５】
図１４は本発明に係るディスクカートリッジの実施形態を説明するための平面図、図１５は図１４におけるＡ−Ａ線一部断面図であり、第１実施形態の光学的記録／再生装置と同様な装置に使用することが可能なディスクカートリッジである。
【００９６】
図１４，図１５に示すように、ディスクカートリッジ３３内には可撓性を有するシート状の光ディスク１が複数枚収納することができ、チェンジャーとして使用することができる構成になっており、収納されている光ディスク１の枚数分、容量を増やすことができる。多数の光ディスク１をディスクカートリッジ３３に収納しても、光ディスク１の肉厚が薄いため、ディスクカートリッジ３３の全体体積が大きくならない。
【００９７】
本実施形態のディスクカートリッジ３３は、各光ディスク１の一端部を、光ディスク１を支えるディスクトレイ３４に挟んで、重ねた状態で収納する構成になっており、光ディスク１と共にディスクトレイ３４を記録／再生装置と、このディスクカートリッジ３３間において出し入れすることによってチェンジャー動作を行う。
【００９８】
ディスクトレイ３４には１枚ごとに異なる位置にディスクトレイ識別部３５が突設されており、この異なる位置を検知して出し入れするチェンジャー機構（図示せず）を記録／再生装置側に設置することによって、光ディスクを１枚ごとに区別して出し入れすることを可能にしている。
【００９９】
本実施形態では、光ディスク１が薄いためディスク間隔が狭い。このため、記録／再生装置のチェンジャー機構が上下の異なる光ディスク１を区別することができるように、各ディスクトレイ３４において、図１４に示すように、横方向に異なる位置にディスクトレイ識別部３５を設置してある。記録／再生装置側は、この横方向に異なる位置にあるディスクトレイ識別部３５を、例えば図示しないアーム部材をディスクトレイ識別部３５に形成した孔３５ａに引っ掛けるようにし、そのアーム部材を移動させることによって、光ディスク１をディスクカートリッジ３３に対して出し入れすることができる。ディスクトレイ識別部３５を上下に設置する構成に比べて、本実施形態のような構成では、横方向における距離が比較的広いために、識別が容易に行えることになる。
【０１００】
このように、図１４，図１５に示すディスクカートリッジ３３は、単にディスクトレイ３４を重ねた構造であるため、きわめて簡便な構造となり、しかも小型で大容量なカートリッジとすることができる。
【０１０１】
なお、前記実施形態の説明では相変化記録層を用いた書換型の光ディスクについて説明したが、本発明は、可撓性を有する光ディスクのガイド安定化における、さらなる高精度化のためのガイド形状と、その記録／再生システムへの応用が可能であるため、エンボスピットを用いる再生型光ディスク、あるいは光磁気型の記録ディスクなどの光を集光して記録再生する他の光ディスクにおいても同様な効果を見込むことができる。
【０１０２】
また、安定化ガイド部材については、各種形状，構造のものを採用することができ、例えば図１６〜図２１に示すものを例示することができる。図１６（ａ），（ｂ）に示す安定化ガイド部材４０，４１は図７にて説明した構成のものであって、凸形状の第１ガイド面４０ａ，４１ａと、凹形状の第２ガイド面４０ｂ，４１ｂと、平坦面４０ｃ，４１ｃとから表面形成されており、図１６（ａ）の安定化ガイド部材４０は光ピックアップの移動動線に沿って光ディスクの径方向に配設されるものであり、図１６（ｂ）の安定化ガイド部材４１は光ピックアップの移動動線に沿って光ディスクの径方向に移動可能に設置されるものである。
【０１０３】
なお、図１６（ａ），（ｂ）に示す安定化ガイド部材４０，４１において、平坦面４０ｃ，４１ｃをなくして、第１ガイド面４０ａ，４１ａと第２ガイド面４０ｂ，４１ｂのみを形成したものであってもよい。
【０１０４】
図１７，図１８に示す安定化ガイド部材４２，４３は、ディスク回転方向の上流側から順に、凸形状の第１ガイド面４２ａ，４３ａと、平坦面４２ｃ，４３ｃと、凸形状の第２ガイド面４２ｂ，４３ｂとから表面形成されており、図１８（ａ）の安定化ガイド部材４２は光ピックアップの移動動線に沿って光ディスクの径方向に配設されるものであり、図１８（ｂ）の安定化ガイド部材４３は光ピックアップの移動動線に沿って光ディスクの径方向に移動可能に設置されるものである。
【０１０５】
なお、図１８（ａ），（ｂ）に示す安定化ガイド部材４２，４３において、平坦面４２ｃ，４３ｃをなくして、第１ガイド面４２ａ，４３ａと第２ガイド面４２ｂ，４３ｂのみを形成したものであってもよく、また、第２ガイド面４２ｂ，４３ｂをなくして、第１ガイド面４２ａ，４３ａと平坦面４２ｃ，４３ｃのみを形成したものであってもよい。
【０１０６】
図１９，図２０に示す安定化ガイド部材４４は、ディスク回転方向の上流側から順に、凸形状で、かつディスク回転方向と直交する方向の面が曲面をなす第１ガイド面４４ａと、ディスク回転方向と直交する方向の側部が曲面をなす平坦面４４ｃと、凸形状で、かつディスク回転方向と直交する方向の面が曲面をなす第２ガイド面４４ｂを表面形成している。この安定化ガイド部材４４は光ピックアップの移動動線に沿って光ディスクの径方向に移動可能に設置されるものである。
【０１０７】
なお、図１９，図２０に示す安定化ガイド部材４４において、平坦面４４ｃをなくして、第１ガイド面４４ａと第２ガイド面４４ｂのみを形成したものであってもよく、また、第２ガイド面４４ｂをなくして、第１ガイド面４４ａと平坦面４４ｃのみを形成したものであってもよい。
【０１０８】
図２１に示す安定化ガイド部材４５は、基本的に円柱状のものであって、図４に示す安定化ガイド部材８と同様に、光ディスク１に対向する端面に曲面４５ａを表面形成したものである。
【０１０９】
このように、前記各実施形態によれば、可撓性のある光ディスクを安定化ガイド部材の対向位置で回転させたとき、安定化ガイド部材が光ディスクに対して回転方向の上流側で正圧を発生させることにより、その部位において光ディスクと安定化ガイド部材には反発力が働き、ある距離を持って光ディスクが安定化ガイド部材に対して浮上する。さらに回転方向の下流側において安定化ガイド部材の形状を変えて負圧を発生させることで、その部位において光ディスクは安定化ガイド部材側への吸引力を受ける。ただし、光ディスクは、ある程度の剛性を持つため、直ちに安定化ガイド部材に対して当接して摺動することはない。
【０１１０】
このように、光ディスクは、１個の安定化ガイド部材から反発する空気力を受けた後に、前記空気力とは反対向きの吸引される力を受けることにより、光ディスクと安定化ガイド部材とは、ある一定距離を保ち、かつこの距離が安定しながら光ディスクが回転することになる。したがって、この安定領域に対して記録／再生光を集光することによって、光ディスクにおける面ぶれ，チルトが小さい領域に対して記録再生できることになる。
【０１１１】
前記安定化のために空気力を用いていること、そして光ディスクを構成する基板を低剛性にしたことから、光ディスク自体を高精度に作成する必要はなく、また、大きな面ぶれをなくすことができることから、記録／再生用の光ピックアップの構成は大きな面ぶれに追従しなくてよくなり、したがって、デフォーカスが減少し、高密度の記録／再生を安定して行うことが可能になる。
【０１１２】
さらに、このことから、光ピックアップを構成する対物レンズのアクチュエータとしては、低周波数帯域の大きな振幅に対応しない代わりに、アクチュエータ支持用の弾性部材（ばね）として高剛性のものを採用することにより、高域共振が高い周波数側に存在する特性の光ピックアップを構成することができる。このため、サーボ系の動作を高速化することができ、より高線速でもデフォーカス分を抑圧することができることになる。
【０１１３】
また光ディスクにおいて面ぶれを安定化させた部位よりも、ディスク回転方向上流側および下流側の任意の位置に、ベルヌーイの定理による空気力を作用させない領域を存在させることによって、面ぶれがより効果的に抑圧されることになる。この理由は、可撓性を有する光ディスクを、安定化ガイド部材により変形させて強制的に光の集光点に、光ディスクの安定化領域を生成させることになるため、その安定化領域の前後位置に光ディスクに「逃げ」となる部分を設けた方が、安定化領域での光ディスクの反発力を小さくすることができ、空気力の安定化力の効果が増大するからである。
【０１１４】
従来の可撓性を有するディスクの全面に対して平板ガイド部材を対向設置させる構成は、ディスク全面に対応させて安定化面を存在させるものであり、ディスクより大きな平板を設置するものであった。したがって、この構成を光ディスクを用いる記録／再生装置に適用すると、面ぶれを安定化させたい部位である光ピックアップの集光点以外の周辺においても光ディスクの面ぶれが安定化することになる。このため、光ディスクにうねりがある場合には、前記集光点付近を安定化させたくても、そのディスク回転方向の前後（上流下流）の位置からの曲げの力が強く作用し、面ぶれの安定化作用が不十分となる可能性がある。
【０１１５】
また、光ディスクとして可撓性のある基板に記録層を成膜する構成のものでは、その基板は成膜面に対して逆側に反りやすい。したがって、本実施形態のように、光ディスクの基板側において安定化ガイド部材にて空気力によるガイドを行うことによって、基板自体の元に戻る力と、安定化ガイド部材の反発力とによって安定化作用が良好に行えることになる。このことから、本実施形態では、光ディスクの基板側に安定化ガイド部材を配し、記録層側に光ピックアップを配して記録／再生を行う構成にしている。このような構成にしたことによって、万一、光ディスクと光ピックアップとが摺動状態になって、光ディスクに傷が付いたとしても、その傷は記録層側に生じないため、記録／再生エラーの原因にならない。また、このような構成にしたため、記録／再生の光は光ディスクの基板を通らないことになるため、記録／再生特性は傷の影響、および基板の光学特性の影響を受けない。
【０１１６】
また、本実施形態では、光ディスクは柔らかく可撓性を有しているものを使用しているため、安定化ガイド部材で安定化していない領域では、光ディスクには大きな面ぶれが生じやすい。しかし、この面ぶれを、光ピックアップ周辺の安定化ガイド部材で一気に収束することは困難である。このため、本実施形態では安定化ガイド部材を、光ディスクの周方向で、かつ光ピックアップの周辺から離した位置にも複数個設置することにより、光ディスク全体を粗安定化し、主安定面（光ピックアップ付近）で更なる安定化を図るようにしている。このことにより、装置システム設計のマージンを向上することができる。
【０１１７】
なお、前記実施形態では光学的記録／再生装置を例にして説明したが、情報記録単機能の装置、あるいは情報再生単機能の装置など、記録および／または再生のため可撓性を有する光ディスクを使用する装置に適用して同一効果を得ることができる。
【０１１８】
【発明の効果】
以上説明したように、本発明によれば、可撓性を有するシート状の光ディスクにおける情報の書き込み／読み取りが行われる部位における回転軸方向の面ぶれをベルヌーイの法則に基づく空気流の圧力差によって安定化させる安定化手段を備えた装置において、光ディスクの面ぶれを安定化させた部位の前後位置に「逃げ」となる部分を設けたことにより、安定化させた部位における光ディスクの反発力を小さくすることができ、空気力による安定化力の効果が増大するため、安定化させた部位において高密度の書き込みが可能になる。
【０１１９】
また、前記のように可撓性を有するシート状の光ディスクにおける情報の書き込み／読み取りが行われる部位における回転軸方向の振れを空気流の圧力差によって局部的に安定化させる安定化手段を、光ディスクにおける記録面とは反対側に少なくとも１つ存在させて、記録面側における面ぶれを安定化させた部位から書き込み／読み取りを行うので、光ディスクが安定化手段と摺動して傷がつくことを防止することができると共に、万一、光ディスクが安定化手段と摺動して傷がついたとしても、その傷は記録面には付かないためエラーを発生することがなくなり、例えば光ディスクの記録面とは反対側の基板に傷が付いても記録／再生用の光は基板を通らず、よって、基板の傷の影響、および基板の光学特性の影響を受けることがない。したがって、長期にわたって安定した記録／再生を行うことができ、安定化手段を設置したことによる不具合の発生もない。
【０１２０】
また、前記装置に使用される可撓性を有するシート状の光ディスクをカートリッジケース内に収納することによって、薄く曲がりやすい光ディスクであっても、その取り扱いが容易になり、また複数枚の光ディスクを収納して大記録容量のものにすることができ、しかもカートリッジ全体として厚くならない等、実際的な効果が大である。
【図面の簡単な説明】
【図１】本発明の第１実施形態を説明するための光学的情報記録／再生装置の概略構成図
【図２】本発明の実施形態における光ピックアップを構成する記録手段と再生手段の説明図
【図３】本発明の実施形態における光ディスクの一例を示す断面図
【図４】本発明の実施形態における光ディスクの面ぶれ安定化を説明するための説明図
【図５】図４に示す構成例に対して測定した光ディスクの面ぶれの測定結果を示す図
【図６】本発明の実施形態における記録／再生時の動作に係るフローチャート
【図７】第１実施形態における安定化ガイド部材の変形例を示す説明図
【図８】第１実施形態における安定化ガイド部材の配設例の説明図
【図９】第１実施形態における安定化ガイド部材の配設例の他例を示す説明図
【図１０】第１実施形態における安定化ガイド部材の配設例の他例を示す説明図
【図１１】本発明の第２実施形態を説明するための光学的情報記録／再生装置の概略構成図
【図１２】本発明の第３実施形態を説明するための光学的情報記録／再生装置の概略構成図
【図１３】第３実施形態における安定化ガイド部材の配設例の説明図
【図１４】本発明のディスクカートリッジの実施形態を説明するための平面図
【図１５】図１４におけるＡ−Ａ線一部断面図
【図１６】本発明の実施形態における安定化ガイド部材の構成例を示す説明図
【図１７】本発明の実施形態における安定化ガイド部材の構成例を示す説明図
【図１８】本発明の実施形態における安定化ガイド部材の構成例を示す説明図
【図１９】本発明の実施形態における安定化ガイド部材の構成例を示す説明図
【図２０】本発明の実施形態における安定化ガイド部材の構成例を示す説明図
【図２１】本発明の実施形態における安定化ガイド部材の構成例を示す説明図
【符号の説明】
１ 光ディスク
２ スピンドルシャフト
３ ハブ
４ スピンドルモータ
６ 光ピックアップ
７ ピックアップ用位置決め機構
８，２５，３０，４０〜４５ 安定化ガイド部材
８ａ 主安定化ガイド部材
８ｂ 副安定化ガイド部材
９ 安定化ガイド用位置決め機構
１０ 装置本体
１４ レーザ光源
１５ 対物レンズ
１７ 光電変換素子
２０ 光ディスクの記録層
２１ 光ディスクの基板
２５ａ 安定化ガイド部材の正圧発生部
２５ｂ 安定化ガイド部材の負圧発生部
２５ｃ 安定化ガイド部材の平坦部
２７，３３ ディスクカートリッジ
３４ ディスクトレイ
３５ ディスクトレイ識別部[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical disc driving device, an optical information recording device, an optical information reproducing device, and a disc cartridge used in the optical disc driving device for rotationally driving an optical disc which is a flexible sheet-like optical information recording medium. It is about.
[0002]
[Prior art]
In recent years, there has been a demand for optical discs to record large volumes of digital data, such as the start of digitization of television broadcasts. Of the methods for increasing the density of optical discs, the basic method is to reduce the spot diameter of light for recording / reproduction.
[0003]
For this reason, it is effective to shorten the wavelength of light used for recording / reproduction and to increase the numerical aperture NA of the objective lens. As for the wavelength of light, a wavelength of near infrared light of 780 nm is used for CD (compact disk), and a wavelength of 650 nm of red light is used for DVD (digital versatile disk). Recently, a blue-violet semiconductor laser has been developed, and it is expected that a laser beam of around 400 nm will be used in the future.
[0004]
As for the objective lens, it was less than NA0.5 for CD, but it is about NA0.6 for DVD. In the future, it is required to further increase the numerical aperture (NA) to NA or more 0.7. However, increasing the NA of the objective lens and shortening the wavelength of light also increase the influence of aberrations when focusing light. Therefore, the margin for the tilt of the optical disk is reduced. Further, since the depth of focus is reduced by increasing the NA, the focus servo accuracy must be increased.
[0005]
Furthermore, since the distance between the objective lens and the recording surface of the optical disk is reduced by using a high NA objective lens, it is necessary to reduce the surface blur of the optical disk before the focus servo at the start is pulled in. The objective lens and the optical disk may collide, causing a pickup failure.
[0006]
As a short wavelength, high NA large capacity optical disk, for example, as shown on page 183 of O PLUS E (vol. 20 No. 2), a recording film is formed on a substrate that is as thick and rigid as CD. However, a system has been proposed in which recording / reproducing light is recorded / reproduced with respect to the recording film through the thin cover layer without passing through the substrate.
[0007]
Further, as described in, for example, Japanese Patent Application Laid-Open Nos. 7-105657 and 10-308059, a flexible optical disk is rotated on a flat stabilizing plate to cause surface blur in the optical disk. Methods for stabilization are known.
[0008]
[Problems to be solved by the invention]
However, in the conventional technique, when the optical disk substrate is formed of a rigid body, in order to reduce surface deflection and tilt in the rotating optical disk, extremely accurate molding is performed and recording is performed at a low temperature so that thermal deformation does not occur. A film must be deposited. This prolongs the tact time associated with optical disc manufacture and increases costs.
[0009]
Further, in the method of rotating a flexible optical disk on a stabilizing plate, as described in JP-A-10-308059, when rotating on a simple flat plate, the optical disk and the stabilizing plate are in contact with each other. As a result, the optical disk vibrates and high-frequency surface shake occurs. This surface blur often occurs in a frequency region where mechanical focus servo cannot respond, and the residual servo error cannot be sufficiently suppressed.
[0010]
Further, when the optical disk and the objective lens slide due to surface blurring, dust is generated and the dust or the like causes an error. In particular, as described in Japanese Patent Application Laid-Open No. 7-105657, when the recording film is present on the stabilizing plate side, the recording film of the optical disk is damaged by sliding and causes an error directly. .
[0011]
The object of the present invention is to solve the above-mentioned conventional problems, and to reliably suppress the surface shake of the optical disk by aerodynamic force when recording / reproduction is performed using a flexible sheet-like optical disk. To provide an optical disc driving device, an optical information recording device, an optical information reproducing device, and a disc cartridge used therefor, which enable recording and prevent occurrence of problems such as sliding contact with an objective lens. It is in.
[0012]
[Means for Solving the Problems]
In order to achieve the above-mentioned object, the invention according to claim 1 is provided with a rotation driving means for rotating a flexible sheet-like optical disc and a recording surface of the optical disc, and at least writing on the optical disc. Alternatively, the optical disk drive device includes stabilization means for stabilizing the vibration in the direction of the rotation axis at the portion where the reading is performed by the pressure difference of the air flow based on Bernoulli's law, Is provided with an area that does not cause the pressure difference of the air flow between the upstream side and the downstream side in the disk rotation direction of the part where the vibration is stabilized, and this configuration stabilizes the surface blurring in the sheet-like optical disk. By providing a portion that becomes “escape” at the front and back positions of the optical disc, The force can be reduced, the effect of stabilizing force by aerodynamic force is increased, and there is a stabilizing means on the substrate side opposite to the recording surface of the optical disc, and surface blurring on the recording surface side is stabilized. Since recording / reproduction is performed from the part that has been made, even if the optical disk slides with the stabilizing means and is damaged, the error does not occur because the scratch does not attach to the recording surface, Even if the substrate of the optical disk is scratched, the recording / reproducing light does not pass through the substrate, so that it is not affected by the scratch on the substrate and the optical characteristics of the substrate.
[0013]
According to a second aspect of the present invention, in the optical disk drive device according to the first aspect, the stabilizing means is a protruding member that protrudes in the direction of the optical disk. With this configuration, the air flow pressure based on Bernoulli's law is provided. Differences can be generated effectively.
[0014]
According to a third aspect of the present invention, in the optical disk drive device according to the first or second aspect, the stabilizing means generates a positive pressure with respect to the atmospheric pressure upstream in the disk rotation direction, and a large pressure downstream in the disk rotation direction. It is characterized in that a portion that generates a negative pressure with respect to the atmospheric pressure is formed. With this configuration, the optical disk is repelled by the stabilizing means, and then receives a force in the direction opposite to the suction, so that the optical disk becomes the stabilizing means. On the other hand, a certain distance is maintained, and this distance rotates stably.
[0015]
According to a fourth aspect of the present invention, in the optical disk drive device according to the second or third aspect, the flat surface portion for stabilizing the surface blur of the optical disk is formed on the most protruding portion of the protruding surface of the stabilizing means. With this configuration, it is possible to stably set the stable portion of the surface shake in the optical disc.
[0016]
According to a fifth aspect of the present invention, in the optical disk drive device according to the fourth aspect, an arcuate surface portion is formed at least upstream of the flat surface portion of the stabilizing means in the disk rotation direction. The pressure difference of the air flow based on the law can be generated smoothly.
[0017]
The invention according to claim 6 is characterized in that, in the optical disk drive device according to any one of claims 1 to 5, the stabilizing means is scattered in the circumferential direction of the optical disk. The installation position and number of stabilization means are selected and set as appropriate according to the design and specifications of the device.
[0018]
The invention according to claim 7 is characterized in that, in the plurality of stabilizing means in the optical disk drive device according to claim 6, the height is set to be different depending on the installation position. With this configuration, the height of the stabilizing means is increased. Since the air pressure state changes depending on the setting, it is possible to set a favorable air pressure state in order to stabilize the surface blur on the recording surface side over the entire surface of the optical disc.
[0019]
The invention according to claim 8 is characterized in that, in the plurality of stabilizing means in the optical disk drive device according to claim 6 or 7, the cross-sectional area of the part parallel to the optical disk is set differently depending on the installation position. Depending on the configuration, the state of the air pressure changes depending on the setting of the cross-sectional area of the stabilizing means. Therefore, in order to stabilize the surface blurring on the recording surface side over the entire surface of the optical disc, a favorable air pressure state can be set.
[0020]
The invention according to claim 9 is characterized in that, in the optical disk drive device according to any one of claims 1 to 8, the stabilizing means is extended in the radial direction of the optical disk. Depending on the design and specifications of the device, the length and the like of the stabilizing means are appropriately selected and set.
[0021]
According to a tenth aspect of the present invention, in the optical disk drive device according to any one of the first to ninth aspects, the stabilizing means is installed on a part of the constituent members of the optical disk drive device.
[0022]
An eleventh aspect of the present invention is the optical disk drive device according to any one of the first to tenth aspects, wherein a flexible sheet-shaped optical disk can be mounted on a predetermined set portion alone. And
[0023]
According to a twelfth aspect of the present invention, there is provided a rotational driving means for rotating a flexible sheet-like optical disk, an optical writing means for irradiating the recording surface of the optical disk with light, and an optical disk. And a stabilizing means for stabilizing the vibration in the direction of the rotation axis in a portion of the optical disk on which information is written, locally by the pressure difference of the air flow, The writing means and the stabilizing means are arranged so as to face each other through the optical disk, and this configuration stabilizes the surface blurring in the sheet-like optical disk by utilizing the air flow pressure difference. In this case, there is a stabilizing means on the side opposite to the recording surface of the optical disc. Optical disc even scratched slides and stabilizing means, the wound it is unnecessary to generate an error because not attached to the recording surface.
[0024]
According to a thirteenth aspect of the present invention, there is provided a rotation driving means for rotating a flexible sheet-like optical disk, an optical writing means for writing information on a recording surface of the optical disk, and the optical writing means. Stabilizing means installed on the side opposite to the recording surface side of the installed optical disc and stabilizing the vibration in the direction of the rotation axis in the portion of the optical disc where writing is performed by the pressure difference of the air flow based on Bernoulli's law An optical information recording apparatus comprising: an optical disc provided with a region that does not cause a pressure difference in the air flow between the upstream side and the downstream side in the disc rotation direction of the portion of the optical disc that is stabilized by the stabilizing means. With this configuration, the operation and effect of the first aspect of the invention can be achieved, and the state of the portion where writing is performed on the optical disc is stabilized. Inclusive recording density can be enhanced.
[0025]
According to a fourteenth aspect of the present invention, in the optical information recording apparatus according to the twelfth or thirteenth aspect, the stabilizing means is a projecting member that projects in the direction of the optical disc. The same effects as those of the present invention can be obtained.
[0026]
According to a fifteenth aspect of the present invention, in the optical information recording apparatus according to the twelfth, thirteenth or fourteenth aspect, the stabilizing means generates a positive pressure with respect to the atmospheric pressure upstream of the disk rotation direction, and the disk rotation direction. A site for generating a negative pressure with respect to the atmospheric pressure is formed on the downstream side, and this configuration provides the same effects as the invention of the third aspect.
[0027]
According to a sixteenth aspect of the present invention, there is provided the optical information recording apparatus according to the fourteenth or fifteenth aspect, wherein a flat surface portion for stabilizing the surface blur of the optical disk is formed on the most protruding portion of the protruding surface of the stabilizing means. According to this configuration, the same function and effect as those of the fourth aspect of the invention can be achieved.
[0028]
According to a seventeenth aspect of the present invention, in the optical information recording apparatus of the sixteenth aspect, an arcuate surface portion is formed at least upstream of the flat surface portion of the stabilizing means in the disk rotation direction. The same effects as those of the invention of the fifth aspect are achieved.
[0029]
The invention according to claim 18 is the optical information recording apparatus according to any one of claims 13 to 17, wherein the optical writing means and the stabilizing means are arranged so as to face each other through the optical disk. With this configuration, the state of the portion where writing is performed on the optical disc is reliably stabilized, and the writing recording density can be increased.
[0030]
The invention according to claim 19 is characterized in that, in the optical information recording apparatus according to any one of claims 12 to 18, the stabilizing means is scattered in the circumferential direction of the optical disc. The same effects as those of the invention of the sixth aspect are achieved.
[0031]
According to a twentieth aspect of the present invention, in the stabilizing means in the optical information recording apparatus according to the nineteenth aspect, the stabilizing means facing the optical writing means is the main stabilizing means, and other than the main stabilizing means. As a sub-stabilization means, the main stabilization means and the sub-stabilization means are set to have different heights. With this configuration, by setting the height of the main stabilization means and the sub-stabilization means Since the air pressure state changes, it is possible to set a favorable air pressure state at each position of the optical disk in order to stabilize the surface blur on the recording surface side.
[0032]
According to a twenty-first aspect of the present invention, in the optical information recording apparatus of the twentieth aspect, the distance between the sub-stabilizing means and the installation reference plane of the optical disc is greater than the distance between the main stabilization means and the installation reference plane of the optical disc. This is characterized in that it is set longer, and with this configuration, the flying height of the disk at the installation position of the sub-stabilizing means is increased, so that the sliding contact with the optical disk is reduced.
[0033]
The invention according to claim 22 is the stabilizing means in the optical information recording apparatus according to any one of claims 19 to 21, wherein the stabilizing means facing the optical writing means is a main stabilizing means, Other than this main stabilization means is a sub-stabilization means, and the main stabilization means and the sub-stabilization means are set so that the cross-sectional areas of the parts parallel to the optical disc are different. Since the state of the air pressure changes depending on the setting of the cross-sectional areas of the means and the sub-stabilizing means, it is possible to set a favorable air pressure state at each position of the optical disk in order to stabilize the surface blur on the recording surface side.
[0034]
According to a twenty-third aspect of the present invention, in the optical information recording apparatus of the twenty-second aspect, the cross-sectional area of the portion parallel to the optical disc in the sub-stabilizing means is greater than the cross-sectional area of the portion in parallel to the optical disc in the main stabilizing means. This is characterized in that it is set larger, and this configuration increases the flying height of the disk at the position where the sub-stabilizing means is installed, thereby reducing sliding contact with the optical disk.
[0035]
The invention according to claim 24 is the optical information recording apparatus according to any one of claims 12 to 23, characterized in that the stabilizing means extends in the radial direction of the optical disc. The same effect as that attained by the 9th aspect can be attained.
[0036]
According to a twenty-fifth aspect of the present invention, there is provided an optical information recording apparatus according to any one of the twelfth to twenty-fourth aspects, in order to maintain the opposing relationship between the optical writing means and the stabilizing means. A means for moving the stabilizing means in conjunction with the optical writing means in the direction is provided. With this configuration, the state of the portion where writing is performed on the optical disk is reliably stabilized over the entire area of the optical disk.
[0037]
According to a twenty-sixth aspect of the present invention, in the optical information recording apparatus according to any one of the twelfth to twenty-fifth aspects, the stabilizing means is installed in a part of the constituent members in the apparatus main body.
[0038]
According to a twenty-seventh aspect of the present invention, in the optical information recording apparatus according to any one of the twelfth to twenty-sixth aspects, a flexible sheet-like optical disk can be mounted on a predetermined set portion alone. It is characterized by.
[0039]
The invention according to claim 28 is a rotary drive means for rotating a flexible sheet-like optical disk, an optical reading means for reading information by irradiating the recording surface of the optical disk, and an optical disk Stabilizing means that is installed on the side opposite to the recording surface side and locally stabilizes the vibration in the direction of the rotation axis at the part of the optical disk from which information is read, by the pressure difference of the air flow, and the optical reading Means and the stabilizing means are arranged so as to face each other through the optical disc, and this configuration stabilizes the surface blurring in the sheet-like optical disc using the pressure difference of the air flow. A portion can be provided, information is read stably at this portion, and there is a stabilizing means on the side opposite to the recording surface of the optical disc. Optical disc even scratched slides and stabilizing means, the wound it is unnecessary to generate an error because not attached to the recording surface.
[0040]
According to a twenty-ninth aspect of the present invention, there is provided a rotation driving means for rotating a flexible sheet-like optical disk, an optical reading means for reading information recorded on a recording surface of the optical disk, and the optical reading means. Stabilization means installed on the side opposite to the recording surface of the optical disc installed to stabilize the vibration in the direction of the rotation axis at the portion of the optical disc to be read by the pressure difference of the air flow based on Bernoulli's law An optical information reproducing apparatus comprising: an optical disc provided with a region that does not cause a pressure difference in the air flow between the upstream side and the downstream side in the disc rotation direction of a portion of the optical disc that is stabilized by the stabilizing means. With this configuration, the operational effect of the first aspect of the invention can be achieved, and the state of the portion where the reading is performed on the optical disc is low. And, even in a state of high density recording can be performed satisfactorily read.
[0041]
A thirty-third aspect of the present invention is the optical information reproducing apparatus according to the twenty-eighth or the twenty-ninth aspect, wherein the stabilizing means is a projecting member that projects in the direction of the optical disc. The same effects as those of the present invention can be achieved.
[0042]
According to a thirty-first aspect of the present invention, in the optical information reproducing apparatus according to the twenty-eighth, twenty-ninth or thirty-third aspect, the stabilizing means generates a positive pressure with respect to the atmospheric pressure upstream of the disk rotation direction, A site for generating a negative pressure with respect to the atmospheric pressure is formed on the downstream side. With this configuration, the same effect as that of the invention of the third aspect can be achieved.
[0043]
According to a thirty-second aspect of the present invention, in the optical information reproducing apparatus according to the thirty-third or thirty-first aspect, a flat surface portion for stabilizing the surface blur of the optical disk is formed on the most protruding portion of the protruding surface of the stabilizing means. With this configuration, the same function and effect as that of the invention of the fourth aspect can be achieved.
[0044]
According to a thirty-third aspect of the present invention, in the optical information reproducing apparatus according to the thirty-second aspect, an arcuate surface portion is formed at least upstream of the flat surface portion of the stabilizing means in the disk rotation direction. The same effects as those of the invention of the fifth aspect can be achieved.
[0045]
The invention according to claim 34 is the optical information reproducing apparatus according to any one of claims 29 to 33, wherein the optical reading means and the stabilizing means are disposed so as to face each other through the optical disk. With this configuration, the state of the portion where reading is performed on the optical disc is reliably stabilized, and good reading can be performed even in a high recording density state.
[0046]
The invention according to claim 35 is characterized in that, in the optical information reproducing apparatus according to any one of claims 28 to 34, the stabilizing means is scattered in the circumferential direction of the optical disc. The same effects as those of the invention of the sixth aspect can be achieved.
[0047]
According to a thirty-sixth aspect of the present invention, in the stabilizing means of the optical information reproducing apparatus according to the thirty-fifth aspect, the stabilizing means facing the optical reading means is the main stabilizing means, and other than the main stabilizing means is the sub-stabilizing means. The stabilization means is characterized in that the main stabilization means and the sub-stabilization means are set so as to have different heights. With this configuration, the same effect as that of the invention of claim 20 can be obtained.
[0048]
The invention according to claim 37 is the optical information reproducing apparatus according to claim 36, wherein the distance between the sub-stabilizing means and the installation reference plane of the optical disc is greater than the distance between the main stabilization means and the installation reference plane of the optical disc. This is characterized in that it is set longer, and with this configuration, the same effect as that of the 21st aspect of the invention can be achieved.
[0049]
The invention as set forth in claim 38 is the stabilizing means in the optical information reproducing apparatus according to any one of claims 35 to 37, wherein the stabilizing means facing the optical reading means is the main stabilizing means. The sub-stabilization means other than the stabilization means is set such that the cross-sectional areas of the parts parallel to the optical disc in the main stabilization means and the sub-stabilization means are different, and according to this configuration, the structure according to claim 22 is provided. The same effects as those of the present invention are achieved.
[0050]
The invention according to claim 39 is the optical information reproducing apparatus according to claim 38, wherein the cross section of the portion parallel to the optical disc in the sub-stabilization means is larger than the cross sectional area of the portion in parallel to the optical disc in the main stabilization means. The area is set to be larger, and this configuration provides the same effects as the invention of the twenty-third aspect.
[0051]
The invention according to claim 40 is characterized in that, in the optical information reproducing apparatus according to any one of claims 28 to 39, the stabilizing means extends in the radial direction of the optical disc. The same effects as those of the ninth aspect of the invention can be achieved.
[0052]
The invention according to claim 41 is the optical information reproducing apparatus according to any one of claims 28 to 40, in order to maintain the opposing relationship between the optical reading means and the stabilizing means, in the radial direction of the optical disk. Further, it is provided with means for moving the stabilizing means in conjunction with the optical reading means. With this configuration, the state of the portion where reading is performed on the optical disk is reliably stabilized over the entire area of the optical disk.
[0053]
The invention according to claim 42 is the optical information reproducing apparatus according to any one of claims 28 to 41, characterized in that the stabilizing means is installed in a part of the constituent members in the apparatus main body.
[0054]
The invention according to claim 43 is the optical information reproducing apparatus according to any one of claims 28 to 42, wherein a flexible sheet-like optical disk can be mounted on a predetermined set part alone. It is characterized by.
[0055]
The invention according to claim 44 is the optical disk drive device according to any one of claims 1 to 10, the optical information recording device according to any one of claims 12 to 26, or 43. At least one optical disk used in the optical information reproducing apparatus according to any one of claims 28 to 42 is accommodated. With this configuration, a flexible sheet-shaped optical disk is placed in the cartridge case. Since it is housed, even an optical disk that is thin and easily bent can be handled easily, and a plurality of optical disks can be housed to have a large recording capacity, and the entire cartridge does not become thick.
[0056]
The invention according to claim 45 is the disk cartridge according to claim 44, wherein the cartridge case, the optical disk drive device according to any one of claims 1 to 9, or any one of claims 12 to 25. The optical information recording apparatus according to any one of claims 28 to 41 or the optical information reproducing apparatus according to any one of claims 28 to 41 is provided with a stabilizing means. It can be simplified.
[0057]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.
[0058]
FIG. 1 is a schematic configuration diagram of an optical information recording / reproducing apparatus for explaining a first embodiment of the present invention. 1 is a flexible sheet-like optical disk, 2 is a hub 3 of the optical disk 1 4 is a spindle motor that rotationally drives the spindle shaft 2, 6 is a recording means for writing information to the optical disc 1, and an optical pickup as a reproducing means for reading the written information, 7 A pickup positioning mechanism 8 for moving the optical pickup 6 in the radial direction of the optical disk 1 is placed opposite to the optical pickup 6 via the optical disk 1 and a stabilizing guide member 9 for preventing the optical disk 1 from shaking. Stabilizing guide positioning device for moving the stabilizing guide member 8 in the radial direction of the optical disc 1 in conjunction with the optical pickup 6 , 10 is a device body that houses the respective components.
[0059]
FIG. 2 is an explanatory diagram of recording means and reproducing means constituting the optical pickup. As shown in FIG. 2A, the recording means performs digital signal processing and signal compression on the input recording signal. A signal processing circuit 11 that performs processing, a laser drive control circuit 12 that generates a laser drive control signal based on an output from the signal processing circuit 11, and a semiconductor laser that receives an output from the laser drive control circuit 12 The laser drive unit 13 that drives the laser light source 14, and the like, the emitted light La of high emission energy emitted from the laser light source 14 is condensed by the objective lens 15 of the optical pickup 6 shown in FIG. The recording surface is irradiated as a light spot, and information recording by bit formation is performed.
[0060]
Further, as shown in FIG. 2B, the reproducing means includes a photoelectric conversion element 17 such as a photodiode, a reproduction signal processing circuit 18 and the like, and with respect to a recording bit formed on the recording surface of the optical disc 1. Then, a laser beam with low emission energy is emitted from the laser light source 14, the reflected light Lb is received by the photoelectric conversion element 17 through the objective lens 15, and the signal is expanded by the reproduction signal processing circuit 18 to the output from the photoelectric conversion element 17. A reproduction signal is generated by performing processing or the like.
[0061]
The optical disc 1 is configured as shown in the cross-sectional view of FIG. 3, and the spindle shaft 2 so that the recording layer 20 faces the objective lens 15 of the optical pickup 6 and the substrate 21 faces the stabilization guide member 8. Is set in the chucking section provided in.
[0062]
A specific example of the optical disc 1 in the present embodiment will be described. In order to give flexibility as a substrate, a thin sheet of about 0.1 mm was used. For example, a groove having a stamper pitch of 0.6 μm and a width of 0.3 μm is transferred by thermal transfer onto a 80 μm thick sheet made of polyethylene terephthalate, and then the sheet / Ag reflective layer is formed by sputtering to 120 nm / (ZrO ₂ -Y ₂ O _Three ) -SiO ₂ , 7 nm / AgInSbTeGe, 10 nm / ZnS—SiO ₂ , 25nm / Si _Three N _Four The films were formed in the order of. This sheet is spin-coated with UV resin, cured by ultraviolet irradiation to form a transparent protective film having a thickness of 5 μm, and the recording layer is melt-crystallized with a large-diameter laser beam to reflect the reflectivity. The one with increased
[0063]
With reference to the explanatory diagram of FIG. 4, stabilization of surface deflection of a flexible sheet-like optical disc in the present embodiment will be described. During recording / reproduction, the flexible optical disk 1 having the above-described configuration is rotated between the optical pickup 6 and the stabilizing guide member 8. The rotating optical disk 1 itself is small but rigid, and when it rotates, it has a force to turn straight due to the action of centrifugal force. Therefore, by bringing the stabilization guide member 8 close to the optical disc 1 and generating a repulsive force due to the pressure difference of the air flow based on Bernoulli's law and applying it to the optical disc 1, the force that makes the optical disc 1 straight Due to the balance of the repulsive force from the stabilizing guide member 8, the large runout (running in the disc rotation axis direction) can be reduced.
[0064]
In the present embodiment, the stabilizing guide member 8 is not placed opposite to the entire surface of the recording layer 20 of the optical disc 1. For example, in the configuration example of FIG. 4, a columnar stabilization guide member 8 whose surface facing the optical disc 1 forms an arc shape is used, and surface blurring due to the action of air pressure by the stabilization guide member 8 in the optical disc 1 is stable. Before and after the portion A where the surface vibration is stabilized by providing regions (space portions where the stabilizing guide member 8 is not provided) B and C where the air pressure action is not generated on the upstream side and the downstream side in the disk rotation direction By making the optical disc 1 a portion that becomes “escape” at a position, the repulsive force of the optical disc 1 at the portion A where the surface blur is stabilized is reduced. By doing in this way, the effect of the stabilization force by an aerodynamic force will increase.
[0065]
Further, the stabilizing guide member 8 is present on the substrate 21 side opposite to the recording layer 20 in the optical disc 1, and the recording / reproducing lights La and Lb are condensed on the recording layer 20 of the optical disc 1. Perform recording / playback. The stabilization guide member 8 stabilizes the substrate 21 side opposite to the recording layer 20. Therefore, even if a sliding state occurs between the stabilizing guide member 8 and the optical disc 1, the recording layer 20 is not damaged and does not directly cause an error. Further, the optical disc 1 usually warps in a convex shape on the recording layer 20 side. This corresponds to the fact that the sputtered film in the recording layer 20 has a compressive stress. For this reason, when the stabilization guide member 8 is applied so as to be pushed from the substrate 21 side, the pressure-bonding force between the stabilization guide member 8 and the optical disc 1 becomes more stable, and the compression against the surface shake becomes better.
[0066]
In addition, since the recording / reproducing lights La and Lb directly enter and exit the opposite side of the portion A where the surface blurring on the recording layer 20 side of the optical disc 1 is stabilized, the optical disc 1 is stabilized by any chance. Even if the guide member 8 slides and gets scratched, the scratch is not attached to the recording layer 20, so that a recording / reproducing error does not occur, and the substrate 21 of the optical disk 1 is scratched. However, since the recording / reproducing lights La and Lb do not pass through the substrate 21, they are not affected by the scratches on the substrate 21 and the optical characteristics of the substrate 21. For example, the substrate 21 may be opaque. Good.
[0067]
This will be described more specifically with reference to the explanatory diagram of FIG. In FIG. 4, when the component member other than the stabilizing guide member 8 or the apparatus main body case or the optical disk 1 is used in a state of being stored in the cartridge, the optical disk is removed from the cartridge so that the action according to Bernoulli's law does not work. Assume that 1 is separated by about 1 mm or more. However, when the objective lens 15 is exceptionally high NA, the working distance is shortened, so that the objective lens 15 approaches 0.05 mm to 0.3 mm.
[0068]
Further, FIG. 5 shows an actual measurement diagram (for two rotations) of the measurement result of the surface deflection of the optical disk in the configuration of FIG. The stabilizing guide member 8 has a tip shape of a radius of 50 mm and a diameter of 20 mm, and the optical disk 1 is formed by forming a groove for tracking with a pitch of 0.65 μm on an 80 μm PET (polyethylene terephthalate) sheet and forming a recording film by sputtering. The diameter was 45 mm, the rotation speed was 2000 rpm, and surface deflection was measured using a laser displacement meter. The set interval between the stabilizing guide member 8 and the optical disc 1 is about 5 μm.
Since there was no abnormal vibration in the stabilizing guide member 8 and no sliding flaw occurred in the optical disc 1, it can be determined that excessive air levitation did not occur and no sliding state occurred. Further, the disc surface runout is about 3 μm, and it can be seen that a normal rigid disc produces surface runout of 50 μm or more, which is extremely small.
[0069]
Further, (Table 1) is a table summarizing the results obtained by measuring the surface shake state by rotating 10 times in the same manner as the measurement method described with reference to FIG. 5, and a stabilizing guide member is provided on one side of the optical disc as in this embodiment. The installed configuration was compared with the conventional configuration in which the guide member was installed on the entire surface of the optical disc.
[0070]
[Table 1]

[0071]
As can be seen from (Table 1), in the configuration of the present embodiment, the maximum width of the runout is about 11 μm, and the 3σ of the runout variation is about 3 μm.
[0072]
Whether the stabilization guide member 8 of the present embodiment is installed in the apparatus main body case or in the cartridge, the above-described good surface stabilization is obtained.
[0073]
The disk system according to the present embodiment having the above configuration was recorded and reproduced using an optical pickup having a wavelength of 405 nm and NA of 0.9. For example, the recording position on the optical disk was set to a radius of 45 mm, the shortest recording bit length was 0.12 μm, and random digital data was modulated and recorded with 1-7 RLL.
[0074]
When the recording linear velocity is 10 m / s, the recording peak power is 5 mW, the erasing power is 2.6 mW, the recording bottom power is ternary modulation of 0.1 mW, and the reproduction is performed at 0.25 mW, the basic clock and the recording signal The jitter between and was less than 8%. Further, stable focusing and tracking were performed without any disturbance of the envelope of the recording signal. The focus residual error was measured for both recording and reproduction, but the defocus amount was ± 0.12 μm or less. With a high NA of 0.8 or more, the defocus margin is very narrow, it is only a fraction of that of a DVD or the like, and the defocus amount must be ± 0.2 μm or less. In this sense, it can be said that sufficient focus stabilization has been performed in this embodiment.
[0075]
In addition, the defocus was evaluated by increasing the linear velocity to 20 m / s and evaluating the defocus, but the amount was ± 0.12 μm or less as described above. With the conventional high-rigidity disk, when the linear velocity is increased, the surface shake increases due to the action of resonance and the like, and a better result is obtained than when the defocus amount increases. This is because in this embodiment, since aerodynamic stabilization is used, the force for stabilization increases as the linear velocity increases.
[0076]
In this embodiment, it is necessary to consider the operation timing of each member in order to effectively stabilize the aerodynamic force. The operation at the time of recording / reproducing in this embodiment will be described with reference to the flowchart shown in FIG.
[0077]
That is, when a start signal is input to a central processing circuit (not shown), the spindle motor 4 is started to rotate the optical disc 1 (S1), and when a predetermined number of rotations is reached (YES in S2), stabilization is performed. The guide member 8 is moved to a predetermined approach position with respect to the optical disc 1 (S3). Here, when the surface shake is measured using a laser displacement meter or the like and enters the predetermined surface shake stable range (YES in S4), the optical pickup 6 is moved to a predetermined approach position with respect to the optical disc 1 (S5). At this point, recording / reproduction is started (S6).
[0078]
Then, the stabilization guide member 8 is linked by the stabilization guide positioning mechanism 9 and the optical pickup 6 is linked by the pickup positioning mechanism 7 so that the optical pickup 6 and the stabilization guide member 8 face each other. (S7) and continues until recording / reproduction of all signals is completed (S8).
[0079]
The shape of the stabilizing guide member 8 is basically the shape described above, but by forming it like the stabilizing guide member 25 shown in FIG. It was. In the stabilization guide member 25 shown in FIG. 7, the side on which the optical disc 1 enters is a positive pressure generating portion 25a having a convex shape, and is compressed by the air entering the positive pressure generating portion 25a and is compressed in comparison with the atmospheric pressure. Therefore, a repulsive force is generated between the stabilizing guide member 25 and the optical disc 1. Further, the side of the stabilizing guide member 25 from which the optical disk 1 is ejected is a negative pressure generating portion 25b having a concave shape, and the air flowing through the negative pressure generating portion 25b expands rapidly, resulting in a negative pressure compared to the atmospheric pressure. Therefore, an attractive force is exerted between the stabilizing guide member 25 and the optical disc 1.
[0080]
As described above, the surface shake of the optical disk 1 can be stabilized only by the balance between the attractive force and the repulsive force caused by the difference in air pressure according to Bernoulli's law between the stabilizing guide member 25 and the optical disk 1.
[0081]
Furthermore, by providing a flat portion 25c at the boundary (guide surface curvature boundary line) between the positive pressure generating portion 25a and the negative pressure generating portion 25b in the stabilizing guide member 25, the surface blur stable region can be greatly expanded. Yes. Thus, both the repulsive force and the attracting force are generated in the stabilizing guide member 25, and the distance between the optical disc 1 and the stabilizing guide member 25 can be stabilized by these acting forces.
[0082]
As shown in FIG. 8, the stabilizing guide member 8 (25) is installed at a plurality of locations in the circumferential direction so as to face the optical disc 1, so that the optical disc 1 or the optical disc 1 adapted to the design and specifications of the apparatus can be used. It is conceivable to set the stable state as appropriate.
[0083]
In the present embodiment, since the surface blur or tilt is corrected by aerodynamic force, the optical disc 1 must be soft and flexible. As a result, in the region that is not stabilized by the stabilizing guide member, the optical disc 1 has a larger surface shake than that of a normal disc material such as a CD, and the surface shake up to about 0.5 mm is easy. appear. In some cases, it is difficult to converge this surface blur to 5 μm or less at once with a stabilizing guide member around the optical pickup 6.
[0084]
Therefore, in the present embodiment, as shown in FIGS. 8 to 10, a plurality of stabilizing guide members 8 are installed in the circumferential direction of the optical disk 1 and also at positions away from the periphery of the optical pickup 6, thereby By roughly stabilizing the whole 1 and further stabilizing the main stable surface (near the optical pickup 6), the margin of the device system design could be improved.
[0085]
As shown in FIG. 8, the stabilization guide member 8 installed opposite to the optical pickup 6 is a main stabilization guide member 8a, and the stabilization guide member 8 installed away from the optical pickup 6 is a sub-stabilization guide member 8b. Then, the sub-stabilization guide member 8b installed for rough stabilization does not need to have so much precision in the stabilizing action. Since it is sufficient to take a large surface blur that reaches about 0.5 mm, it is sufficient to generate mainly a repulsive force, and a simple spherical convex shape is sufficient. Rather, it is necessary to have an installation configuration that does not cause sliding. This is because it is preferable not to cause unnecessary vibration by sliding. For this reason, the sub-stabilization guide member 8b as an auxiliary guide for rough stabilization has a larger flying height when the shape is larger than the main stabilization guide member 8a as a main guide in the vicinity of the optical pickup 6. preferable. That is, the larger the guide shape (higher, the larger area) tends to increase the flying height.
[0086]
For example, as shown in FIG. 9, a main stabilizing guide member 8a as a main guide is formed with a diameter D. ₁ (= About 10 mm) of a cylindrical shape, the diameter D of the auxiliary stabilizing guide member 8b as an auxiliary guide ₂ Is a cylinder having a diameter of 20 mm larger than that of the main stabilizing guide member 8a, the flying height of the auxiliary guide becomes larger. Alternatively, as shown in FIG. 10, the installation reference plane of the optical disc 1 (the horizontal extension line of the chucking position between the spindle shaft 2 of the spindle motor 4 and the hub 3 of the optical disc 1 shown in FIG. 1) and the both stabilizing guide members 8a. , 8b distance L ₁ , L ₂ By making the distance L2 of the auxiliary stabilization guide member 8b longer than the distance L1 of the main stabilization guide member 8a, the flying height of the auxiliary guide becomes larger. By doing so, the frequency of occurrence of disk sliding in the sub-stabilizing guide member 8b can be reduced.
[0087]
Further, when the shape of the stabilizing guide member 8 is a cylinder and the tip has a hemispherical shape, the area at the cross-sectional portion parallel to the optical disc 1 and the flying height are proportional. Therefore, if the auxiliary guide is large, the flying height is stabilized at a large point.
[0088]
In the first embodiment shown in FIG. 1, the stabilization guide member 8 and the stabilization guide positioning mechanism 9 are installed in the upper part of the apparatus main body 10. Therefore, the user can handle the optical disc 1 in a bare state without a cartridge.
[0089]
In this case, since the optical disk 1 is a thin sheet, for example, it can be handled in a bag, taken out when used, and set on the spindle shaft 2 to be used as an inexpensive optical information recording medium. can do.
[0090]
FIG. 11 is a schematic configuration diagram of an optical information recording / reproducing apparatus for explaining the second embodiment of the present invention. The second embodiment is different from the first embodiment in that one optical disk 1 is opened. A disk cartridge 27 provided with windows 26 and 26 is built in, the disk cartridge 27 is set at a predetermined position in the apparatus, and the shutters 28 and 28 are moved by operating means (not shown) to open the open windows 26 and 26. The stabilization guide member 8 and the optical pickup 6 are moved so as to be inserted into the recording / reproducing state.
[0091]
As the disk cartridge 27, one having a general configuration can be adopted, so that there is no cost increase.
[0092]
FIG. 12 is a schematic configuration diagram of an optical information recording / reproducing apparatus for explaining a third embodiment of the present invention. In the third embodiment, a stabilizing guide member 30 is installed inside a disk cartridge 31. It is. In this case, as shown in FIG. 13, the stabilization guide member 30 has a horizontally long shape extending in the radial direction of the optical disc 1, and is provided with the stabilization guide positioning mechanism 9 as in the first and second embodiments. It is unnecessary. Due to the action of the stabilization guide member 30, stabilization of the surface shake of the optical disc 1 occurs in the same manner as described in the first embodiment, and the stabilization guide member 30 stabilizes the surface shake of the optical disc 1 most. The stabilizing guide member 30 is installed so that the region that can be converted to the light is located at the condensing point of the optical pickup 6.
[0093]
Also in the third embodiment, the shutter 28 is moved by operating means (not shown), and moved so as to insert the optical pickup 6 into the opened opening window 26 so that recording / reproduction is possible.
[0094]
In the third embodiment, since the stabilization guide member 30 is built in the disk cartridge 31, the overall configuration of the apparatus can be made substantially the same as the configuration of a conventional apparatus using a rigid substrate optical disk. It becomes easy to achieve compatibility with an optical disk system using such a rigid substrate.
[0095]
FIG. 14 is a plan view for explaining an embodiment of a disk cartridge according to the present invention, and FIG. 15 is a partial sectional view taken along line AA in FIG. 14, similar to the optical recording / reproducing apparatus of the first embodiment. It is a disc cartridge that can be used for various devices.
[0096]
As shown in FIGS. 14 and 15, a plurality of flexible sheet-like optical disks 1 can be stored in the disk cartridge 33 and can be used as a changer. The capacity can be increased by the number of the optical discs 1 that are present. Even if a large number of optical disks 1 are stored in the disk cartridge 33, the entire volume of the disk cartridge 33 does not increase because the optical disk 1 is thin.
[0097]
The disc cartridge 33 according to the present embodiment is configured such that one end portion of each optical disc 1 is sandwiched between disc discs 34 that support the optical disc 1 and stored in an overlapped manner, and the disc tray 34 is recorded / reproduced together with the optical disc 1. A changer operation is performed by inserting and removing between the apparatus and the disk cartridge 33.
[0098]
Each disc tray 34 is provided with a disc tray identifying portion 35 protruding at a different position for each sheet, and a changer mechanism (not shown) for detecting and taking this different position is installed on the recording / reproducing apparatus side. Thus, it is possible to distinguish and load the optical discs one by one.
[0099]
In this embodiment, since the optical disk 1 is thin, the disk interval is narrow. Therefore, in order to enable the changer mechanism of the recording / reproducing apparatus to distinguish between the upper and lower optical discs 1, the disc tray identifying portions 35 are placed at different positions in the horizontal direction as shown in FIG. It is installed. The recording / reproducing apparatus side moves the arm member by, for example, hooking an unillustrated arm member in a hole 35a formed in the disc tray identifying portion 35 with the disc tray identifying portion 35 at a different position in the lateral direction. Thus, the optical disk 1 can be taken in and out of the disk cartridge 33. Compared to a configuration in which the disc tray identification unit 35 is installed vertically, the configuration in the present embodiment can be easily identified because the distance in the horizontal direction is relatively large.
[0100]
As described above, the disk cartridge 33 shown in FIGS. 14 and 15 has a structure in which the disk trays 34 are simply stacked, and thus has a very simple structure, and can be a small and large capacity cartridge.
[0101]
In the above description of the embodiment, the rewritable optical disk using the phase change recording layer has been described. However, the present invention provides a guide shape for further improving the accuracy of guide stabilization of a flexible optical disk. Since it can be applied to the recording / reproducing system, the same effect can be obtained for other optical discs that collect and collect light such as a reproducing optical disc using embossed pits or a magneto-optical recording disc. I can expect.
[0102]
Moreover, about the stabilization guide member, the thing of various shapes and structures can be employ | adopted, For example, what is shown in FIGS. 16-21 can be illustrated. Stabilizing guide members 40 and 41 shown in FIGS. 16 (a) and 16 (b) have the structure described in FIG. 7, and have convex first guide surfaces 40a and 41a and concave second guides. Surfaces 40b and 41b and flat surfaces 40c and 41c are formed on the surface, and the stabilizing guide member 40 in FIG. 16A is disposed in the radial direction of the optical disk along the movement flow line of the optical pickup. The stabilizing guide member 41 shown in FIG. 16B is installed so as to be movable in the radial direction of the optical disc along the movement flow line of the optical pickup.
[0103]
In addition, in the stabilizing guide members 40 and 41 shown in FIGS. 16A and 16B, the flat surfaces 40c and 41c are eliminated, and only the first guide surfaces 40a and 41a and the second guide surfaces 40b and 41b are formed. It may be a thing.
[0104]
The stabilization guide members 42 and 43 shown in FIGS. 17 and 18 are, in order from the upstream side in the disk rotation direction, convex first guide surfaces 42a and 43a, flat surfaces 42c and 43c, and convex second guides. The stabilization guide member 42 in FIG. 18A is disposed in the radial direction of the optical disk along the movement flow line of the optical pickup, and is formed from the surfaces 42b and 43b. ) Stabilization guide member 43 is installed to be movable in the radial direction of the optical disc along the movement flow line of the optical pickup.
[0105]
In the stabilization guide members 42 and 43 shown in FIGS. 18A and 18B, the flat surfaces 42c and 43c are eliminated, and only the first guide surfaces 42a and 43a and the second guide surfaces 42b and 43b are formed. Alternatively, the second guide surfaces 42b and 43b may be omitted, and only the first guide surfaces 42a and 43a and the flat surfaces 42c and 43c may be formed.
[0106]
A stabilization guide member 44 shown in FIG. 19 and FIG. 20 has, in order from the upstream side in the disk rotation direction, a first guide surface 44a having a convex shape and a curved surface in a direction perpendicular to the disk rotation direction, and the disk rotation. A flat surface 44c having a curved side surface in a direction orthogonal to the direction and a second guide surface 44b having a convex shape and a curved surface in a direction perpendicular to the disk rotation direction are formed. The stabilizing guide member 44 is installed so as to be movable in the radial direction of the optical disc along the movement flow line of the optical pickup.
[0107]
19 and 20, the flat guide surface 44c may be eliminated and only the first guide surface 44a and the second guide surface 44b may be formed, or the second guide may be provided. The surface 44b may be eliminated, and only the first guide surface 44a and the flat surface 44c may be formed.
[0108]
The stabilization guide member 45 shown in FIG. 21 is basically cylindrical, and has a curved surface 45a formed on the end surface facing the optical disc 1 in the same manner as the stabilization guide member 8 shown in FIG. is there.
[0109]
As described above, according to each of the embodiments, when the flexible optical disk is rotated at the position facing the stabilization guide member, the stabilization guide member applies positive pressure to the optical disk on the upstream side in the rotation direction. As a result, a repulsive force acts on the optical disc and the stabilizing guide member at that portion, and the optical disc floats with respect to the stabilizing guide member with a certain distance. Further, by generating a negative pressure by changing the shape of the stabilizing guide member on the downstream side in the rotation direction, the optical disc receives a suction force toward the stabilizing guide member at that portion. However, since the optical disk has a certain degree of rigidity, it does not slide immediately against the stabilizing guide member.
[0110]
As described above, after the optical disk receives a repulsive aerodynamic force from one stabilization guide member, the optical disk and the stabilization guide member receive a suction force opposite to the aerodynamic force. The optical disk rotates while maintaining a certain distance and stabilizing this distance. Accordingly, by focusing the recording / reproducing light on this stable area, it is possible to record / reproduce on an area where the optical disc has a small surface shake and tilt.
[0111]
Since the aerodynamic force is used for the stabilization and the substrate constituting the optical disk is made low in rigidity, it is not necessary to prepare the optical disk itself with high accuracy, and it is possible to eliminate a large surface shake. Therefore, the configuration of the optical pickup for recording / reproducing does not have to follow a large surface fluctuation, and therefore, defocusing is reduced, and high-density recording / reproducing can be stably performed.
[0112]
Furthermore, from this, as an actuator of the objective lens constituting the optical pickup, instead of not corresponding to a large amplitude in the low frequency band, by adopting a highly rigid one as an elastic member (spring) for supporting the actuator, An optical pickup having characteristics in which high-frequency resonance exists on the high frequency side can be configured. For this reason, the operation of the servo system can be speeded up, and the defocus can be suppressed even at a higher linear velocity.
[0113]
In addition, surface blurring is more effective by making the area where the aerodynamic force according to Bernoulli's theorem does not act at any position upstream and downstream of the disk rotation direction rather than the part where surface blurring is stabilized in the optical disk. Will be suppressed. This is because the optical disc having flexibility is deformed by the stabilization guide member to forcibly generate a stabilization region of the optical disc at the light condensing point. If the optical disk is provided with a portion that becomes “escape”, the repulsive force of the optical disk in the stabilization region can be reduced, and the effect of the stabilization force of the aerodynamic force is increased.
[0114]
The conventional configuration in which the flat plate guide member is placed opposite to the entire surface of the flexible disk is to have a stabilizing surface corresponding to the entire disk surface, and to install a flat plate larger than the disk. . Therefore, when this configuration is applied to a recording / reproducing apparatus using an optical disk, the surface blur of the optical disk is stabilized even in the periphery other than the condensing point of the optical pickup, which is a part where the surface blur is desired to be stabilized. For this reason, when the optical disc has waviness, even if it is desired to stabilize the vicinity of the light condensing point, the bending force from the front and rear (upstream / downstream) positions in the disc rotation direction acts strongly, and the surface blurring occurs. Stabilization may be insufficient.
[0115]
Further, in the case where the recording layer is formed on a flexible substrate as an optical disk, the substrate is likely to warp on the opposite side with respect to the film formation surface. Therefore, as in this embodiment, by performing the aerodynamic guide on the substrate side of the optical disc on the substrate side, the stabilizing action is achieved by the force to return the substrate itself and the repulsive force of the stabilization guide member. Can be performed satisfactorily. For this reason, in this embodiment, a recording / reproduction is performed by providing a stabilizing guide member on the substrate side of the optical disc and an optical pickup on the recording layer side. By adopting such a configuration, even if the optical disk and the optical pickup are in a sliding state and the optical disk is damaged, the scratch does not occur on the recording layer side. It does not cause. In addition, because of such a configuration, the recording / reproducing light does not pass through the substrate of the optical disk, so the recording / reproducing characteristics are not affected by scratches and the optical characteristics of the substrate.
[0116]
In this embodiment, since the optical disk is soft and flexible, the optical disk is likely to be greatly shaken in an area that is not stabilized by the stabilizing guide member. However, it is difficult to converge this surface blur at once with the stabilizing guide member around the optical pickup. For this reason, in this embodiment, a plurality of stabilizing guide members are installed in the circumferential direction of the optical disk and at positions away from the periphery of the optical pickup, so that the entire optical disk is coarsely stabilized, and the main stable surface (optical pickup) In the vicinity), further stabilization is attempted. As a result, the margin of the device system design can be improved.
[0117]
Although the optical recording / reproducing apparatus has been described as an example in the above-described embodiment, an optical disk having flexibility for recording and / or reproduction, such as an information recording single-function apparatus or an information reproduction single-function apparatus, is used. The same effect can be obtained by applying to the apparatus to be used.
[0118]
【The invention's effect】
As described above, according to the present invention, the surface shake in the rotation axis direction at the portion where information is written / read on the flexible sheet-like optical disc is caused by the pressure difference of the air flow based on Bernoulli's law. In an apparatus equipped with stabilization means for stabilizing, by providing a portion that becomes “escape” at the front and rear positions of the portion where the optical disc surface stabilization is stabilized, the repulsive force of the optical disc at the stabilized portion is reduced. Since the effect of the stabilizing force by the aerodynamic force is increased, high-density writing can be performed at the stabilized portion.
[0119]
In addition, the optical disc includes a stabilizing means for stabilizing the vibration in the direction of the rotation axis in a portion where information is written / read on the flexible sheet-like optical disc as described above by the air flow pressure difference. Writing / reading is performed from the portion where the surface blurring on the recording surface side is stabilized by making at least one on the side opposite to the recording surface in FIG. In addition, even if the optical disk slides with the stabilizing means and is damaged, the scratch does not attach to the recording surface, so that no error occurs. For example, the recording surface of the optical disk Even if the substrate on the opposite side is scratched, the recording / reproducing light does not pass through the substrate, so that it is not affected by the scratch on the substrate and the optical characteristics of the substrate. Therefore, stable recording / reproduction can be performed over a long period of time, and there is no problem due to the installation of the stabilizing means.
[0120]
In addition, by storing a flexible sheet-shaped optical disk used in the apparatus in a cartridge case, even an optical disk that is thin and easily bent can be handled easily, and a plurality of optical disks can be stored. Thus, a large recording capacity can be obtained, and the actual effect is great, for example, the cartridge does not become thick as a whole.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an optical information recording / reproducing apparatus for explaining a first embodiment of the invention.
FIG. 2 is an explanatory diagram of recording means and reproducing means constituting an optical pickup in an embodiment of the present invention.
FIG. 3 is a cross-sectional view showing an example of an optical disc according to an embodiment of the present invention.
FIG. 4 is an explanatory diagram for explaining stabilization of surface wobbling of an optical disc according to an embodiment of the present invention.
FIG. 5 is a diagram showing the measurement result of the surface deflection of the optical disc measured for the configuration example shown in FIG. 4;
FIG. 6 is a flowchart relating to operations at the time of recording / reproducing in the embodiment of the present invention.
FIG. 7 is an explanatory view showing a modification of the stabilization guide member in the first embodiment.
FIG. 8 is an explanatory view of an arrangement example of the stabilization guide member in the first embodiment.
FIG. 9 is an explanatory view showing another example of the arrangement example of the stabilizing guide member in the first embodiment.
FIG. 10 is an explanatory view showing another example of the arrangement example of the stabilizing guide member in the first embodiment.
FIG. 11 is a schematic configuration diagram of an optical information recording / reproducing apparatus for explaining a second embodiment of the present invention.
FIG. 12 is a schematic configuration diagram of an optical information recording / reproducing apparatus for explaining a third embodiment of the present invention.
FIG. 13 is an explanatory view of an arrangement example of a stabilizing guide member in the third embodiment.
FIG. 14 is a plan view for explaining an embodiment of the disk cartridge of the present invention.
15 is a partial sectional view taken along line AA in FIG.
FIG. 16 is an explanatory view showing a configuration example of a stabilization guide member in the embodiment of the present invention.
FIG. 17 is an explanatory view showing a configuration example of a stabilization guide member in the embodiment of the present invention.
FIG. 18 is an explanatory view showing a configuration example of a stabilization guide member in the embodiment of the present invention.
FIG. 19 is an explanatory view showing a configuration example of a stabilization guide member in the embodiment of the present invention.
FIG. 20 is an explanatory view showing a configuration example of a stabilization guide member in the embodiment of the present invention.
FIG. 21 is an explanatory view showing a configuration example of a stabilization guide member in the embodiment of the present invention.
[Explanation of symbols]
1 Optical disc
2 Spindle shaft
3 Hub
4 Spindle motor
6 Optical pickup
7 Pickup positioning mechanism
8, 25, 30, 40 to 45 Stabilizing guide member
8a Main stabilization guide member
8b Sub-stabilizing guide member
9 Stabilizing guide positioning mechanism
10 Device body
14 Laser light source
15 Objective lens
17 Photoelectric conversion element
20 Recording layer of optical disc
21 Optical disk substrate
25a Positive pressure generating portion of stabilizing guide member
25b Negative pressure generating portion of stabilizing guide member
25c Flat part of stabilizing guide member
27,33 Disc cartridge
34 Disc tray
35 Disc tray identification section

Claims (45)

Rotation driving means for rotating a flexible sheet-like optical disc, and Bernoulli's law for the rotation in the direction of the rotational axis at least on the portion of the optical disc where writing or reading is performed. An optical disk drive device comprising stabilization means for stabilizing the air flow based on a pressure difference based on
2. An optical disk drive apparatus comprising: an optical disk drive unit configured to provide a region in which an air flow pressure difference is not generated between an upstream side and a downstream side in a disk rotation direction of a portion where surface deflection is stabilized by the stabilizing unit.   2. The optical disk drive device according to claim 1, wherein the stabilizing means is a protruding member protruding in the optical disk direction.   2. The stabilization means is characterized in that a portion for generating a positive pressure with respect to the atmospheric pressure upstream of the disk rotation direction and generating a negative pressure with respect to the atmospheric pressure downstream of the disk rotation direction is formed. 3. The optical disk drive device according to 1 or 2.   4. The optical disk drive device according to claim 2, wherein a flat surface portion for stabilizing the surface blur of the optical disk is formed at the most protruding portion of the protruding surface of the stabilizing means.   5. An optical disk drive device according to claim 4, wherein an arcuate surface portion is formed at least upstream of the flat surface portion in the stabilizing means in the disk rotation direction.   6. The optical disc driving apparatus according to claim 1, wherein the stabilizing means is scattered in the circumferential direction of the optical disc.   7. The optical disc driving apparatus according to claim 6, wherein the plurality of stabilizing means are set to have different heights depending on installation positions.   8. The optical disc driving apparatus according to claim 6, wherein the plurality of stabilizing means are set so that a cross-sectional area of a portion parallel to the optical disc differs depending on an installation position.   9. The optical disc driving apparatus according to claim 1, wherein the stabilizing means extends in a radial direction of the optical disc.   The optical disk drive device according to claim 1, wherein the stabilizing means is installed on a part of a constituent member of the optical disk drive device.   11. The optical disc driving apparatus according to claim 1, wherein a flexible sheet-like optical disc can be mounted on a predetermined set part as a single unit.   Rotation drive means for rotating a sheet-like optical disk having flexibility, optical writing means for writing information by irradiating the recording surface of the optical disk, and on the side opposite to the recording surface side of the optical disk Stabilizing means for stabilizing the vibration in the direction of the rotation axis in a portion of the optical disk where information is written and locally stabilized by the pressure difference of the air flow, and the optical writing means and the stabilizing means, Is installed so as to face each other through an optical disk. Rotation driving means for rotating a sheet-like optical disk having flexibility, optical writing means for writing information on the recording surface of the optical disk, and the recording surface side of the optical disk on which the optical writing means is installed An optical information recording apparatus provided with a stabilizing means that is installed on the side opposite to the optical disk and stabilizes the vibration in the direction of the rotation axis in the portion of the optical disk to be written by the pressure difference of the air flow based on Bernoulli's law. There,
2. An optical information recording apparatus according to claim 1, wherein a region in which a pressure difference of the air flow is not generated is provided on an upstream side and a downstream side in a disc rotation direction of a portion of the optical disc where the surface blur is stabilized by the stabilizing means.   14. The optical information recording apparatus according to claim 12, wherein the stabilizing means is a protruding member protruding in the direction of the optical disk.   2. The stabilization means is characterized in that a portion for generating a positive pressure with respect to the atmospheric pressure upstream of the disk rotation direction and generating a negative pressure with respect to the atmospheric pressure downstream of the disk rotation direction is formed. The optical information recording apparatus according to 12, 13 or 14.   16. The optical information recording apparatus according to claim 14, wherein a flat surface portion for stabilizing the surface blur of the optical disc is formed at the most protruding portion of the protruding surface of the stabilizing means.   17. The optical information recording apparatus according to claim 16, wherein an arcuate surface portion is formed at least upstream of the flat surface portion of the stabilizing means in the disk rotation direction.   18. The optical information recording apparatus according to claim 13, wherein the optical writing unit and the stabilizing unit are disposed so as to face each other with an optical disc interposed therebetween.   The optical information recording apparatus according to any one of claims 12 to 18, wherein the stabilizing means is scattered in a circumferential direction of the optical disk.   In the stabilizing means, the stabilizing means opposite to the optical writing means is a main stabilizing means, and other than the main stabilizing means are sub-stabilizing means, and the main stabilizing means and the sub-stabilizing means are high. 20. The optical information recording apparatus according to claim 19, wherein the optical information recording apparatus is set to be different from each other.   21. The optical information according to claim 20, wherein the distance between the sub-stabilizing means and the installation reference plane of the optical disc is set longer than the distance between the main stabilization means and the installation reference plane of the optical disc. Recording device.   In the stabilization means, the stabilization means opposite to the optical writing means is a main stabilization means, and the other than the main stabilization means is a sub-stabilization means, and the optical disk in the main stabilization means and the sub-stabilization means The optical information recording apparatus according to any one of claims 19 to 21, wherein the cross-sectional areas of parts parallel to the head are different from each other.   23. The optical information according to claim 22, wherein the cross-sectional area of the portion parallel to the optical disc in the sub-stabilization means is set larger than the cross-sectional area of the portion parallel to the optical disc in the main stabilization means. Recording device.   The optical information recording apparatus according to any one of claims 12 to 23, wherein the stabilizing means extends in a radial direction of the optical disk.   In order to maintain the opposing relationship between the optical writing means and the stabilizing means, there is provided means for moving the stabilizing means in conjunction with the optical writing means in the radial direction of the optical disc. The optical information recording device according to any one of claims 12 to 24.   The optical information recording apparatus according to any one of claims 12 to 25, wherein the stabilizing means is installed on a part of a constituent member in the apparatus main body.   27. The optical information recording apparatus according to any one of claims 12 to 26, wherein a flexible sheet-like optical disk can be mounted on a predetermined set part as a single unit. Rotation drive means for rotating a flexible sheet-like optical disk, optical reading means for reading information by irradiating light on the recording surface of the optical disk, and installed on the side opposite to the recording surface side of the optical disk The optical reading means and the stabilizing means are provided with stabilizing means for locally stabilizing the vibration in the direction of the rotation axis in the part of the optical disk from which information is read, by the pressure difference of the air flow, An optical information reproducing apparatus, which is installed so as to face each other through an optical disk. Rotation driving means for rotating a flexible sheet-like optical disk, optical reading means for reading information recorded on the recording surface of the optical disk, and the recording surface side of the optical disk on which the optical reading means is installed An optical information reproducing apparatus equipped with a stabilizing means that is installed on the side opposite to the optical disk and stabilizes the vibration in the direction of the rotation axis at the part of the optical disk to be read by the pressure difference of the air flow based on Bernoulli's law. There,
2. An optical information reproducing apparatus according to claim 1, wherein a region in which a pressure difference of the air flow is not generated is provided on an upstream side and a downstream side in a disc rotation direction of a portion of the optical disc in which surface stabilization is stabilized.   30. The optical information reproducing apparatus according to claim 28, wherein the stabilizing means is a projecting member projecting in the direction of the optical disc.   2. The stabilization means is characterized in that a portion for generating a positive pressure with respect to the atmospheric pressure upstream of the disk rotation direction and generating a negative pressure with respect to the atmospheric pressure downstream of the disk rotation direction is formed. 28. An optical information reproducing apparatus according to 28, 29 or 30.   32. The optical information reproducing apparatus according to claim 30, wherein a flat surface portion for stabilizing the surface blur of the optical disc is formed at the most protruding portion of the protruding surface of the stabilizing means.   33. The optical information reproducing apparatus according to claim 32, wherein an arcuate surface portion is formed at least upstream of the flat surface portion of the stabilizing means in the disk rotation direction.   The optical information reproducing apparatus according to any one of claims 29 to 33, wherein the optical reading unit and the stabilizing unit are disposed so as to face each other with an optical disc interposed therebetween.   The optical information reproducing apparatus according to any one of claims 28 to 34, wherein the stabilizing means is scattered in the circumferential direction of the optical disk.   In the stabilizing means, the stabilizing means facing the optical reading means is a main stabilizing means, and other than the main stabilizing means is a sub-stabilizing means, and the main stabilizing means and the sub-stabilizing means are raised. 36. The optical information reproducing apparatus according to claim 35, wherein the optical information reproducing apparatuses are set to be different from each other.   The optical information according to claim 36, wherein the distance between the sub-stabilizing means and the installation reference plane of the optical disc is set longer than the distance between the main stabilization means and the installation reference plane of the optical disc. Playback device.   In the stabilizing means, the stabilizing means opposite to the optical reading means is a main stabilizing means, and other than the main stabilizing means is a sub-stabilizing means, and the optical disc in the main stabilizing means and the sub-stabilizing means is 38. The optical information reproducing apparatus according to any one of claims 35 to 37, wherein the cross-sectional areas of the parallel portions are set to be different.   The optical information according to claim 38, wherein a cross-sectional area of a portion parallel to the optical disc in the sub-stabilization means is set larger than a cross-sectional area of a portion parallel to the optical disc in the main stabilization means. Playback device.   40. The optical information reproducing apparatus according to claim 28, wherein the stabilizing means extends in a radial direction of the optical disk.   In order to maintain the opposing relationship between the optical reading means and the stabilizing means, there is provided means for moving the stabilizing means in conjunction with the optical reading means in the radial direction of the optical disc. Item 42. The optical information reproducing apparatus according to any one of Items 28 to 40.   The optical information reproducing apparatus according to any one of claims 28 to 41, wherein the stabilizing means is installed in a part of a constituent member in the apparatus main body.   43. The optical information reproducing apparatus according to any one of claims 28 to 42, wherein a flexible sheet-like optical disk can be mounted on a predetermined set part as a single unit.   The optical disk drive device according to any one of claims 1 to 10, the optical information recording device according to any one of claims 12 to 26, or any one of claims 28 to 42, in a cartridge case. A disc cartridge containing at least one optical disc used in the optical information reproducing apparatus described in 1.   The optical disk drive device according to any one of claims 1 to 9, the optical information recording device according to any one of claims 12 to 25, or any one of claims 28 to 41, in the cartridge case. 45. The disk cartridge according to claim 44, further comprising stabilizing means in the optical information reproducing apparatus according to claim 44.

Images