JP2004139670A - Information storage device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an information storage device which increasingly improves oscillation durability and shock durability to an oscillation and a shock from the outside of a housing. <P>SOLUTION: The information storage device 1 is attachable and detachable to an equipment main body and provided with a first housing which houses a hard disk drive mechanism part 2 in it, a second housing 3 which houses the first housing in it and a connector part. The first housing is separated from the second housing 3 and supported by a plurality of buffer materials 14 and 16, and a second buffer material 15, which gets contact only with either the first housing or the second housing 3 in a usual state, is arranged between the first housing and the second housing 3. The first buffer materials 14 and 16 include the buffer material 16 having nonlinear characteristics. The buffer material 16 has a size of elastic modulus which causes no resonance to the oscillation given from the outside in a static state, and the elastic modulus decreases when the shock is given. <P>COPYRIGHT: (C)2004,JPO

Description

【００２８】
式（１）より、固有振動数ωｃは、バネ定数ｋが小さい方が、小さな値となることがわかり、よって、振動用緩衝材１４においては、バネ定数ｋが小さい方がそれだけ広い振動数域で防振効果を得ることができることになる。
【００２９】
一方、衝撃吸収においては、ある対象物が落下衝撃を受けた際にそれが壊れるかどうかの基準となるバウンダリーカーブを使用して最適なバネ定数を判断した。図８に示すバウンダリーカーブでは、横軸が対象物の受ける速度変化（Ｖｅｌｏｃｉｔｙ　Ｃｈａｎｇｅ　）であり、縦軸が対象物の受ける加速度（Ａｃｃｅｌｅｒａｔｉｏｎ）であり、図中領域Ａで示す範囲は、対象物が壊れる落下衝撃の速度変化及び加速度の範囲である。図８からわかるように、ある対象物が落下衝撃を受けた際に壊れないようにするためには、落下衝撃による速度変化及び加速度を図中領域Ｂの範囲に、具体的には速度変化を小さくするか、加速度を小さくすることが必要である。
【００３０】
一般に、緩衝材は、そのクッション性を利用して対象物の受ける衝撃加速度を低くすることで、対象物が壊れないようにするものである。このため、大きな衝撃吸収効果を得るためには、上述した振動用緩衝材１４における物理モデル（図７）を再度使用して得られる衝撃用緩衝材１５のバネ定数ｋがどのような値をとるときが最も小さな加速度となるかが問題となる。そこで、複数のバネ定数ｋ（ｋ１〜ｋ４）を横軸に、横軸のバネ定数を有する緩衝材に落下させた際に対象物が受ける最大加速度を縦軸とする特性図を図９に示す。衝撃用緩衝材１５のバネ定数ｋが最も小さい場合（ｋ１）には、受けた衝撃に対して柔らかすぎて衝撃用緩衝材１５が潰れきってしまい、最大加速度が大きくなる。また、逆に、衝撃用緩衝材１５のバネ定数が最も大きい場合（ｋ４）には、緩衝材が硬すぎてクッション性がなく、やはり最大加速度が大きくなってしまう。図９からわかるように、最も小さいバネ定数ｋ１と最も大きいバネ定数ｋ４との間に、最も加速度を小さくする最適なｋ、図９においてはバネ定数ｋ３が存在し、このバネ定数ｋ３の緩衝材が最も高い衝撃吸収効果を得ることができることになる。
【００３１】
このようなことから、防振用の緩衝材と衝撃吸収用の緩衝材とでは、最も高い効果を得ることができる緩衝材の大きさやバネ定数がそれぞれ異なり、一の緩衝材で防振用と衝撃吸収用とを両立することは困難である。このため、情報記憶装置１においては、異なる大きさとバネ定数を有し、振動吸収に適した振動用緩衝材１４と、衝撃吸収に適した衝撃用緩衝材１５という２種の緩衝材がそれぞれ筺体３内に配されている。
このように、情報記憶装置１においては、防振用の緩衝材と衝撃吸収用の緩衝材とを別個に設けることにより、振動吸収、衝撃吸収のそれぞれにおいて、最適な大きさやバネ定数を有する緩衝材を選択して使用することができ、防振、衝撃吸収のそれぞれにおいて高い効果を得て、耐振動性、耐衝撃性を向上させることができる。
【００３２】
上述した振動用緩衝材１４は、図３に示すように、略円錐台形状を呈し、ハードディスク駆動機構部２の側面と筺体３の側面との間に、小径部側の端面が筺体３に、大径部側の端面がハードディスク駆動機構部２にそれぞれ接するように配置されている。この振動用緩衝材１４は、ハードディスク駆動機構部２の４つの側面に配され、これら側面の両端部近傍にそれぞれ配設されている。
【００３３】
しかしながら、上述した略円錐台形状の振動用緩衝材１４だけで振動用緩衝材を構成すると、バネ定数（弾性係数）がほぼ一定となることから、前述したように、一般車両内で使用した場合に車両から発生する幅広い周波数領域（１０〜２００Ｈｚ）の振動に対して防振を行うことが難しくなる。
【００３４】
ここで、実際に試算を行ってみる。
例えば図６に示す範囲のうち、防振の効果が現れるのは、入力加速度に対して出力加速度が小さくなる部分、即ち縦軸の値がＧｏｕｔ／Ｇｉｎ＜１の部分であり、横軸においてω／ωｃ＞１．４の部分（ω：加振振動数（入力振動数）、ωｃ：共振振動数（固有振動数））である。
質量ｍの物体をバネ定数ｋで支えている場合の共振振動数ωｃは、数１で計算される。
【００３５】
共振振動数ωｃと共振周波数ｆとの間に、ωｃ＝２πｆという関係があることから、式（１）と合わせて、バネ定数ｋについて次式（２）が成り立つ。
ｋ＝ｍωｃ^２＝ｍ・（２πｆ）^２　（２）
次に、ハードディスク駆動機構部２の質量を０．１ｋｇと仮定して、車両から発生する振動（１０〜２００Ｈｚ）に対して振動しないようにする、即ち加振周波数が１０Ｈｚでも振動しないようにするためのバネ定数ｋを求める。図６の結果から、ω／ωｃ＝１０［Ｈｚ］／ｆ＞１．４であるから、共振周波数ｆの範囲は
ｆ＜７．１４
となる。この範囲を式（２）に当てはめると、
ｋ＜２０１［Ｎ／ｍ］
となる。このとき、バネ（振動用緩衝材１４）のたわみ量ｘは、ハードディスク駆動機構部２の質量ｗから求めることができ、

となる。
従って、ハードディスク駆動機構部２の自重で４．９ｍｍもたわむような非常に柔らかい振動用緩衝材１４が必要となることがわかるが、もともと振動用緩衝材１４が設けられる隙間が数ｍｍ程度しかないため、４．９ｍｍもたわむことはほとんど不可能であり、そのような緩衝材を使用することができない。
【００３６】
そこで、本実施の形態の情報記憶装置１においては、振動用緩衝材のばね定数（弾性係数）を小さくして積極的に防振を行うのではなく、入力に対して出力が１となる状態、即ちω／ωｃ＜１となる状態で、共振を起こさないようにハードディスク駆動機構部２を支持すると共に、衝撃を受けたときに衝撃用緩衝材１５を作用させて衝撃吸収を行うことが可能なように、振動用緩衝材を構成するものである。
【００３７】
図６の結果から、ω／ωｃ＜１となる状態で共振を起こさないのは、ω／ωｃ＜０．２程度であるので、これを満たすような加振振動数ωに対して充分大きい共振振動数ωｃを有する緩衝材、即ち充分大きいバネ定数（弾性係数）ｋを有する緩衝材を、振動用緩衝材として使用する。
【００３８】
具体的には、ハードディスク駆動機構部２のトップカバー６側の上面と筐体３の天面板との間、並びにハードディスク駆動機構部２の配線基板１２側の下面と筺体３の底面板との間に、板バネから成る第２の振動用緩衝材１６が配置されて、情報記憶装置１が構成されている。
第２の振動用緩衝材１６は、図１及び図３に示すように、ハードディスク駆動機構部２の上面及び下面において、各面の四隅近傍に配設されている。
【００３９】
この第２の振動用緩衝材１６の拡大図を図４Ａに示す。また図４ＡのＡ−Ａ´における断面図を図４Ｂに示す。
この第２の振動用緩衝材１６は、図４Ａ及び図４Ｂに示すように、板面が平坦面ではなく、曲率を有する曲面１６Ｃとなっている板バネにより構成されている。
これは、板バネ１６が衝撃等によりたわんでいくときのたわみと反力の関係を非線形にすることを目的としている。
【００４０】
また、板バネ１６の板面の途中には、幅が狭くなったくびれ部１６Ｂが設けられている。このくびれ部１６Ｂが設けられていることにより、衝撃が加わった際に、細く最も弱くなっているくびれ部１６Ｂにおいて板バネ１６が屈曲する。即ち、くびれ部１６Ｂにより、衝撃が加わった際に板バネ１６が屈曲する位置を規制することができる。このくびれ部１６Ｂで板バネ１６が大きく屈曲することにより、屈曲したときの高さをできるだけ低く抑えることができるので、衝撃用緩衝材１５がハードディスク駆動機構部２に接触して衝撃を吸収することができる。
【００４１】
さらに、板バネ１６の一端（図中右端）は、螺子等で留めるための穴１７を有しハードディスク駆動機構部２に対して固定される固定端１６Ａとなっており、板バネ１６の他端（図中左端）は穴がなく固定されない自由端となっている。
このように他端は自由端となっているため、静的な状態では筐体３と接触してハードディスク駆動機構部２を支持することが可能である。一方、衝撃が加わった際には、くびれ部１６Ｂでうまく屈曲させることができ、また筐体３との接触点が動くことにより衝撃を緩和することが可能になる。
もし板バネの両端が固定されていると、衝撃が加わった時に板バネの板面に大きな力が掛かり、くびれ部１６Ｂでうまく屈曲しないで衝撃がハードディスク駆動機構部２に伝わってしまうおそれがある。
【００４２】
ここで、この板バネ１６の特性として、たわみ（押し込み変位）−反力（押し込み力）の関係を図４Ｃに示す。
図４Ｃに示すように、たわみと反力の関係は線形ではなく、押し込み変位がｕ１以下で見かけのバネ定数（図４Ｃの線の傾き）がｋ１である第１の状態と、押し込み変位ｕ１以上で見かけのバネ定数がｋ２（＜ｋ１）と急激にバネ定数が下がった第２の状態と、特性の異なる２つの状態に分かれている。
【００４３】
板バネ１６がこのような特性（非線形の特性）を持つことにより、情報記憶装置１が静置されている静的な状態では、ハードディスク駆動機構部２の重力だけが加わるため、荷重は小さく、第１の状態にあって強いバネ定数ｋ１で支えられている状態となる。このときの共振振動数ωｃは、式（２）から算出され、例えば一般車両で発生する加振振動数ωの領域（１０〜２００Ｈｚ）よりも高い周波数領域になるため、共振を起こさず、入力振動をそのまま伝達する。
一方、落下衝撃等の際には、数百Ｇを超える加速度が加わるため、板ばね１６に掛かる加重Ｆは瞬間的に大きくなり（Ｆ＝ｍ・ａ、ｍ：質量、ａ：加速度）、例えば数百Ｇ以上となる。このとき、板ばね１６が小さいバネ定数ｋ２の第２の状態に移り、たわみが大きくなることで、ハードディスク駆動機構部２が衝撃用緩衝材１５と接触し、この衝撃用緩衝材１５により衝撃吸収が行われる。
【００４４】
そして、本実施の形態の情報記憶装置１においては、ハードディスク駆動機構部２が、複数の振動用緩衝材１４，１６によって筺体３から離間して宙吊り状態に支持されている。
【００４５】
衝撃用緩衝材１５は、振動用緩衝材１４，１６で筺体３から離間して支持されているハードディスク駆動機構部２と筺体３との間の空間に、定常状態、即ち情報記憶装置１に対して振動も衝撃も加わっていない状態において、ハードディスク駆動機構部２又は筺体３のうちのいずれか一方にのみ接するように配設されている。
本実施の形態においては、衝撃用緩衝材１５を筺体３にのみ接し、ハードディスク駆動機構部２から所定の間隔を隔てて配設している。尚、衝撃用緩衝材１５は、これとは逆にハードディスク駆動機構部２にのみ接し、筺体３から所定の間隔を隔てて配設されるものであってもよい。
【００４６】
衝撃用緩衝材１５は、平板状を呈しており、ハードディスク駆動機構部２の側面に対しては、略中央部に対向する位置に少なくとも１枚配設されていると共に、ハードディスク駆動機構部２の側面に設けられた振動用緩衝材１４よりも大きな体積を有するものであり、後述するように情報記憶装置１が衝撃を受けた際におけるハードディスク駆動機構部２との接触面積も、振動用緩衝材１４のハードディスク駆動機構部２に対する接触面積に比して大きな面積とされている。
【００４７】
また、衝撃用緩衝材１５は、ハードディスク駆動機構部２の上面及び下面に対しては、これらの各辺近傍に対向する位置にそれぞれ配設されると共に、第２の振動用緩衝材１６のある部分を避けて設けられている。このため、筺体３の上ハーフ３ａ及び下ハーフ３ｂの短辺側では衝撃用緩衝材１５が長く形成されているのに対して、上ハーフ３ａ及び下ハーフ３ｂの長辺側では衝撃用緩衝材１５が短く形成されている。
【００４８】
尚、振動用緩衝材１４と衝撃用緩衝材１５のハードディスク駆動機構部２に対する接触面積は、本実施の形態ではこれら振動用緩衝材１４及び衝撃用緩衝材１５に同一材料を使用しているため、上述したように、即ち衝撃用緩衝材１５の接触面積が振動用緩衝材１４の接触面積に比して大きくなっている。
しかしながら、後述するように振動用緩衝材１４と衝撃用緩衝材１５とに異なる材料を使用する場合には、接触面積の大きさが上述したような関係を有するとは限らず、使用される材料との関係において適した接触面積とされる。
【００４９】
振動用緩衝材１４と衝撃用緩衝材１５とを上述したような配置とした本実施の形態の情報記憶装置１の水平方向における衝撃吸収の作用について、図１０を用いて説明する。図１０Ａは、情報記憶装置１におけるハードディスク駆動機構部２、筺体３、振動用緩衝材１４及び衝撃用緩衝材１５の、静的な状態、例えば情報記憶装置１が設置され、微弱な振動のみが伝わっている状態でのそれぞれの位置関係を模式的に示す図である。このような静的な状態においては、振動用緩衝材１４のみがハードディスク駆動機構部２に接して緩衝材として作用しているため、高い防振の効果を得ることができる。
【００５０】
これに対し、情報記憶装置１が落下して衝撃を受けた、いわゆる動的な場合には、図１０Ｂに示すように、振動用緩衝材１４が衝撃用緩衝材１５とハードディスク駆動機構部２との間隔ｔ以上潰れ、ハードディスク駆動機構部２が衝撃用緩衝材１５と接触する。その結果、今度は衝撃用緩衝材１５が緩衝材として作用して、ハードディスク駆動機構部２に加わる加速度を充分に低下させ、高い衝撃吸収効果を得ることができる。
そして、落下後に充分に時間が経過すると、再び筺体３内は静的な状態、即ち衝撃用緩衝材１５がハードディスク駆動機構部２から離間した状態に戻され、振動用緩衝材１４のみによる振動の吸収が行われるようになる。
【００５１】
同様に、第２の振動用緩衝材１６と衝撃用緩衝材１５とを上述したような配置とした本実施の形態の情報記憶装置１の上下方向における衝撃吸収の作用について、図１１を用いて説明する。図１１Ａは、情報記憶装置１におけるハードディスク駆動機構部２、筺体３、第２の振動用緩衝材１６及び衝撃用緩衝材１５の、静的な状態、例えば情報記憶装置１が設置され、微弱な振動のみが伝わっている状態でのそれぞれの位置関係を模式的に示す図である。このような静的な状態においては、第２の振動用緩衝材１６のみがハードディスク駆動機構部２に接して（固定されて）緩衝材として作用し、かつ第２の振動用緩衝材１６が高い弾性係数を有しているため、高い防振の効果を得ることができる。
【００５２】
これに対し、情報記憶装置１が落下して衝撃を受けた、いわゆる動的な場合には、図１１Ｂに示すように、第２の振動用緩衝材１６がくびれ部１６Ｂで屈曲することにより、衝撃用緩衝材１５とハードディスク駆動機構部２との間隔ｔ以上たわんで、ハードディスク駆動機構部２が衝撃用緩衝材１５と接触する。その結果、今度は衝撃用緩衝材１５が緩衝材として作用し、ハードディスク駆動機構部２に加わる加速度を充分に低下させ、高い衝撃吸収効果を得ることができる。
そして、落下後に充分に時間が経過すると、再び筺体３内は静的な状態、即ち屈曲していた第２の振動用緩衝材１６が復元して衝撃用緩衝材１５がハードディスク駆動機構部２から離間した状態に戻され、第２の振動用緩衝材１６による振動の吸収が行われるようになる。
【００５３】
本実施の形態の情報記憶装置１においては、このような仕組みが上述したように縦方向、横方向及び厚み方向の全方向にそれぞれ設けられ、ハードディスク駆動機構部２が筺体３から離間して宙吊り状態で支持されているため、３次元全方向に対して防振、耐緩衝の効果を高いレベルで得て、耐振動性、耐衝撃性を向上させることができる。
【００５４】
側面に設けられた振動用緩衝材１４には、弾性を有する部材、例えばゴムやゲル状物質等の粘弾性体やバネ等を使用することができる。ゴムは、例えば天然ゴム（ＮＲ）、イソプレンゴム（ＩＲ）、スチレンゴム（ＳＢＲ）、ブチルゴム（ＩＩＲ）、ブタジエンゴム（ＢＲ）、ニトリルゴム（ＮＢＲ）、シリコンゴム、フッ素ゴム等の種々のゴムを使用することができ、例えば内外ゴム社製のハネナイト（商品名）、イノアックコーポレーション製のポロン（商品名）等が挙げられる。一方、ゲル状物質は、シリコーンゲルのようにシリコーンを主成分としたゲル状素材を使用することができ、例えばジェルテック社製のαゲル、βゲル、θゲル（いずれも商品名）等が挙げられる。バネは、コイルバネや板バネ等の金属バネを使用することができる。
【００５５】
また、衝撃用緩衝材１５には、適度な柔らかさがあり、加速度を低下させることができればよく、基本的には振動用緩衝材１４と同様の部材、即ち弾性を有する部材、例えばゴムやゲル状物質等の粘弾性体やバネ等を使用することができる。衝撃用緩衝材１５においても、やはり温度依存性が少なく、特性が一定な材料が適するため、ゴムよりもゲル状物質を使用することが好ましく、特に広範囲な温度変化にも緩衝効果が変化しにくいシリコーンゲルを使用することが好ましい。本実施の形態においては、衝撃用緩衝材１５にシリコーンゲルを使用した。
【００５６】
尚、振動用緩衝材１４と衝撃用緩衝材１５とに異なる材料を使用する場合には、ハードディスク駆動機構部２との接触面積が、使用される材料との関係において適した大きさになるように振動用緩衝材１４と衝撃用緩衝材１５とが形成される。
【００５７】
さらに、上面及び下面に設けられた第２の振動用緩衝材１６には、一般的な板バネと同様の材料を用いて、前述した非線形の特性が得られるように、成型や加工を施した板バネを使用することができる。
【００５８】
ここで本実施の形態の情報記憶装置１の構成に対して、前述したと同様の試算を行ってみる。
図６の結果より防振の効果が現れるのはω／ωｃ＜０．２であり、車両から発生する振動（１０〜２００Ｈｚ）に対して振動しないようにする、即ち加振周波数が２００Ｈｚでも振動しないようにするためには、ω／ωｃ＝２００［Ｈｚ］／ｆ＜０．２であるから、共振周波数ｆの範囲がｆ＞１０００Ｈｚであればよい。
本実施の形態では、第２の振動用緩衝材１６が同じ上下方向に合計８つ設けられているため、１つの緩衝材１６のバネ定数を例えば５．０×１０^５［Ｎ／ｍ］とすると、全体のバネ定数はその８倍でｋ＝４．０×１０^６［Ｎ／ｍ］となる。このような緩衝材１６を用いれば、式（２）から共振周波数ｆ＝１００７＞１０００Ｈｚとなって条件を満たす。
【００５９】
尚、図６の結果は図５のモデルに基づくものであるので、情報記憶装置１の内筐体（ハードディスク駆動機構部２）の形状や第２の振動用緩衝材１６の配置によって、防振の効果が現れるω／ωｃの範囲が図６の結果から変わることがある。その場合も車両から発生する振動（加振周波数１０〜２００Ｈｚ）に対して振動しない共振周波数ｆを有するように第２の振動用緩衝材１６を選定すればよい。
【００６０】
上述の本実施の形態の情報記憶装置１の構成によれば、非線形の特性を有する板バネ１６と衝撃用緩衝材１５とを設けたことにより、静的な状態で第２の振動用緩衝材１６即ち非線形の特性を有する板バネ１６によりハードディスク駆動機構部２を支え、そのバネ定数（弾性係数）を衝撃用緩衝材１５よりも剛に即ち充分大きくすることで共振周波数を高くし、車両等実際の使用環境での振動を起こさなくすることができる。
さらに、衝撃を受けたときには、非線形の特性を有する板バネ１６がたわむと共にそのバネ定数（弾性係数）が低下するため、衝撃用緩衝材１５がハードディスク駆動機構部２と接触してその衝撃を緩衝させる働きをする。
これにより、耐衝撃性と耐振動性の両方の向上を図ることができる。
【００６１】
静的状態で非線形の特性を有する板バネ１６のバネ定数が充分大きく共振周波数が高いことにより、特に車両から発生する幅広い周波数領域の振動に対しても共振を起こさないようにすることが可能になる。
【００６２】
そして、本実施の形態によれば、振動用緩衝材１４，１６と、衝撃用緩衝材１５とを設けたことにより、それぞれに振動吸収、衝撃吸収という別個の役割を与えることができ、この役割に最適な大きさ、材料、並びに配置位置を選択して使用することができる。
これにより、衝撃吸収のための衝撃用緩衝材１５を設計する際に、緩衝材１５の共振周波数を気にすることなく、衝撃吸収の目的に対して適切なバネ定数をもった緩衝材を使用することができる。
【００６３】
尚、上述の実施の形態では、第２の振動用緩衝材（板バネ）１６から離して衝撃用緩衝材１５が設けられていたが、本発明ではこのような配置関係に限定されるものではない。
衝撃用緩衝材１５の位置については、第２の振動用緩衝材（板バネ）１６のたわみに影響を及ぼさず、かつ筺体３からハードディスク駆動機構部２に衝撃用緩衝材１５を通して振動を伝達しないようにする限りは、その他の配置としても問題ない。
特に、第２の振動用緩衝材（板バネ）１６の本来の目的が、静的な状態でハードディスク駆動機構部２を支持することであるから、この支持している状態で、衝撃用緩衝材１５が板バネ１６の曲げを拘束したり、衝撃用緩衝材１５が筺体３及びハードディスク駆動機構部２の両方と接触したりすることがなければよい。
【００６４】
第２の振動用緩衝材（板バネ）１６及び衝撃用緩衝材１５の配置を変えた他の形態を、図１２Ａ〜図１２Ｃにそれぞれ示す。
いずれの形態も、ハードディスク駆動機構部２と筐体３との間に第２の振動用緩衝材（板バネ）１６及び衝撃用緩衝材１５が設けられ、第２の振動用緩衝材（板バネ）１６がハードディスク駆動機構部２及び筐体３の一方に固定され、他方に自由端で接触するように構成されている点は共通している。
【００６５】
図１２Ａは、第２の振動用緩衝材（板バネ）１６の近くに衝撃用緩衝材１５を設けた形態である。この場合、衝撃により板バネ１６が屈曲すると、衝撃用緩衝材１５と筐体３（又はハードディスク駆動機構部２）との間に板バネ１６の自由端側が挟まれるが、それでも衝撃用緩衝材１５により衝撃が吸収されるため問題はない。
図１２Ｂは、第２の振動用緩衝材（板バネ）１６の固定端１６Ａに衝撃用緩衝材１５を取り付けた形態である。
図１２Ｃは、第２の振動用緩衝材（板バネ）１６の固定端１６Ａと対向する位置に衝撃用緩衝材１５を取り付けた形態である。
【００６６】
先の実施の形態は、特に一方向（上下方向）の共振周波数について注意を払った構成であったが、共振周波数について必要な方向に関して、それぞれ非線形の特性を有する板バネ１６と衝撃用緩衝材１５とを組み合わせることにより、その方向について共振周波数に注意を払った設計とすることができる。
【００６７】
続いて、本発明の情報記憶装置の他の実施の形態を示す。
図１３に、本発明の他の実施の形態として、情報記憶装置において、ハードディスク駆動機構部２を外側の筐体３から取り出した状態を示す。
本実施の形態では、全方向に、即ちＸＹＺの３軸方向に、振動用緩衝材として図４Ａ及び図４Ｂに示した非線形の特性を有する板バネ１６を用いた場合であり、ハードディスク駆動機構部２の四隅付近の上面、下面、並びに両側面に振動用緩衝材として非線形の特性を有する板バネ１６が設けられている。
【００６８】
この場合、衝撃用緩衝材１５については、図示しないが、前述したように静的な状態で振動を伝達しないように、ハードディスク駆動機構部２或いは筺体３の一方からは離すように設置すればよい。
【００６９】
上述の本実施の形態の構成によれば、ＸＹＺの３軸方向に、非線形の特性を有する板バネ１６を設けたことにより、これら３軸方向に対して共振周波数を高くして、例えば車両から発生する幅広い周波数領域の振動に対しても、耐振動性を向上することができる。
【００７０】
上述の各実施の形態では、振動用緩衝材の板バネ１６の板面を曲率を有する曲面１６Ｃとしていたが、板バネの板面の形状を他の構成としても良い。
板バネの板面の形状の他の形態を図１４Ａ及び図１４Ｂにそれぞれ示す。
図１４Ａは、板バネの板面を断面略Ｖ字形状とした形態である。
図１４Ｂは、板バネの板面を断面平板状として両端部を折り曲げた形態である。
【００７１】
いずれの形態にしても、衝撃を受けた際に、板バネがたわんで、静的な状態と比較して見かけのバネ定数が下がるような、非線形の特性を有するように板バネの板面を構成すればよい。
【００７２】
また、本発明では、静的な状態において所望の高い弾性係数が得られ、衝撃を受けた際には弾性係数が低下する非線形の特性を有する材料であれば、板バネ以外のものを用いて振動用緩衝材を構成してもよい。
【００７３】
さらに、図４Ｃではある値で屈折する特性曲線となっているが、本発明では、想定される使用時の振動及び衝撃時の振動に対する弾性係数がそれぞれほぼ同等であれば、弾性係数が応力の増加により徐々に低下する材料、即ち曲線的に（例えば上に凸な放物線状に）変化する特性曲線となる材料を使用することも可能である。
【００７４】
また、上述の各実施の形態では、ハードディスク駆動機構部２をシャーシ５・トップカバー６による筺体に収納された構成としたが、このハードディスク駆動機構部２が収納されたシャーシ・トップカバー等の筐体をさらに密閉構造を有する筺体内に収容した構成としてもよい。
【００７５】
本発明は、上述の実施の形態に限定されるものではなく、本発明の要旨を逸脱しない範囲でその他様々な構成が取り得る。
【００７６】
【発明の効果】
上述の本発明によれば、振動吸収、衝撃吸収のそれぞれについて高い効果を得ることができ、耐衝撃性と耐振動性の両方の向上を図ることができる。
また、本発明によれば、車両から発生する振動のような、幅広い周波数領域の振動に対しても振動吸収を行うことができる。
【図面の簡単な説明】
【図１】本発明の一実施の形態の情報記憶装置の概略構成図（分解斜視図）である。
【図２】ハードディスク駆動機構部の構成を示す図である。
Ａ　トップカバー側から見た斜視図である。
Ｂ　配線基板側から見た斜視図である。
Ｃ　内部の概略構成を示す図である。
【図３】図１の情報記憶装置において筺体の上ハーフ部を外した状態の斜視図である。
【図４】Ａ　図１の情報記憶装置の第２の振動用緩衝材の拡大図である。
Ｂ　図４ＡのＡ−Ａ´における断面図である。
Ｃ　図４Ａの第２の振動用緩衝材（板バネ）のたわみ−反力の関係を示す図である。
【図５】最適なバネ定数測定のために防振対象物の振動を測定する装置を示す図である。
【図６】図５の測定装置による測定結果を示す特性図である。
【図７】固有振動数を表すための物理モデルを示す図である。
【図８】落下衝撃を受けた対象物が壊れるかどうかの基準となるバウンダリーカーブを示す特性図である。
【図９】バネ定数と緩衝材に落下させた際に対象物が受ける最大加速度との関係を示す特性図である。
【図１０】Ａ、Ｂ　衝撃吸収時における筐体内の緩衝材の状態を説明するための模式図である。
【図１１】Ａ、Ｂ　衝撃吸収時における筐体内の緩衝材の状態を説明するための模式図である。
【図１２】Ａ〜Ｃ　第２の振動用緩衝材（板バネ）と衝撃用緩衝材の配置を変えた他の形態をそれぞれ示す図である。
【図１３】本発明の他の実施の形態の情報記憶装置におけるハードディスク駆動機構部を筐体から取り出した状態を示す図である。
【図１４】Ａ、Ｂ　板バネの板面の他の形態をそれぞれ示す断面図である。
【符号の説明】
１　情報記憶装置、２　ハードディスク駆動機構部、３　筐体、４　コネクタ、５　シャーシ、６　トップカバー、７　回転スピンドル、８　磁気ディスク、９磁気ヘッド、１０　ヘッドアーム、１１　アクチュエータ、１２　配線基板、１３　コネクタピン、１４　振動用緩衝材、１５　衝撃用緩衝材、１６　第２の振動用緩衝材（板バネ）[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a so-called external information storage device.
[0002]
[Prior art]
2. Description of the Related Art A hard disk drive (HDD) plays an important role in an information processing apparatus such as a personal computer as a recording / reproducing apparatus for writing data and programs and reading recorded data.
[0003]
The use of this HDD as a small-sized information storage device, which is a detachable extension device that is detachable from the information processing device main body as well as the information processing device main body, is being studied.
Then, such an information recording device is detached from the information processing device main body as necessary, and is carried by itself or stored separately from the information processing device main body. Furthermore, it is used by being attached to a portable device.
[0004]
When the HDD is attached to an information processing device, for example, the time of reading or writing becomes longer due to the influence of vibration or shock applied via the information processing device, or when the above-mentioned portable device is used. In some cases, the information recording device may be accidentally dropped, and the shock at the time of the drop may cause a problem such as breakage of the HDD.
[0005]
In the above-mentioned external information recording apparatus, the HDD is usually provided in a housing and provided with a cushioning material such as a sponge for the purpose of protecting from the above-mentioned shock and vibration. (For example, see Patent Document 1), but a sufficient effect has not been obtained.
[0006]
[Patent Document 1]
Japanese Patent Publication No. 6-66111
[0007]
[Problems to be solved by the invention]
Therefore, by providing a shock absorbing cushioning material and a vibration absorbing cushioning material between the outer housing (outer housing) and the inner housing (inner housing) in which the HDD is housed, the shock absorption is provided. It is conceivable to perform vibration isolation.
[0008]
In this case, in the vibration absorbing cushioning material, the resonance frequency is set to a low frequency region, and is set lower (smaller) than the frequency region of the externally applied vibration, so that the externally applied vibration resonates. Can not be.
[0009]
For example, when the purpose is to use the device indoors or to carry it when walking, the information processing apparatus is provided with the two types of cushioning materials as described above to cope with both shocks such as vibration and dropping. It becomes possible.
[0010]
On the other hand, when intended for use in a general vehicle, the vibration generated by the vehicle includes a wide frequency range from a low frequency of about 10 Hz to 200 Hz, and does not cause resonance in such an environment. In order to exhibit the effect of vibration isolation, a cushioning material (vibration isolation material) having a resonance frequency as low as 10 Hz or less is required.
However, it is not realistic to construct such a vibration isolator because a very soft material is required.
[0011]
In order to solve the above-described problems, the present invention provides an information storage device capable of greatly improving vibration resistance and shock resistance against vibration and impact from the outside of a housing.
[0012]
[Means for Solving the Problems]
An information storage device according to the present invention is detachable from a device main body, and includes a hard disk drive mechanism, a first housing that houses the hard disk drive mechanism, and the first housing inside. A second housing for accommodating the first housing; a connector portion; a first housing which is supported by the first cushion while being separated from the second housing; A second cushioning material that is in contact with only one of the second housings is disposed between the first housing and the second housing, and a plurality of first cushioning materials are provided. The cushioning material 1 includes a cushioning material having a non-linear characteristic, and the cushioning material having a non-linear characteristic has a large elastic coefficient such that it does not have resonance with respect to vibration received from the outside in a static state. , Which has the characteristic that the elastic modulus becomes smaller when subjected to impact
[0013]
According to the configuration of the information storage device of the present invention described above, the plurality of first cushioning members include the cushioning member having a non-linear characteristic, and the cushioning member having the non-linear characteristic is externally provided in a static state. By having a large elastic coefficient that does not have resonance with the received vibration, the vibration can be prevented from resonating with the vibration received from the outside due to the large elastic coefficient in a static state. On the other hand, the cushioning material having non-linear characteristics has such a characteristic that the elastic coefficient becomes small when subjected to an impact, so that it is greatly deformed when subjected to an impact. At this time, due to the deformation of the cushioning material having the non-linear characteristic, the second cushioning material that is in contact with only one of (the housing of) the first housing or the second housing is separated from the other. Since the housing comes into contact with the second cushioning material, the shock can be absorbed by the second cushioning material.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention relates to an information storage device that is detachably attached to a device main body, a hard disk drive mechanism, a first housing accommodating the hard disk drive mechanism inside, and a first housing. And a connector portion, the first housing being separated from the second housing by the first cushioning material, and the first housing being in a steady state. A second cushioning material that is in contact with only one of the housing and the second housing is provided between the first housing and the second housing, and a plurality of first cushioning materials are provided. The plurality of first shock-absorbing materials include a shock-absorbing material having a non-linear characteristic, and the shock-absorbing material having a non-linear characteristic has a large elastic coefficient that does not cause resonance in response to external vibration in a static state. Information that has the property of reducing the elastic modulus when subjected to an impact. It is a storage device.
[0015]
Further, according to the present invention, in the above-mentioned information storage device, the cushioning material having a non-linear characteristic is made of a leaf spring, and the elastic modulus changes by bending when receiving an impact.
[0016]
Further, according to the present invention, in the information storage device, the leaf spring has a narrow portion formed with a small width, and is bent at the narrow portion so as to bend when subjected to an impact.
[0017]
According to the present invention, in the information storage device, the leaf spring may be in contact with a fixed end fixed to one of the first housing and the second housing and the other housing. It has a free end that is not fixed.
[0018]
FIG. 1 shows a schematic configuration diagram (exploded perspective view) of an information storage device 1 as one embodiment of the present invention. The information storage device 1 includes a hard disk drive mechanism 2, a housing 3 accommodating the hard disk drive mechanism 2, and a connector 4.
The information storage device 1 is connected to a personal computer, a video camera, or the like (hereinafter, the information storage device 1 is connected) as an expansion device for capacity expansion or as a recording medium for recording data or programs such as a large amount of images and videos. The information storage device 1 itself is detachably connected directly to the electronic device by the connector 4 without using a cable or the like.
[0019]
The hard disk drive mechanism 2 includes a magnetic disk 8 mounted on a rotating spindle 7 as shown in FIG. 2C, and a magnetic disk 8 in a space formed by the chassis 5 and the top cover 6 shown in FIGS. 2A and 2B. On the other hand, a magnetic head 9 for recording / reproducing information and a head positioning actuator 11 supported by the magnetic head 9 via a head arm 10 are provided. In addition, a wiring board 12 on which an electronic circuit for controlling driving of each of the above-described components and controlling recording / reproducing to / from the magnetic disk 7 is mounted on the rear surface side of the chassis 5 in the hard disk drive mechanism 2. . On the wiring board 12, connector pins 13 for input / output of recording / reproducing signals to / from the magnetic head 9 and for connecting a drive power supply to a spindle motor (not shown), the actuator 11 and the like are provided on one side surface of the chassis 5. It is attached to be located.
[0020]
The housing 3 includes an upper half 3a and a lower half 3b, and the upper half 3a and the lower half 3b are formed of a synthetic resin such as plastic, for example. In the lower half 3b, one side wall, in this embodiment, a short side wall is cut out, and the connector 4 is attached to the cut out portion. The connector pins 13 of the hard disk drive mechanism 2 are connected to the connector 4 via a flexible cable (not shown) on which a power supply line and a signal line are formed.
In the information storage device 1 of the present embodiment, the connector 4 is directly connected to the connection terminal of the device main body and serves as an interface for power supply and signal transmission / reception from the device main body. Supply of driving power and transmission and reception of signals are performed.
[0021]
In the information storage device 1 according to the present embodiment, as shown in FIGS. 1 and 3, the housing 3 is disposed between the side surface of the hard disk drive mechanism 2 and the side surface of the housing 3 due to external vibration and impact. A first cushioning member 14 for absorbing vibration and a second cushioning member 15 for absorbing shock are provided in order to protect the hard disk drive mechanism 2 inside.
As described above, in the information storage device 1 of the present embodiment, two types of cushioning materials, the first cushioning material (vibration cushioning material) 14 and the second cushioning material (impact cushioning material) 15, are provided in the housing 3. And the side surface of the hard disk drive mechanism 2, respectively, for the following reason.
[0022]
That is, in vibration absorption, it is necessary to lower the natural frequency of the vibration damping material 14 to a lower frequency band in order to obtain a more vibration-proof effect and improve the vibration resistance of the information storage device 1. . The natural frequency of the vibration damper 14 can be increased by increasing the weight of the hard disk drive mechanism 2 itself, which is the object to which the vibration damping effect is to be provided, or by reducing the size of the vibration damper 14. The apparent frequency of the driving mechanism 2, that is, the ratio of the weight of the hard disk driving mechanism 2 to the size of the vibration damping material 14 may be increased to lower the frequency band. . Actually, increasing the weight of the hard disk drive mechanism 2 leads to an increase in product weight, which is not preferable and is not practical. Therefore, by reducing the size of the vibration damping material 14, the vibration damping material 14 is reduced. Will be lowered to a lower frequency band.
[0023]
On the other hand, in the case of shock absorption, if a shock absorbing material that is too small is used as the shock absorbing material 15, the shock absorbing material 15 will be completely crushed when receiving an impact from outside the housing 3, and the spring constant of the shock absorbing material 15 will be reduced. Becomes almost the same as the spring constant of the rigid body. For this reason, in the case of the shock buffer material 15 that is too small, the same shock that comes into contact with the housing 3 is transmitted to the hard disk drive mechanism 2 in extreme cases. In this case, the shock absorbing material becomes meaningless. Therefore, in order to obtain a high shock absorbing effect and improve the shock resistance of the information storage device 1, a larger shock absorbing material should be used in the shock absorbing material 15. Is required.
[0024]
Further, the cushioning material used for absorbing vibration and the cushioning material used for absorbing shock have different spring constants (elastic coefficients) that are optimal for obtaining the effect of vibration damping and shock absorption. The optimum spring constant of the vibration damper 14 was determined as follows. First, as shown in FIG. 5, a vibration damping material 14 is arranged on a vibration table T, an object X for which an effect of vibration isolation is desired to be placed thereon, and vibration is applied to the vibration table T. The vibration of the object X is measured. FIG. 6 shows the measurement results.
[0025]
In the characteristic diagram shown in FIG. 6, the vibration is displayed in a dimensionless manner, and the vertical axis represents the acceleration of the object X (output acceleration amplitude: Gout) and the input acceleration of the excitation table T (input acceleration amplitude: Gin). The horizontal axis represents the ratio of the excitation frequency (input frequency: ω) / the primary natural frequency of the vibration damping material 14 (natural frequency: ωc). As can be seen from FIG. 6, as the excitation frequency approaches the natural frequency, that is, as the value on the horizontal axis approaches 1, the ratio of Gout / Gin increases, and the value on the horizontal axis becomes 1, ie, the excitation oscillation It peaks at the point where the number and the natural frequency are the same. Then, as the excitation frequency becomes higher than the natural frequency, the ratio of Gout / Gin decreases. This phenomenon applies to all general vibration damping materials. In the case of the vibration damping material, when the ratio of Gout / Gin is 1 or less, the effect of vibration damping can be obtained. For this reason, by setting the natural frequency ωc of the vibration damping material 14 as small as possible and by setting the frequency at which the excitation frequency ω and the natural frequency ωc are the same as each other, a wider frequency range can be obtained. It can be seen that the effect of vibration isolation can be obtained.
[0026]
The above-mentioned natural frequency ωc is expressed by the following equation when considering a physical model where the mass of the weight (object X) as shown in FIG. 7 is m and the spring constant of the vibration damping material 14 is k. It is represented by equation (1) shown in Equation 1.
[0027]
(Equation 1)

[0028]
From equation (1), it can be seen that the smaller the spring constant k is, the smaller the natural frequency ωc is. Therefore, in the vibration damping material 14, the smaller the spring constant k is, the wider the frequency range becomes. Thus, an anti-vibration effect can be obtained.
[0029]
On the other hand, in shock absorption, an optimal spring constant was determined by using a boundary curve as a reference for determining whether or not a target object was broken when it received a drop impact. In the boundary curve shown in FIG. 8, the horizontal axis represents the speed change (velocity change) received by the object, the vertical axis represents the acceleration (Acceleration) received by the object, and the range indicated by region A in the figure is the range of the object. Is the range of the speed change and acceleration of the drop impact that breaks. As can be seen from FIG. 8, in order to prevent a certain object from being broken when subjected to a drop impact, the speed change and acceleration due to the drop impact must be within the range of the area B in the figure, specifically, the speed change. It is necessary to reduce the acceleration or the acceleration.
[0030]
In general, the cushioning material prevents the object from being broken by reducing the impact acceleration received by the object by using the cushioning property. For this reason, in order to obtain a large shock absorbing effect, what value is taken as the spring constant k of the shock absorbing material 15 obtained by using the physical model (FIG. 7) of the vibration absorbing material 14 again. The problem is whether the acceleration becomes the smallest. Therefore, FIG. 9 shows a characteristic diagram in which a plurality of spring constants k (k1 to k4) are plotted on the horizontal axis, and the maximum acceleration received by the object when dropped on a buffer material having a spring constant on the horizontal axis is plotted on the vertical axis. . When the spring constant k of the shock-absorbing material 15 is the smallest (k1), the shock-absorbing material 15 is too soft against the received shock, and the shock-absorbing material 15 is completely crushed, and the maximum acceleration increases. Conversely, when the spring constant of the shock-absorbing material 15 is the largest (k4), the cushioning material is too hard and has no cushioning property, and the maximum acceleration also becomes large. As can be seen from FIG. 9, there is an optimum k for minimizing the acceleration between the smallest spring constant k1 and the largest spring constant k4. In FIG. 9, there is a spring constant k3. Means that the highest shock absorbing effect can be obtained.
[0031]
For this reason, the size and spring constant of the cushioning material that can provide the highest effect are different between the shock absorbing cushioning material and the shock absorbing cushioning material. It is difficult to achieve both impact absorption. For this reason, in the information storage device 1, two types of cushioning materials having different sizes and spring constants and having a shock absorbing material 14 suitable for absorbing vibration and a shock absorbing material 15 suitable for absorbing shock are respectively provided in the housing. 3 are arranged.
As described above, in the information storage device 1, by separately providing the shock-absorbing cushioning material and the shock-absorbing cushioning material, the shock-absorbing material having the optimal size and spring constant in each of the vibration absorption and the shock absorption. A material can be selected and used, and a high effect can be obtained in each of vibration isolation and shock absorption, and vibration resistance and impact resistance can be improved.
[0032]
As shown in FIG. 3, the above-described vibration damping material 14 has a substantially truncated cone shape, and an end surface on the small diameter portion side is provided between the side surface of the hard disk drive mechanism 2 and the side surface of the housing 3. The large-diameter portion side end faces are arranged so as to be in contact with the hard disk drive mechanism 2 respectively. The vibration dampers 14 are arranged on four side surfaces of the hard disk drive mechanism 2 and are arranged near both ends of these side surfaces.
[0033]
However, when the vibration damping material is constituted only by the vibration damping material 14 having the substantially truncated cone shape, the spring constant (elastic coefficient) becomes substantially constant. Therefore, it becomes difficult to perform vibration proof against vibration in a wide frequency range (10 to 200 Hz) generated from the vehicle.
[0034]
Here, a trial calculation is actually performed.
For example, in the range shown in FIG. 6, the effect of the image stabilization appears in a portion where the output acceleration is smaller than the input acceleration, that is, in a portion where the value on the vertical axis is Gout / Gin <1, and ω on the horizontal axis. /Ωc>1.4 (ω: excitation frequency (input frequency), ωc: resonance frequency (natural frequency)).
The resonance frequency ωc when the object having the mass m is supported by the spring constant k is calculated by Expression 1.
[0035]
Since there is a relationship of ωc = 2πf between the resonance frequency ωc and the resonance frequency f, the following expression (2) holds for the spring constant k together with the expression (1).
k = mωc ² = M · (2πf) ² (2)
Next, assuming that the mass of the hard disk drive mechanism section 2 is 0.1 kg, the hard disk drive mechanism section 2 does not vibrate with respect to vibration (10 to 200 Hz) generated from the vehicle, that is, does not vibrate even if the vibration frequency is 10 Hz. To determine the spring constant k. From the results of FIG. 6, since ω / ωc = 10 [Hz] / f> 1.4, the range of the resonance frequency f is
f <7.14
It becomes. When this range is applied to equation (2),
k <201 [N / m]
It becomes. At this time, the amount of deflection x of the spring (vibration cushioning member 14) can be obtained from the mass w of the hard disk drive mechanism 2.

It becomes.
Therefore, it is understood that a very soft vibration damping material 14 that bends by 4.9 mm by its own weight of the hard disk drive mechanism unit 2 is required, but the gap in which the vibration damping material 14 is provided is only about several mm. Therefore, it is almost impossible to bend by 4.9 mm, and such a cushioning material cannot be used.
[0036]
Therefore, in the information storage device 1 according to the present embodiment, the spring constant (elasticity coefficient) of the vibration damping material is not reduced to actively perform the vibration damping, but the output becomes 1 with respect to the input. In other words, in a state where ω / ωc <1, it is possible to support the hard disk drive mechanism 2 so as not to cause resonance, and to make the shock absorbing material 15 act to absorb a shock when receiving a shock. Thus, it constitutes a vibration damping material.
[0037]
From the results of FIG. 6, it is about ω / ωc <0.2 that resonance does not occur in the state where ω / ωc <1. Therefore, resonance that is sufficiently large for an excitation frequency ω that satisfies this condition is satisfied. A cushioning material having a frequency ωc, that is, a cushioning material having a sufficiently large spring constant (elastic coefficient) k is used as a vibration damping material.
[0038]
Specifically, between the upper surface of the hard disk drive mechanism 2 on the top cover 6 side and the top plate of the housing 3, and between the lower surface of the hard disk drive mechanism 2 on the wiring board 12 side and the bottom plate of the housing 3 The information storage device 1 is configured by disposing a second vibration damper 16 made of a leaf spring.
As shown in FIGS. 1 and 3, the second vibration damping material 16 is provided on the upper surface and the lower surface of the hard disk drive mechanism 2 near four corners of each surface.
[0039]
FIG. 4A shows an enlarged view of the second vibration damping material 16. FIG. 4B is a cross-sectional view taken along line AA ′ of FIG. 4A.
As shown in FIGS. 4A and 4B, the second vibration damping member 16 is formed of a leaf spring having a curved surface 16C having a curved surface instead of a flat surface.
This is intended to make the relationship between the deflection and the reaction force when the leaf spring 16 bends due to an impact or the like non-linear.
[0040]
In the middle of the plate surface of the leaf spring 16, a narrow portion 16B having a reduced width is provided. The provision of the constricted portion 16B causes the leaf spring 16 to bend at the narrowed and weakest constricted portion 16B when an impact is applied. That is, the position where the leaf spring 16 bends when an impact is applied can be restricted by the constricted portion 16B. When the leaf spring 16 is largely bent by the constricted portion 16B, the height at the time of bending can be suppressed as low as possible. Therefore, the shock absorbing material 15 contacts the hard disk drive mechanism 2 to absorb the shock. Can be.
[0041]
Further, one end (the right end in the drawing) of the leaf spring 16 has a hole 17 for fastening with a screw or the like, and serves as a fixed end 16A fixed to the hard disk drive mechanism 2. (Left end in the figure) is a free end that is not fixed without a hole.
Since the other end is a free end as described above, it can contact the housing 3 and support the hard disk drive mechanism 2 in a static state. On the other hand, when an impact is applied, it is possible to bend well at the constricted portion 16B, and the impact can be reduced by moving the contact point with the housing 3.
If both ends of the leaf spring are fixed, a large force is applied to the plate surface of the leaf spring when an impact is applied, and the impact may be transmitted to the hard disk drive mechanism 2 without being bent well at the constricted portion 16B. .
[0042]
Here, as a characteristic of the leaf spring 16, a relationship between deflection (push displacement) -reaction force (push force) is shown in FIG. 4C.
As shown in FIG. 4C, the relationship between the deflection and the reaction force is not linear, the first state in which the indentation displacement is u1 or less and the apparent spring constant (the inclination of the line in FIG. 4C) is k1, and the indentation displacement is u1 or more. In this case, the apparent spring constant is k2 (<k1), that is, a second state in which the spring constant sharply decreases, and two states having different characteristics.
[0043]
When the leaf spring 16 has such characteristics (non-linear characteristics), only the gravity of the hard disk drive mechanism 2 is applied in a static state where the information storage device 1 is stationary, so that the load is small. It is in the first state and is supported by a strong spring constant k1. The resonance frequency ωc at this time is calculated from Expression (2), and is in a frequency region higher than the region (10 to 200 Hz) of the excitation frequency ω generated in a general vehicle, for example. Vibration is transmitted as it is.
On the other hand, when a drop impact or the like is applied, an acceleration exceeding several hundred G is applied, so that the load F applied to the leaf spring 16 increases instantaneously (F = ma, m: mass, a: acceleration). It becomes several hundred G or more. At this time, the leaf spring 16 shifts to the second state with a small spring constant k2 and the deflection increases, so that the hard disk drive mechanism 2 comes into contact with the shock absorbing material 15, and the shock absorbing material 15 absorbs the shock. Is performed.
[0044]
In the information storage device 1 of the present embodiment, the hard disk drive mechanism 2 is suspended from the housing 3 by a plurality of vibration dampers 14 and 16 so as to be suspended.
[0045]
The shock-absorbing material 15 is provided in a space between the hard disk drive mechanism 2 and the housing 3 supported by the vibration-absorbing materials 14 and 16 apart from the housing 3 in a steady state, that is, with respect to the information storage device 1. In a state where neither vibration nor shock is applied, it is disposed so as to be in contact with only one of the hard disk drive mechanism 2 and the housing 3.
In the present embodiment, the shock-absorbing material 15 is in contact with only the housing 3 and is arranged at a predetermined distance from the hard disk drive mechanism 2. Alternatively, the shock absorbing material 15 may be in contact with only the hard disk drive mechanism 2 and disposed at a predetermined distance from the housing 3.
[0046]
The shock-absorbing material 15 has a flat plate shape, and is provided at least one sheet at a position facing a substantially central portion with respect to a side surface of the hard disk drive mechanism 2. It has a larger volume than the vibration damping material 14 provided on the side surface, and also has a contact area with the hard disk drive mechanism 2 when the information storage device 1 receives an impact as described later. 14 is larger than the contact area with the hard disk drive mechanism 2.
[0047]
In addition, the shock-absorbing material 15 is disposed on the upper surface and the lower surface of the hard disk drive mechanism 2 at positions opposed to the vicinity of each of these sides, and has a second vibration-absorbing material 16. It is provided avoiding the part. For this reason, the shock absorbing material 15 is formed long on the short sides of the upper half 3a and the lower half 3b of the housing 3, whereas the shock absorbing material is formed on the long sides of the upper half 3a and the lower half 3b. 15 is formed short.
[0048]
The contact area between the vibration buffer 14 and the shock buffer 15 with respect to the hard disk drive mechanism 2 is the same because the vibration buffer 14 and the shock buffer 15 use the same material in the present embodiment. As described above, that is, the contact area of the shock absorbing material 15 is larger than the contact area of the vibration absorbing material 14.
However, when different materials are used for the vibration damping material 14 and the shock damping material 15 as described later, the size of the contact area does not always have the above-described relationship, and the material used is And a suitable contact area.
[0049]
The operation of absorbing shock in the horizontal direction of the information storage device 1 of the present embodiment in which the vibration cushioning member 14 and the shock cushioning member 15 are arranged as described above will be described with reference to FIG. FIG. 10A shows a static state of the hard disk drive mechanism 2, the housing 3, the vibration damping material 14 and the shock absorbing material 15 in the information storage device 1, for example, the information storage device 1 is installed, and only weak vibration is generated. It is a figure which shows each positional relationship in the state which is transmitted typically. In such a static state, only the vibration damping member 14 is in contact with the hard disk drive mechanism 2 and acts as a damping member, so that a high vibration damping effect can be obtained.
[0050]
On the other hand, in the case of a so-called dynamic case where the information storage device 1 is dropped and receives an impact, as shown in FIG. 10B, the shock absorbing material 14 is And the hard disk drive mechanism 2 comes into contact with the shock absorbing material 15. As a result, the shock absorbing material 15 acts as a shock absorbing material, and the acceleration applied to the hard disk drive mechanism 2 is sufficiently reduced, so that a high shock absorbing effect can be obtained.
When a sufficient time has elapsed after the fall, the inside of the housing 3 is returned to a static state, that is, the state in which the shock-absorbing material 15 is separated from the hard disk drive mechanism 2, and the vibration of only the vibration-absorbing material 14 is reduced. Absorption will take place.
[0051]
Similarly, the effect of absorbing shock in the vertical direction of the information storage device 1 of the present embodiment in which the second vibration damping material 16 and the shock damping material 15 are arranged as described above will be described with reference to FIG. explain. FIG. 11A shows a static state of the hard disk drive mechanism 2, the housing 3, the second vibration damping material 16 and the shock damping material 15 in the information storage device 1, for example, the information storage device 1 is installed and is weak. It is a figure which shows typically each positional relationship in the state where only vibration is transmitted. In such a static state, only the second vibration damper 16 is in contact with (fixed to) the hard disk drive mechanism 2 and acts as a shock absorber, and the second vibration damper 16 is high. Since it has an elastic coefficient, a high vibration-proof effect can be obtained.
[0052]
On the other hand, in a so-called dynamic case where the information storage device 1 is dropped and receives an impact, as shown in FIG. 11B, the second vibration damping material 16 is bent at the constricted portion 16B, The hard disk drive mechanism 2 comes into contact with the shock buffer 15 with a deflection of at least the distance t between the shock buffer 15 and the hard disk drive mechanism 2. As a result, the shock absorbing material 15 acts as a shock absorbing material, and the acceleration applied to the hard disk drive mechanism 2 is sufficiently reduced, so that a high shock absorbing effect can be obtained.
When a sufficient time has elapsed after the fall, the inside of the housing 3 is again in a static state, that is, the bent second vibration damper 16 is restored, and the shock damper 15 is moved from the hard disk drive mechanism 2. The state is returned to the separated state, and the vibration is absorbed by the second vibration damping material 16.
[0053]
In the information storage device 1 of the present embodiment, such a mechanism is provided in each of the vertical direction, the horizontal direction, and the thickness direction as described above, and the hard disk drive mechanism 2 is separated from the housing 3 and suspended in the air. Since it is supported in a state, it is possible to obtain a high level of anti-vibration and anti-buffer effects in all three-dimensional directions, thereby improving anti-vibration and anti-shock properties.
[0054]
As the vibration damping member 14 provided on the side surface, a member having elasticity, for example, a viscoelastic body such as rubber or a gel-like substance, a spring, or the like can be used. Examples of the rubber include various rubbers such as natural rubber (NR), isoprene rubber (IR), styrene rubber (SBR), butyl rubber (IIR), butadiene rubber (BR), nitrile rubber (NBR), silicon rubber, and fluorine rubber. Examples thereof include Honey Night (trade name) manufactured by Naigai Rubber Co. and Polon (trade name) manufactured by Inoac Corporation. On the other hand, as the gel-like substance, a gel-like material containing silicone as a main component such as a silicone gel can be used. For example, α-gel, β-gel, and θ-gel (all of which are trade names) manufactured by Geltech Co., Ltd. No. As the spring, a metal spring such as a coil spring or a leaf spring can be used.
[0055]
Further, the shock absorbing material 15 may have a moderate softness and can reduce the acceleration, and is basically the same as the vibration damping material 14, that is, a member having elasticity, for example, rubber or gel. A viscoelastic body such as a state substance, a spring, or the like can be used. Also in the shock absorbing material 15, since a material having a low temperature dependency and a constant property is suitable, it is preferable to use a gel-like substance rather than a rubber, and the buffer effect is hard to change even in a wide range of temperature change. Preferably, a silicone gel is used. In the present embodiment, a silicone gel is used for the shock absorbing material 15.
[0056]
When different materials are used for the vibration damping material 14 and the shock damping material 15, the contact area with the hard disk drive mechanism 2 is set to an appropriate size in relation to the material used. A vibration damping material 14 and a shock damping material 15 are formed in the fin.
[0057]
Further, the second vibration damping material 16 provided on the upper surface and the lower surface was molded and processed using the same material as a general leaf spring so as to obtain the above-described non-linear characteristics. A leaf spring can be used.
[0058]
Here, the same trial calculation as described above will be performed on the configuration of the information storage device 1 of the present embodiment.
The result of FIG. 6 shows that ω / ωc <0.2 at which the vibration-proof effect appears, so that vibration is not generated with respect to the vibration (10 to 200 Hz) generated from the vehicle, that is, even if the vibration frequency is 200 Hz. To avoid this, since ω / ωc = 200 [Hz] / f <0.2, the range of the resonance frequency f should be f> 1000 Hz.
In the present embodiment, since a total of eight second vibration dampers 16 are provided in the same vertical direction, the spring constant of one damper 16 is, for example, 5.0 × 10 ⁵ [N / m], the overall spring constant is eight times that and k = 4.0 × 10 ⁶ [N / m]. If such a buffer 16 is used, the resonance frequency f = 1007> 1000 Hz is satisfied from the equation (2), which satisfies the condition.
[0059]
Since the result of FIG. 6 is based on the model of FIG. 5, vibration isolation is performed by the shape of the inner housing (hard disk drive mechanism 2) of the information storage device 1 and the arrangement of the second vibration damping material 16. The range of .omega ./. Omega.c in which the effect of (1) appears may change from the result of FIG. In this case as well, the second vibration damping material 16 may be selected so as to have a resonance frequency f that does not vibrate with respect to vibration (excitation frequency of 10 to 200 Hz) generated from the vehicle.
[0060]
According to the configuration of the information storage device 1 of the present embodiment described above, the provision of the leaf spring 16 having the non-linear characteristic and the shock absorbing material 15 allows the second vibration damping material to be in a static state. That is, the hard disk drive mechanism 2 is supported by a leaf spring 16 having a non-linear characteristic, and its spring constant (elastic coefficient) is made rigidly, that is, sufficiently larger than that of the shock-absorbing material 15, to increase the resonance frequency, thereby increasing the resonance frequency. Vibration in an actual use environment can be prevented.
Further, when an impact is received, the leaf spring 16 having a non-linear characteristic bends and its spring constant (elastic coefficient) decreases, so that the shock absorbing material 15 comes into contact with the hard disk drive mechanism 2 to absorb the impact. Work to make it work.
Thereby, both the impact resistance and the vibration resistance can be improved.
[0061]
Since the spring constant of the leaf spring 16 having a non-linear characteristic in a static state is sufficiently large and the resonance frequency is high, it is possible to prevent resonance from occurring particularly in a wide frequency range vibration generated from a vehicle. Become.
[0062]
According to the present embodiment, the vibration dampers 14 and 16 and the shock damper 15 are provided, so that they can be given separate roles of vibration absorption and shock absorption, respectively. The optimal size, material, and arrangement position can be selected and used.
Thus, when designing the shock absorbing material 15 for absorbing the shock, a shock absorbing material having an appropriate spring constant for the purpose of absorbing the shock can be used without concern for the resonance frequency of the shock absorbing material 15. can do.
[0063]
In the above-described embodiment, the shock absorbing material 15 is provided apart from the second vibration damping material (leaf spring) 16, but the present invention is not limited to such an arrangement. Absent.
The position of the shock absorbing material 15 does not affect the deflection of the second vibration damping material (leaf spring) 16 and does not transmit vibration from the housing 3 to the hard disk drive mechanism 2 through the shock damping material 15. As long as this is done, there is no problem with other arrangements.
In particular, the original purpose of the second vibration damping material (leaf spring) 16 is to support the hard disk drive mechanism 2 in a static state. It is only necessary that the 15 does not restrict the bending of the leaf spring 16 and that the shock absorbing material 15 does not contact both the housing 3 and the hard disk drive mechanism 2.
[0064]
12A to 12C show other forms in which the arrangement of the second vibration damping material (leaf spring) 16 and the shock absorbing material 15 is changed.
In any of the embodiments, a second vibration damping material (leaf spring) 16 and a shock damping material 15 are provided between the hard disk drive mechanism 2 and the housing 3, and the second vibration damping material (leaf spring) is provided. ) 16 is fixed to one of the hard disk drive mechanism 2 and the housing 3 and is configured to contact the other at a free end.
[0065]
FIG. 12A shows a form in which a shock absorbing material 15 is provided near a second vibration damping material (leaf spring) 16. In this case, when the leaf spring 16 is bent by an impact, the free end side of the leaf spring 16 is sandwiched between the impact buffer 15 and the housing 3 (or the hard disk drive mechanism 2). There is no problem because the shock is absorbed by the.
FIG. 12B shows a form in which the shock absorbing material 15 is attached to the fixed end 16A of the second vibration damping material (leaf spring) 16.
FIG. 12C shows a form in which the shock absorbing material 15 is attached to a position facing the fixed end 16A of the second vibration damping material (leaf spring) 16.
[0066]
In the above-described embodiment, the configuration pays particular attention to the resonance frequency in one direction (vertical direction). However, the leaf spring 16 and the shock absorbing material each having nonlinear characteristics with respect to the direction required for the resonance frequency. 15 can be designed to pay attention to the resonance frequency in that direction.
[0067]
Next, another embodiment of the information storage device of the present invention will be described.
FIG. 13 shows, as another embodiment of the present invention, a state where the hard disk drive mechanism 2 is taken out of the outer casing 3 in the information storage device.
In the present embodiment, the leaf spring 16 having the non-linear characteristics shown in FIGS. 4A and 4B is used as a vibration damping material in all directions, that is, in three XYZ directions. Plate springs 16 having non-linear characteristics as vibration dampers are provided on the upper surface, lower surface, and both side surfaces near the four corners of No. 2.
[0068]
In this case, the shock-absorbing material 15 is not shown, but may be installed away from the hard disk drive mechanism 2 or one of the housings 3 so as not to transmit vibration in a static state as described above. .
[0069]
According to the configuration of the present embodiment described above, by providing the leaf springs 16 having non-linear characteristics in the three axial directions of XYZ, the resonance frequency is increased in these three axial directions. Vibration resistance can be improved even with respect to the generated vibration in a wide frequency range.
[0070]
In each of the above-described embodiments, the plate surface of the leaf spring 16 of the vibration damping material is a curved surface 16C having a curvature, but the plate spring may have another shape.
14A and 14B show other forms of the plate surface shape of the leaf spring.
FIG. 14A shows a form in which the plate surface of the leaf spring has a substantially V-shaped cross section.
FIG. 14B shows a form in which the plate surface of the leaf spring is made flat in cross section and both ends are bent.
[0071]
In any case, when a shock is applied, the leaf surface of the leaf spring is bent so as to have a non-linear characteristic such that the leaf spring bends and an apparent spring constant is reduced as compared with a static state. What is necessary is just to comprise.
[0072]
Further, in the present invention, a material other than a leaf spring can be used as long as the material has a non-linear characteristic in which a desired high elastic modulus is obtained in a static state and the elastic modulus is reduced when subjected to an impact. A vibration damping material may be configured.
[0073]
Further, in FIG. 4C, the characteristic curve is refracted at a certain value. However, in the present invention, if the elastic coefficients for the assumed use vibration and the shock vibration are substantially equal to each other, the elastic coefficient becomes It is also possible to use a material that gradually decreases with increasing, that is, a material that has a characteristic curve that changes in a curvilinear manner (for example, in the shape of an upwardly convex parabola).
[0074]
Further, in each of the above-described embodiments, the hard disk drive mechanism 2 is housed in the housing including the chassis 5 and the top cover 6. However, the chassis such as the chassis / top cover in which the hard disk drive mechanism 2 is housed. The body may be further housed in a housing having a closed structure.
[0075]
The present invention is not limited to the above-described embodiment, and may take various other configurations without departing from the gist of the present invention.
[0076]
【The invention's effect】
According to the present invention described above, a high effect can be obtained for each of vibration absorption and shock absorption, and both impact resistance and vibration resistance can be improved.
Further, according to the present invention, it is possible to absorb vibrations even in vibrations in a wide frequency range, such as vibrations generated from a vehicle.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram (exploded perspective view) of an information storage device according to an embodiment of the present invention.
FIG. 2 is a diagram showing a configuration of a hard disk drive mechanism.
FIG. 2A is a perspective view as viewed from the top cover side.
B is a perspective view seen from the wiring board side.
It is a figure showing the schematic structure inside C.
FIG. 3 is a perspective view of the information storage device of FIG. 1 in a state where an upper half portion of a housing is removed.
FIG. 4A is an enlarged view of a second vibration damper of the information storage device of FIG. 1;
B It is sectional drawing in AA 'of FIG. 4A.
FIG. 4C is a diagram showing a relationship between the deflection and the reaction force of the second vibration damping material (leaf spring) of FIG. 4A.
FIG. 5 is a diagram showing an apparatus for measuring vibration of an object to be damped for optimal measurement of a spring constant.
FIG. 6 is a characteristic diagram showing a result of measurement by the measuring device of FIG. 5;
FIG. 7 is a diagram showing a physical model for representing a natural frequency.
FIG. 8 is a characteristic diagram showing a boundary curve serving as a reference for determining whether an object subjected to a drop impact is broken.
FIG. 9 is a characteristic diagram showing a relationship between a spring constant and a maximum acceleration applied to an object when the object is dropped on a cushioning material.
FIGS. 10A and 10B are schematic diagrams for explaining a state of a cushioning material in a housing when a shock is absorbed.
FIGS. 11A and 11B are schematic diagrams for explaining a state of a cushioning material in a housing at the time of absorbing a shock.
12A to 12C are diagrams showing other forms in which the arrangement of a second vibration damping material (leaf spring) and a shock absorbing material is changed.
FIG. 13 is a diagram illustrating a state in which a hard disk drive mechanism in an information storage device according to another embodiment of the present invention is removed from a housing.
14A and 14B are cross-sectional views showing other forms of the plate surface of the leaf springs.
[Explanation of symbols]
REFERENCE SIGNS LIST 1 information storage device, 2 hard disk drive mechanism unit, 3 housing, 4 connectors, 5 chassis, 6 top cover, 7 rotating spindle, 8 magnetic disk, 9 magnetic head, 10 head arm, 11 actuator, 12 wiring board, 13 connector Pin, 14 Vibration buffer, 15 Impact buffer, 16 Second vibration buffer (leaf spring)

Claims (4)

An information storage device that is detachable from a device body,
A hard disk drive mechanism,
A first housing accommodating the hard disk drive mechanism therein;
A second housing accommodating the first housing therein;
With a connector part,
The first housing is supported by the first cushion member so as to be separated from the second housing, and only one of the first housing and the second housing in a steady state. A second cushioning material that is in contact with the first housing and the second housing;
A plurality of the first cushioning materials are provided, and the plurality of first cushioning materials include a cushioning material having a non-linear characteristic;
The cushioning material having the above non-linear characteristic has such a large elastic coefficient that it does not have resonance in response to vibrations received from the outside in a static state, and has a characteristic that the elastic coefficient becomes small when subjected to an impact. An information storage device, comprising: 2. The information storage device according to claim 1, wherein the cushioning material having the non-linear characteristic is made of a leaf spring, and the elastic coefficient changes by bending when receiving an impact. 3. The information storage device according to claim 2, wherein the leaf spring has a narrow portion formed to have a small width, and bends when receiving an impact by bending at the narrow portion. The leaf spring has a fixed end fixed to one of the first and second housings and a free end that is in contact with the other housing but is not fixed. 3. The information storage device according to claim 2, comprising:

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