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JP2744114B2 - Multi-frequency superimposed magnetic recording method and magnetic recording medium for multi-frequency superimposed magnetic head recording - Google Patents

Multi-frequency superimposed magnetic recording method and magnetic recording medium for multi-frequency superimposed magnetic head recording

Info

Publication number
JP2744114B2
JP2744114B2 JP2122698A JP12269890A JP2744114B2 JP 2744114 B2 JP2744114 B2 JP 2744114B2 JP 2122698 A JP2122698 A JP 2122698A JP 12269890 A JP12269890 A JP 12269890A JP 2744114 B2 JP2744114 B2 JP 2744114B2
Authority
JP
Japan
Prior art keywords
magnetic
layer
magnetic layer
recording
recording medium
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Expired - Lifetime
Application number
JP2122698A
Other languages
Japanese (ja)
Other versions
JPH0419815A (en
Inventor
正憲 一色
寿彦 小口
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Toshiba Corp
Original Assignee
Toshiba Corp
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Filing date
Publication date
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Priority to JP2122698A priority Critical patent/JP2744114B2/en
Publication of JPH0419815A publication Critical patent/JPH0419815A/en
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Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

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  • Magnetic Record Carriers (AREA)
  • Recording Or Reproducing By Magnetic Means (AREA)

Description

【発明の詳細な説明】 [発明の目的] (産業上の利用分野) 本発明は、短波長域から長波長域まで広範囲な波長領
域において高い再生出力が得られる高密度記録の可能な
多周波重畳磁気記録方式に関する。
DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention relates to a multi-frequency capable of high-density recording capable of obtaining a high reproduction output in a wide wavelength range from a short wavelength range to a long wavelength range. The present invention relates to a superposition magnetic recording system.

(従来の技術) 近年、磁気記録媒体は、オーディオ用、ビデオ用、コ
ンピュータ用などの様々な分野において大量の情報を記
録する記録媒体として多用されるようになって来てい
る。しかして、このような磁気記録において、たとえば
ビデオなど明暗に係る高周波信号に、たとえばカラーや
オーディオなど複数の低周波信号を重畳して記録する方
式が注目されている。
(Prior Art) In recent years, magnetic recording media have been widely used as recording media for recording a large amount of information in various fields such as audio, video, and computer fields. In such magnetic recording, attention has been paid to a method of superposing a plurality of low-frequency signals, such as color and audio, on a high-frequency signal relating to light and dark, such as video, for example, for recording.

このような高周波信号および低周波信号の重畳記録方
式においては、たとえば超微粒子状の六方晶系強磁性粉
末または金属磁性粉末や酸化物磁性粉末などの針状強磁
性粉末を用いて得られた磁気記録媒体が一般的に用いら
れている。しかし、六方晶系強磁性粉末を用いて形成し
た場合、記録波長が1μm以下程度の短波長域において
高い再生出力が得られる半面、長波長域の信号を短波長
信号に重畳して記録する場合において、その長波長信号
について高い再生出力が得られないという特性を有して
いることが判明している。このため、たとえばVTR用テ
ープのように音声信号やカラー信号のような長波長域の
信号を、短波長域のビデオ信号に重畳して記録再生を行
う場合には、充分な記録が困難になるという問題があっ
た。
In such a superposition recording method of a high frequency signal and a low frequency signal, for example, a magnetic material obtained by using an ultrafine hexagonal ferromagnetic powder or a needle-shaped ferromagnetic powder such as a metal magnetic powder or an oxide magnetic powder is used. Recording media are commonly used. However, when formed using hexagonal ferromagnetic powder, when a recording wavelength is about 1 μm or less, a high reproduction output can be obtained in a short wavelength range, while a signal in a long wavelength range is superimposed on a short wavelength signal for recording. , It has been found that such a long wavelength signal has a characteristic that a high reproduction output cannot be obtained. For this reason, when recording and reproducing a signal in a long wavelength range such as an audio signal or a color signal, such as a VTR tape, on a video signal in a short wavelength range, sufficient recording becomes difficult. There was a problem.

一方、針状強磁性粉末を用いて形成した場合、音声信
号やカラー信号のような長波長域信号の重畳記録再生に
は良好であるが、ビデオ信号など短波長域において高い
再生出力が得られないという問題がある。
On the other hand, when formed using acicular ferromagnetic powder, it is good for superposition recording and reproduction of long wavelength band signals such as audio signals and color signals, but high reproduction output is obtained in short wavelength bands such as video signals. There is no problem.

このような欠点を補うための一手段として、金属磁性
粉末や酸化物磁性粉末など、針状強磁性粉末による磁性
体層を2層に形成し、上層をビデオ用など短波長域信号
の記録・再生に、また下層をオーディオ用など長波長域
信号の重畳記録・再生に使い分けし得る磁気記録媒体を
用いることが試みられている。しかし、この場合、記録
再生特性に対する2層構造の有効性について明確にはさ
れていない現状にある。
As a means for compensating for such a defect, two magnetic layers made of acicular ferromagnetic powder such as metal magnetic powder and oxide magnetic powder are formed, and the upper layer is used for recording short wavelength signals such as for video. Attempts have been made to use a magnetic recording medium that can be used selectively for reproduction, and for the lower layer for superimposed recording and reproduction of long wavelength signals such as for audio. However, in this case, the effectiveness of the two-layer structure with respect to the recording / reproducing characteristics has not yet been clarified.

(発明が解決しようとする課題) 本発明者らは、高周波信号に複数の低周波信号を重畳
して記録する方式に、前記針状強磁性粉末を主体とする
第1の磁性体層および六方晶系強磁性粉を主体とする第
2の磁性体層を備えた2層構造の磁気記録媒体を適用
し、第2の磁性体層の厚さを一定の範囲内に選択設定し
た場合、すぐれた記録再生特性を達成し得ることを確認
した。
(Problems to be Solved by the Invention) The present inventors have proposed a method of superimposing a plurality of low frequency signals on a high frequency signal and recording the first magnetic layer mainly composed of the acicular ferromagnetic powder and a hexagonal magnetic layer. When a magnetic recording medium having a two-layer structure including a second magnetic layer mainly composed of crystalline ferromagnetic powder is applied and the thickness of the second magnetic layer is selected and set within a certain range, excellent results are obtained. It has been confirmed that the recording / reproducing characteristics can be achieved.

本発明はこのような知見に基づいて、短波長領域およ
びそれに重畳記録された長波長領域のすぐれた記録再生
特性を容易かつ確実に達成し得る磁気記録方式の提供を
目的とする。
An object of the present invention is to provide a magnetic recording system capable of easily and reliably achieving excellent recording / reproducing characteristics in a short wavelength region and a long wavelength region superimposed thereon based on such knowledge.

[発明の構成] (課題を解決するための手段) 本発明の磁気記録方式は、磁気記録媒体に磁気ヘッド
を介し、多周波重畳記録する磁気記録方式において、 前記磁気記録媒体として針状強磁性粉末をバインダ成
分とともに塗布形成された第1の磁性体層(下層)およ
び第1の磁性体層上に形成された六方晶系強磁性粉末を
バインダ成分とともに塗布形成された第2の磁性体層
(上層)とから成り、かつ前記第2の磁性体層の厚さδ
が Ra≦δ=0.05〜0.2μm (式中Raは中心線平均粗さを示す)の範囲内にある磁気
記録媒体を使用することを特徴とする。また、 本発明の多周波重畳磁気ヘッド記録用磁気記録媒体
は、針状強磁性粉末をバインダ成分とともに塗布形成さ
れた第1の磁性体層(下層)および第1の磁性体層上に
六方晶系強磁性粉末をバインダ成分とともに塗布形成さ
れた第2の磁性体層(上層)とから成り、かつ前記第2
の磁性体層の厚さδが、 Ra≦δ=0.05〜0.2μm (式中Raは中心線平均粗さを示す)の範囲内にあること
を特徴とする。
[Structure of the Invention] (Means for Solving the Problems) The magnetic recording system of the present invention is a magnetic recording system in which multi-frequency superposition recording is performed on a magnetic recording medium via a magnetic head. A first magnetic layer (lower layer) formed by applying powder with a binder component and a second magnetic layer formed by applying hexagonal ferromagnetic powder formed on the first magnetic layer with a binder component (Upper layer), and the thickness δ of the second magnetic layer
A is characterized by the use of a magnetic recording medium which is within the range of R a ≦ [delta] A = 0.05 to 0.2 [mu] m (wherein R a represents a center line average roughness). Further, the magnetic recording medium for recording a multi-frequency superimposed magnetic head according to the present invention has a first magnetic layer (lower layer) formed by applying acicular ferromagnetic powder together with a binder component and a hexagonal crystal on the first magnetic layer. A second magnetic layer (upper layer) formed by applying a base ferromagnetic powder together with a binder component;
Wherein the thickness δ A of the magnetic layer is within the range of Ra ≦ δ A = 0.05 to 0.2 μm (where Ra indicates the center line average roughness).

なお、「中心線平均粗さRa」は、JIS B0601に規定さ
れている粗さの表示方法で、スタイラス尖端半径2μm
の測定器で表面粗さをチャートに表し、カットオフ値の
3倍以上とした測定長さlにわたり上下の面積が等しく
なる中心線を設け、この中心線をX軸として粗さ曲線を
f(x)で表したとき、 Ra=1/l∫|f(x)|dx で表される。
The “center line average roughness Ra ” is a stylus tip radius of 2 μm in the roughness display method defined in JIS B0601.
The surface roughness is represented on a chart by a measuring device of No. 3, and a center line is provided in which the upper and lower areas are equal over a measurement length 1 which is three times or more the cutoff value, and the center line is defined as an X axis, and a roughness curve is represented by f ( When represented by x), it is represented by Ra = 1 / l1 / | f (x) | dx.

(作 用) 本発明に係る磁気記録方式においては、針状強磁性粉
末を磁性粉とした第1の磁性体層および六方晶系強磁性
粉末を磁性粉とした第2の磁性体層とを具備した構成の
磁気記録媒体を使用する。しかして、上層(第2の磁性
体層)の厚さを少くとも高周波信号、それも最短波長信
号λminの最大出力を得る磁化浸透厚λmin/2以下に構成
することにより、その高周波信号に重畳する低周波信号
の磁化浸透を確実に面内磁化し易い下層(第1の磁性
層)に実現できるので、高周波信号出力、低周波信号出
力ともに高出力が得られる。高周波信号出力はごく表面
が垂直方向に磁化が形成されていれば、最大出力を得る
半円状の磁化モードが保たれるので、高出力が保持され
る。そのδの下限は中心線平均粗さRa以上であれば磁
化モードが乱れる心配はない。
(Operation) In the magnetic recording system according to the present invention, the first magnetic layer made of magnetic powder of acicular ferromagnetic powder and the second magnetic layer made of magnetic powder of hexagonal ferromagnetic powder are used. The magnetic recording medium having the provided configuration is used. By setting the thickness of the upper layer (the second magnetic layer) to at least a high-frequency signal, which is also equal to or less than the magnetization penetration thickness λ min / 2 for obtaining the maximum output of the shortest wavelength signal λ min , The low-frequency signal superimposed on the magnetic layer can be surely realized in the lower layer (the first magnetic layer) that is easily magnetized in the plane, so that both high-frequency signal output and low-frequency signal output can obtain high output. If the surface of the high-frequency signal output is magnetized in the vertical direction, the semi-circular magnetization mode for obtaining the maximum output is maintained, so that the high output is maintained. Its δ lower limit of A is no fear that the magnetization mode is disturbed if the center line average roughness R a above.

(実施例) 以下本発明の実施例を説明する。具体例の説明に先立
って、本発明に係る磁気記録方式に用いる磁気記録媒体
の構成について説明をする。
(Example) Hereinafter, an example of the present invention will be described. Prior to the description of a specific example, the configuration of a magnetic recording medium used in the magnetic recording system according to the present invention will be described.

本発明に係る磁気記録媒体において、第1の磁気記録
体層の構成に使用される針状強磁性粉末としては、たと
えばγ−Fe2O3、Co−γ−Fe2O3などの針状構造を有する
酸化物強磁性粉末やCrO2、Co−Fe合金などの針状構造を
有する金属強磁性粉末が例示される。また、これら針状
強磁性粉末の粒径は、一般に長軸径で表され、0.1μm
〜1μmのものが好適している。
In the magnetic recording medium according to the present invention, examples of the acicular ferromagnetic powder used for the configuration of the first magnetic recording medium layer include acicular ferromagnetic powders such as γ-Fe 2 O 3 and Co-γ-Fe 2 O 3. Examples thereof include an oxide ferromagnetic powder having a structure and a metal ferromagnetic powder having a needle-like structure such as CrO 2 or a Co—Fe alloy. The particle size of these acicular ferromagnetic powders is generally represented by the major axis diameter, and is 0.1 μm
11 μm is preferred.

一方、第2の磁気記録体層の構成に使用される六方晶
系強磁性粉末としては、磁化容易軸が粒子板状面に対し
て垂直である一軸異方性を有し、たとえば保磁力が200O
e〜2000Oe程度の、M型やW型のBaフェライト、Srフェ
ライト、Caフェライト、Pbフェライトあるいはこれらの
固溶体、もしくは次の一般式で表わされるイオン置換体
などのフェライトの超微粒子粉末が例示される。
On the other hand, the hexagonal ferromagnetic powder used for the configuration of the second magnetic recording layer has a uniaxial anisotropy in which the axis of easy magnetization is perpendicular to the particle plate-like surface. 200O
Ultrafine powder of ferrite such as e-2000 Oe, M-type or W-type Ba ferrite, Sr ferrite, Ca ferrite, Pb ferrite or a solid solution thereof, or an ion-substituted product represented by the following general formula is exemplified. .

一般式:AO・n(Fe1-mMm2O3 (式中、AはBa、Sr、Ca、Pbのいずれか1種の元素を、
MはZn、Co、Ti、Ni、Mn、In、Cu、Ge、Nb、Sn、Zr、H
f、Alなどから選ばれた少なくとも1種の元素を、mは
0〜2、nは5.4〜6.0の数を、それぞれ表す。ただし、
Mが2価または4価以上の価数の元素である場合には、
Mは平均価数が3となる2種以上の元素の組合せであ
る。) これら六方晶系強磁性粉末は、その結晶構造が六角板
状を有し、板面の対角線の長さを粒径としたときの平均
粒径が0.03μm〜0.1μmの範囲のものが短波長域の記
録再生に好適している。また、六角板面の対角線の長さ
と厚さの比、すなわち板状比は、3〜5の範囲であるも
のがよい。
General formula: AOn (Fe 1-m M m ) 2 O 3 (where A is any one element of Ba, Sr, Ca, and Pb,
M is Zn, Co, Ti, Ni, Mn, In, Cu, Ge, Nb, Sn, Zr, H
f represents at least one element selected from Al and the like, m represents a number of 0 to 2, and n represents a number of 5.4 to 6.0. However,
When M is a divalent or tetravalent or higher valent element,
M is a combination of two or more elements having an average valence of 3. These hexagonal ferromagnetic powders have a hexagonal plate-like crystal structure, and those having an average particle size in the range of 0.03 μm to 0.1 μm when the diagonal length of the plate surface is defined as the particle size are short. It is suitable for recording and reproduction in the wavelength range. Further, the ratio between the length and the thickness of the diagonal line of the hexagonal plate surface, that is, the plate ratio is preferably in the range of 3 to 5.

本発明に係る磁気記録媒体は、一般に次のようにして
作製される。
The magnetic recording medium according to the present invention is generally manufactured as follows.

先ず、針状強磁性粉末とバインダとを溶媒に分散また
は溶解させ、ボールミル、サンドミルなどによって充分
に混合分散させ磁性塗料を調製する。この磁性塗料中に
は、所望によって分散剤、潤滑剤などを添加し、またグ
ラファイト粉末やカーボンブラックなどの帯電防止剤の
ような各種添加剤を適量添加してもよい。
First, a needle-shaped ferromagnetic powder and a binder are dispersed or dissolved in a solvent and sufficiently mixed and dispersed by a ball mill, a sand mill, or the like to prepare a magnetic paint. If necessary, a dispersant, a lubricant, and the like may be added to the magnetic paint, and various additives such as an antistatic agent such as graphite powder and carbon black may be added in an appropriate amount.

次に、前記磁性塗料を基体上に塗布した後、面内配向
の処理を施してから、乾燥させて第1の磁性体層を作製
する。
Next, after applying the magnetic coating material on the substrate, the substrate is subjected to an in-plane orientation treatment and then dried to produce a first magnetic layer.

上記磁性塗料を作製する再のバインダ成分としては、
従来より使用されている各種公知のものを使用すること
が可能であり、たとえばポリウレタン系樹脂、ポリエス
テル系樹脂、ポリカーボネート系樹脂、ポリアクリル系
樹脂、エポキシ系樹脂、フェノール系樹脂、塩化ビニル
系樹脂、酢酸ビニル系樹脂、あるいはこれらの混合物も
しくは共重合物などが例示される。また、潤滑剤として
はラウリン酸、パルミチン酸、ステアリン酸などが、分
散剤としてはレシチン、各種界面活性剤などが例示され
る。
As a binder component of the above-mentioned magnetic paint,
It is possible to use various known materials conventionally used, for example, polyurethane resins, polyester resins, polycarbonate resins, polyacrylic resins, epoxy resins, phenolic resins, vinyl chloride resins, Examples thereof include vinyl acetate resins, and mixtures or copolymers thereof. Examples of the lubricant include lauric acid, palmitic acid, and stearic acid, and examples of the dispersant include lecithin and various surfactants.

この第1の磁性体層は、面内配向率が0.6程度以上を
呈するように調節し、またその厚さは1μm〜5μm程
度とすることが好ましい。つまり、通常の重畳記録にお
いては、重畳する長波長信号の記録電流が短波長信号の
記録電流の数分の1以下に設定されるので、第1の磁性
体層厚は通常1μm以上であれば十分である。
The first magnetic layer is preferably adjusted to have an in-plane orientation ratio of about 0.6 or more, and preferably has a thickness of about 1 μm to 5 μm. That is, in normal superposition recording, the recording current of the long wavelength signal to be superimposed is set to be a fraction of the recording current of the short wavelength signal, so that the first magnetic layer thickness is usually 1 μm or more. It is enough.

次いで、前記形成した第1の磁性体層上に、第2の磁
性体層を形成する。この第2の磁性体層の形成は、第1
の磁性体層の形成の場合と同様に、先ず六方晶系強磁性
粉末を前述した各種バインダ成分中に均一に分散して磁
性塗料を調製する。この第2の磁性体層用磁性塗料中に
は、研磨剤として、たとえばTiO2、Cr2O3、Al2O3、Si
C、ZrO2などのモース硬度5以上で、平均粒径0.1μm〜
2.0μm程度の無機粉末を、磁性粉末100重量部に対して
0.5〜10重量部程度添加配合する。
Next, a second magnetic layer is formed on the formed first magnetic layer. This second magnetic layer is formed by the first magnetic layer.
As in the case of the formation of the magnetic layer, first, the hexagonal ferromagnetic powder is uniformly dispersed in the above-mentioned various binder components to prepare a magnetic paint. In this second magnetic material layer magnetic paint, for example, TiO 2 , Cr 2 O 3 , Al 2 O 3 , Si
C, and Mohs hardness of 5 or more, such as ZrO 2, average particle diameter 0.1μm~
About 2.0μm of inorganic powder to 100 parts by weight of magnetic powder
Add about 0.5 to 10 parts by weight.

しかる後、前記調製した第2の磁性体層用磁性塗料
を、前記形成した第1の磁性体層上に塗布し、所要の配
向処理たとえば垂直配向処理してから、乾燥させた後に
カレンダ処理などによって表面を平滑化する。この表面
平滑化処理によって、第2の磁性体層に含有させた研磨
剤粒子は、第1の磁気記録層中にくい込み、バインダ成
分に充分に保持され脱離が防止される。
Thereafter, the prepared magnetic coating material for the second magnetic material layer is applied on the formed first magnetic material layer, subjected to a required orientation treatment, for example, a vertical orientation treatment, dried, and then calendered. To smooth the surface. By this surface smoothing treatment, the abrasive particles contained in the second magnetic material layer enter into the first magnetic recording layer and are sufficiently retained by the binder component to prevent desorption.

第2の磁性体層の膜厚δは、 Ra≦δ≦λmin/2 (ただし、式中Raは中心線平均粗さ、λminは最短記録
波長)の範囲内に選択・設定される。つまり、短波長記
録特性を保持し、しかも長波長特性を低下させないよう
に設定する必要があり、一般的に0.05μm〜0.5μm程
度が適している。また、この第2の磁性体層内に帯電防
止剤を微量添加してもよいが、第1の磁性体層の導電性
が確保されていれば導電性粉末をほとんど添加しなくて
も帯電が発生せず、その分第2の磁性体層の磁性粉末の
充填率を高めて記録再生出力を向上させることが可能と
なる。なお、この導電性は基体によって確保することも
可能である。
The thickness δ A of the second magnetic layer is selected within a range of Ra ≦ δ A ≦ λ min / 2 (where Ra is the center line average roughness and λ min is the shortest recording wavelength). Is set. In other words, it is necessary to maintain the short-wavelength recording characteristics and not to degrade the long-wavelength characteristics, and a thickness of about 0.05 μm to 0.5 μm is generally suitable. Also, a small amount of an antistatic agent may be added to the second magnetic layer, but if the first magnetic layer has sufficient conductivity, the charge can be obtained without adding any conductive powder. This does not occur, and the filling rate of the magnetic powder in the second magnetic layer can be increased accordingly, and the recording / reproducing output can be improved. This conductivity can be ensured by the base.

具体例 まず、下記の組成物を充分に混合した後、サンドグラ
インダを用いてさらに1時間分散させ、第1の磁性体層
用磁性塗料を調製した。
Specific Example First, after sufficiently mixing the following composition, it was further dispersed for 1 hour using a sand grinder to prepare a first magnetic material layer magnetic coating material.

(第1の磁性体層用塗料成分) Co被着γ−フェライト粉末(保磁力Hc635Oe、平均粒径
0.5μm) 100重量部 カーボンブラック 4 〃 レシチン 3 〃 ポリウレタン樹脂 12 〃 塩ビ−酢ビ共重合体樹脂 6 〃 メチルエチルケトン 80 〃 シクロヘキサン 80 〃 トルエン 80 〃 次いで、得られた第1の磁性体層用磁性塗料を、厚さ
50μmのポリエステルフイルム上に乾燥後の膜厚が2.2
μmとなるように塗布し、面内配向処理を行った後、乾
燥させて第1の磁性体層を形成した。
(Coating component for first magnetic layer) Co-coated γ-ferrite powder (Hc635Oe, average particle size
0.5 μm) 100 parts by weight carbon black 4 〃 lecithin 3 ポ リ ウ レ タ ン polyurethane resin 12 ビ vinyl chloride-vinyl acetate copolymer resin 6 メ チ ル methyl ethyl ketone 80 シ ク ロ cyclohexane 80 〃 toluene 80 〃 Then, the obtained magnetic coating material for the first magnetic layer The thickness
The film thickness after drying on a 50 μm polyester film is 2.2
It was applied to a thickness of μm, subjected to an in-plane orientation treatment, and then dried to form a first magnetic layer.

次に、下記の組成物を充分に混合した後、サンドグラ
インダを用いてさらに2時間分散させ、第2の磁性体層
用磁性塗料を調製した。
Next, after sufficiently mixing the following composition, it was further dispersed for 2 hours by using a sand grinder to prepare a second magnetic material layer magnetic coating material.

〔第2の磁性体層用磁性塗料成分〕 Ba−フェライト粉末(保磁力620〜625Oe、平均粒径0.05
μm、板状比3) 100重量部 Al2O3粉末(平均粒径0.5μm) 4 〃 レシチン 3 〃 ステアリン酸 2 〃 ポリウレタン樹脂 8 〃 塩化ビニル−酢酸びにる共重合体樹脂 8 〃 メチルエチルケトン 80 〃 シクロヘキサン 80 〃 トルエン 80 〃 上記調製した第2の磁性体層用磁性塗料に、硬化剤と
してイソシアネート化合物を3重量部添加して混練した
後、前述した第1の磁性体層上に乾燥後の膜厚が0.05μ
m(試料1)、0.12μm(試料2)、0.20μm(試料
3)または0.42μm(試料4)となるように塗布し、次
いで磁性体層の面に対して、垂直処理を行った後に乾燥
させ、カレンダ処理を行って表面を平滑化させて第2の
磁性体層を作製した。なお、この磁気記録媒体の性状を
表−1および表−2に示す。
[Magnetic paint component for second magnetic layer] Ba-ferrite powder (coercivity 620 to 625 Oe, average particle size 0.05
μm, plate-like ratio 3) 100 parts by weight Al 2 O 3 powder (average particle size 0.5 μm) 4 〃 lecithin 3 〃 stearic acid 2 ポ リ ウ レ タ ン polyurethane resin 8 ビ ニ ル vinyl chloride-acetic acid copolymer resin 8 メ チ ル methyl ethyl ketone 80 〃 Cyclohexane 80〃Toluene 80〃 3 parts by weight of an isocyanate compound as a curing agent is added to the above-prepared magnetic coating material for the second magnetic material layer, kneaded, and then dried on the first magnetic material layer. 0.05μ thick
m (sample 1), 0.12 μm (sample 2), 0.20 μm (sample 3) or 0.42 μm (sample 4), and then dry the surface of the magnetic layer after performing the vertical processing. Then, the surface was smoothed by calendering to produce a second magnetic layer. Tables 1 and 2 show the properties of the magnetic recording medium.

比較例1、2 上記実施例における第1の磁性体層用磁性塗料をにお
いて、Co被着γ−フェライト粉末(平均粒径0.5μm、
保磁力Hc850Oe)を用いた以外は、同一条件で層厚さ4.3
μmの磁性体層を備えた磁気記録媒体(比較例1)を作
製した。また、実施例における第2の磁性体層用磁性塗
料をにおいて、Ba−フェライト粉末(保磁力660Oe、平
均粒径0.05μm、板状比3)を用いた以外は、同一条件
で層厚さ3.2μmの磁性体層を備えた磁気記録媒体(比
較例2)を作製した。これらの磁気記録媒体の性状を表
−1および表−2に併せて示す。
Comparative Examples 1 and 2 In the first magnetic coating material for the magnetic layer in the above examples, Co-coated γ-ferrite powder (average particle size 0.5 μm,
Except for using coercive force (Hc850Oe), the layer thickness was 4.3
A magnetic recording medium provided with a μm magnetic layer (Comparative Example 1) was manufactured. In addition, except that the Ba-ferrite powder (coercive force: 660 Oe, average particle size: 0.05 μm, plate ratio: 3) was used for the second magnetic material layer magnetic paint in the example, the layer thickness was 3.2 mm. A magnetic recording medium having a μm magnetic layer (Comparative Example 2) was manufactured. The properties of these magnetic recording media are also shown in Tables 1 and 2.

上記構成の各磁気記録媒体を用い、第1図に模式的に
示めす構成の測定系によって、重畳記録特性を次のよう
な条件設定で測定した。すなわち、SVHS型VTRと同じ走
行速度V=5.8m/secで、ビデオ信号Y(周波数7MHz,λ
=0.83μm)にカラー信号C(周波数630KHz,λ=9.2μ
m)を重畳し、フェライトヘッド(実効ギャップ長ge
0.3μm、トラック幅w=35μm、巻線数n=10T)によ
り、ワンループテスター評価を行った。第1図におい
て、1はポリエステルフイルム、2は第1の磁性層、3
は第2の磁性層、4は磁気ヘッド、5は記録回路、6は
再生回路をそれぞれ示す。
Using each of the magnetic recording media having the above-described configurations, the superposition recording characteristics were measured under the following conditions using a measurement system having a configuration schematically shown in FIG. That is, at the same running speed V = 5.8 m / sec as the SVHS VTR, the video signal Y (frequency 7 MHz, λ
= 0.83μm) and color signal C (frequency 630KHz, λ = 9.2μ)
m) and a ferrite head (effective gap length g e =
One-loop tester evaluation was performed using 0.3 μm, track width w = 35 μm, and number of windings n = 10 T). In FIG. 1, 1 is a polyester film, 2 is a first magnetic layer, 3
Denotes a second magnetic layer, 4 denotes a magnetic head, 5 denotes a recording circuit, and 6 denotes a reproducing circuit.

本発明に係る試料1〜4の磁気記録媒体を用いた磁気
記録方式の場合は、いずれもビデオ、カラー領域におい
て比較例1に比べ良好な記録・出力特性を呈した。つま
り、高周波および低周波の重畳記録信号を出力およびS/
Nの高い状態で記録・再生することができた。
In the case of the magnetic recording system using the magnetic recording media of Samples 1 to 4 according to the present invention, all of them exhibited better recording / output characteristics in the video and color regions as compared with Comparative Example 1. That is, high-frequency and low-frequency superimposed recording signals are output and S /
Recording and playback were possible with a high N.

第2図は、前記試料1〜4の磁気記録媒体を含むいろ
いろの磁気記録媒体における、前記出力評価の結果を示
したものである。前記ビデオ信号出力(曲線A)は、第
2の磁性層厚δMに依らず従来例(比較例1)に比べて
高い値を示している。一方、カラー信号出力(曲線B)
は、第2の磁性層厚δMがビデオ信号波長0.83μmの約
1/2以下の付近から急激に上昇していることが分る。試
料1の場合、前記ビデオ信号出力(曲線A)およびカラ
ー信号出力(曲線B)が若干低下気味であったが実用上
充分な高出力を保持していた。試料1における前記出力
の若干低下気味は、表面粗さが第2の磁性層厚δMに近
づいてきたためであり、δM>Raを保持する必要性を示
すものである。
FIG. 2 shows the results of the output evaluations on various magnetic recording media including the magnetic recording media of Samples 1 to 4. The video signal output (curve A) shows a higher value than that of the conventional example (Comparative Example 1) regardless of the second magnetic layer thickness δM. On the other hand, color signal output (curve B)
Means that the second magnetic layer thickness δM is approximately equal to the video signal wavelength 0.83 μm.
It can be seen that it rises sharply from around 1/2 or less. In the case of Sample 1, the video signal output (curve A) and the color signal output (curve B) tended to decrease slightly, but maintained a sufficiently high output for practical use. The slight decrease in the output in Sample 1 is due to the surface roughness approaching the second magnetic layer thickness δM, and indicates the necessity of maintaining δM> Ra.

なお、上記では第1の磁性層および第2の磁性層に保
磁力がほぼ同等なものを用いた例を示したが、第1の磁
性層の保磁力を第2の磁性層の保磁力よりやや小さくし
てもよい。
In the above description, an example is shown in which the first magnetic layer and the second magnetic layer have substantially the same coercive force. However, the coercive force of the first magnetic layer is made smaller than the coercive force of the second magnetic layer. It may be slightly smaller.

[発明の効果] 以上の実施例からも明らかなように、本発明に係る多
周波磁気記録方式によれば、短波長領域および長波長領
域の重畳した磁気記録信号を、容易かつ確実にしかも出
力およびS/Nの高い状態で、常に記録・再生することが
可能となる。勿論重畳する長波長成分はカラー信号1種
類に限らず、FMオーディオ信号やトラッキングパイロッ
ト信号など複数の周波数帯でも同様の作用効果を呈す
る。かくして、本発明に係る多周波重畳磁気記録方式
は、実用上多くの利点をもたらすものといえる。
[Effects of the Invention] As is clear from the above embodiments, according to the multi-frequency magnetic recording system of the present invention, a magnetic recording signal in which a short wavelength region and a long wavelength region are superimposed can be output easily and reliably. In addition, recording and reproduction can be always performed in a high S / N state. Of course, the long wavelength component to be superimposed is not limited to one type of color signal, and a similar effect can be obtained in a plurality of frequency bands such as an FM audio signal and a tracking pilot signal. Thus, it can be said that the multi-frequency superimposed magnetic recording system according to the present invention provides many practical advantages.

【図面の簡単な説明】[Brief description of the drawings]

第1図は本発明に係る磁気記録方式の実施態様を示す模
式図、第2図は本発明に係る磁気記録方式で使用する磁
気記録媒体の第2の磁性体層(上層)厚に対する重畳記
録信号出力の依存性を示す特性図である。 1……磁性層支持基体 2……第1の磁性層 3……第2の磁性層 4……磁気ヘッド 5……記録回路 6……再生回路
FIG. 1 is a schematic view showing an embodiment of a magnetic recording system according to the present invention, and FIG. 2 is an overlap recording with respect to a thickness of a second magnetic layer (upper layer) of a magnetic recording medium used in the magnetic recording system according to the present invention. FIG. 4 is a characteristic diagram illustrating the dependence of signal output. DESCRIPTION OF SYMBOLS 1 ... Magnetic layer support base 2 ... 1st magnetic layer 3 ... 2nd magnetic layer 4 ... Magnetic head 5 ... Recording circuit 6 ... Reproduction circuit

Claims (4)

(57)【特許請求の範囲】(57) [Claims] 【請求項1】磁気記録媒体に磁気ヘッドを介し、多周波
重畳記録する多周波重畳記録方式において、 前記磁気記録媒体として針状強磁性粉末をバインダ成分
とともに塗布形成された第1の磁性体層(下層)および
第1の磁性体層上に六方晶系強磁性粉末をバインダ成分
とともに塗布形成された第2の磁性体層(上層)とから
成り、かつ前記第2の磁性体層の厚さδが、 Ra≦δ=0.05〜0.2μm (式中Raは中心線平均粗さを示す)の範囲内にある磁気
記録媒体を使用することを特徴とする多周波重畳記録方
式。
1. A multi-frequency superposition recording system for performing multi-frequency superposition recording on a magnetic recording medium via a magnetic head, wherein a first magnetic material layer formed by applying acicular ferromagnetic powder together with a binder component as the magnetic recording medium. (Lower layer) and a second magnetic layer (upper layer) formed by applying hexagonal ferromagnetic powder together with a binder component on the first magnetic layer, and a thickness of the second magnetic layer. A multi-frequency superposition recording method using a magnetic recording medium in which δ A is in a range of Ra ≦ δ A = 0.05 to 0.2 μm (where Ra indicates a center line average roughness).
【請求項2】第1の磁性体層および第2の磁性体層の保
磁力がほぼ等しく設定されている事を特徴とする請求項
1記載の多周波重畳記録方式。
2. The multi-frequency superposition recording method according to claim 1, wherein the coercive forces of the first magnetic layer and the second magnetic layer are set substantially equal.
【請求項3】針状強磁性粉末をバインダ成分とともに塗
布形成された第1の磁性体層(下層)および第1の磁性
体層上に六方晶系強磁性粉末をバインダ成分とともに塗
布形成された第2の磁性体層(上層)とから成り、かつ
前記第2の磁性体層の厚さδが、 Ra≦δ=0.05〜0.2μm (式中Raは中心線平均粗さを示す)の範囲内にあること
を特徴とする多周波重畳磁気ヘッド記録用磁気記録媒
体。
3. A first magnetic layer (lower layer) formed by applying acicular ferromagnetic powder together with a binder component, and a hexagonal ferromagnetic powder formed by applying a binder component on the first magnetic layer. made from the second magnetic layer (upper layer), and the thickness [delta] a of the second magnetic layer, the R a ≦ [delta] a = 0.05 to 0.2 [mu] m (wherein R a center line average roughness A magnetic recording medium for recording a multi-frequency superposed magnetic head.
【請求項4】第1の磁性体層および第2の磁性体層の保
磁力がほぼ等しく設定されている事を特徴とする請求項
3記載の多周波重畳磁気ヘッド記録用磁気記録媒体。
4. The magnetic recording medium according to claim 3, wherein the coercive forces of the first magnetic layer and the second magnetic layer are set substantially equal.
JP2122698A 1990-05-11 1990-05-11 Multi-frequency superimposed magnetic recording method and magnetic recording medium for multi-frequency superimposed magnetic head recording Expired - Lifetime JP2744114B2 (en)

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GB2403587B (en) 2002-03-18 2005-08-03 Hitachi Maxell Magnetic recording medium and magnetic recording cartridge
US7494728B2 (en) 2002-04-25 2009-02-24 Hitachi Maxell, Ltd. Magnetic tape and magnetic tape cartridge
US6964811B2 (en) 2002-09-20 2005-11-15 Hitachi Maxell, Ltd. Magnetic powder, method for producing the same and magnetic recording medium comprising the same
DE112004000008T5 (en) 2003-02-19 2005-06-16 Hitachi Maxell, Ltd, Ibaraki Magnetic recording medium
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