KR790001837B1 - Magnetic erasing head - Google Patents

Abstract

An erasing head for magnetic recording appts. using a static magnetic field, is composed of the plurality of magnetic poles having surfaces which confront the recording tape. The 1st and 2nd poles have opposite polarities each other. The 1st pole is arranged to engage a recording track along its full width and magnetizes it to a given polarity. Each half track is magnetized to the opposite polarities so that the distortion of output signals can be reduced when the signal is reproduced.

Description

Demagnetizing head

1 and 2 are layout views for explaining the present invention.

3 and 4 are waveform diagrams for explaining FIGS. 1 and 2, respectively.

5 is a layout view for explaining the present invention.

6 is a curve diagram for explaining the present invention.

7 is a layout for explaining the present invention.

8, 9 and 10 are curve diagrams for explaining the present invention, respectively.

11 is a layout view for explaining the present invention.

12 and 13 are curve diagrams for explaining the present invention, respectively.

14 is a perspective view showing one embodiment of the present invention magnetic erasing head.

15 and 16 are curve diagrams for explaining the present invention.

17, 18 and 19 are perspective views each showing another embodiment of the present invention's magnetic erase head.

20, 21, 22, 23, 24, 25, 26 and 27 are layout views showing another embodiment of the magnetic head of the present invention, respectively.

28 and 29 are curve diagrams for explaining the present invention.

30, 31, and 32 are layout views each showing another embodiment of the inventive magnetic erase head.

The present invention relates to a magnetic erasing head of a method of erasing a residual magnetic field by a DC magnetic field by recording a magnetic recording medium.

As a method of erasing the residual magnetic by recording of a magnetic recording medium such as a magnetic tape, there are a direct current erase method and an alternating current erase method.

The AC erasing method causes an alternating current to flow through the coil of the magnetic erasing head, magnetizes to saturation when the magnetic recording medium passes through the pores of the magnetic erasing head due to the movement of the magnetic recording medium, and then moves away from the void. As a result, the magnetization is repeatedly inverted by the alternating magnetic field, and the intensity of the magnetization becomes smaller gradually, eventually reaching a magnetic neutral point, and in a state of remaining magnetic zero, thereby completely erasing the magnetic recording medium. Way.

This alternating current erasing method is widely employed in the current magnetic recording and reproducing apparatus because the residual magnetic field of the magnetic recording medium is reliably erased.

However, this law is not without its flaws.

In other words, when the magnetic force Hc of the magnetic material of the magnetic recording medium is large, the erase power supplied to the magnetic erasing head is as large as that, and when the magnetic force Hc is too large, the large erase power is supplied to the magnetic erasing head. The core may saturate with a smaller magnetization amount than in the case of direct current magnetization due to eddy current loss and the like, and it may not be possible to sufficiently erase such a recording signal on the magnetic recording medium.

The simplest of the DC erasing method is a method in which a strong DC magnetic field is given by a permanent magnet or an electromagnet as a magnetic recording medium, and all residual magnetization by recording of the magnetic recording medium is magnetized to a saturation point and erased. When the permanent magnet is used, this method does not require the erase power increased by the above-described AC erasing method. Therefore, the method can be applied to an electronic tape recorder and to a cassette tape recorder attached to a radio receiver. Although the beat of the high frequency signal and the erasing alternating signal in the radio receiver, such as in the above, may not be recorded on the magnetic tape as a harmful signal, on the other hand, the signal is recorded on the magnetic recording medium erased by the DC erasing method. This reproduction has a fatal drawback that the reproduction signal is distorted.

Here, an improved DC erasing method is proposed which eliminates defects such as DC erasing method (Japanese Patent Publication No. 40-1551). It is composed of magnetic materials with different polarities in sequence, and gradually magnetizes as the sensitivity of the magnetic field gradually decreases. At the incidence point of the magnetic recording medium, at least the sensitivity of the magnetic field converges to zero. It is a method of erasing using a magnetic erasing head made by vi).

As a specific example of this self-erasing head, a part of the main surface of a permanent magnet material such as barium ferrite intersects magnetic poles having different polarities in the circumferential direction and magnetizes as if the magnetization is arranged in a large number by gradually decreasing the magnetization intensity. The head is configured to drive the magnetic recording medium in the circumferential direction thereof.

According to this improved DC erasing method, the magnetic medium is erased using the same mechanism as the AC erasing method described above, the erasing is surely performed, and the power supply, oscillator, etc. necessary for AC erasing are unnecessary. It is possible to reduce the erase power of the magnetic recording and reproducing apparatus and reduce the cost.

However, this improved DC elimination method is not without drawbacks. That is, the magnetic erasing head requires a large number of magnetic poles, and therefore, the length of hospitality for the magnetic recording medium (magnetic tape) and the magnetic erasing head becomes large, which is suitable for records using small cassette tapes. Not.

In addition, since it is difficult to fully converge the magnetic field given to the magnetic medium, the magnetic recording medium can be erased as reliably as the above-described AC erasing method.

In view of this, the present invention is simple in structure, can be surely erased, can be made compact, and eliminates the need for erasing power. It is to propose a new demagnetizing head.

Next, before describing the self-erasing head according to the present invention, a direct current erasing method is considered in relation to the present invention.

First, consider the simplest DC erasure method.

1 and 2 are explanatory views of this direct current erasing method, in which the magnetic erasing head H _E , the magnetic erasing recording H _R, and the magnetic reproducing head H _P are arranged with respect to the magnetic tape T from left to right in the drawing. The magneto erasing head H _E is a bar magnet. In FIG. 1, the N pole serves the magnetic tape T, and in FIG. 2, the S pole serves the magnetic tape T. In FIG. Thus, these magnetic erasing heads H _E have the strength of magnetization to give the magnetic tape T a sufficient magnetic field to saturate them.

In this case, the magnetic tape T moves in the direction of the arrow a, and passes through the magnetic erasing head H _E magnetic recording head H _R and the magnetic reproducing head H _P in this order.

Incidentally, in these Figs. 1 and 2, the sine wave signal sin 2 πft (where f is frequency and t is time) is supplied to the magnetic recording head H _R as shown in Figs. 3 and 4a, respectively. Recording on the magnetic tape T and reproducing the respective recording signals with the magnetic reproducing head H _P , the respective reproduction outputs are distorted as shown in FIGS. 3B and 4B, and the distortion state thereof is changed. .

The distortion of the reproduction outputs of FIGS. 3B and 4B is distorted, as shown in FIGS. 3C and 4C, as shown in FIGS. 3C and 4C, a sine wave (indicated by a solid line) having the same frequency as the recording input and a second high frequency wave (dotted line). And overlapping with). The distortion of the reproduction outputs of FIGS. 3B and 4B is incorrect because the phases of the second high frequency waves of the sine wave are 180 ° different from each other as is apparent from FIGS. 3C and 4C.

Here, as shown in FIG. 5, the magnetic pole P ₁ of the S-pole (which may be the N-pole) for dividing the recording track t in the width direction and serving the full width of the recording track t, and the divided track t ₁ , any one of t _2, for example, N poles to entertain the width of the divided tracks t ₁ in the longitudinal direction of the magnetic poles P ₂ recording track t a (when the magnetic poles P ₁ N poles is the S-pole), a bit As far apart as possible, the magnetic pole P ₁ is arranged to serve the magnetic tape before the magnetic pole P ₂ to constitute the magnetic erasing head H _E , to erase the recording track t of the magnetic tape, first of all the recording track t at the magnetic pole P ₁ . When the width is saturated magnetized, and the width of the recording track t ₁ is inverted at the stimulus P ₂ , and the saturation magnetization is performed at the opposite polarity, the reproduction output of the recording track t is equal to 180 degrees of the recording signals at each divided track t ₁ , t ₂ . ° The second high frequency with different phase cancels out, so there is not much distortion It can be seen that the output. In FIG. 5, g {H _R } and g {H _P } denote respective voids of the magnetic recording head and the magnetic reproduction head, respectively.

In general, the recording track is divided into n (an integer of 2 or more) in the width direction, and the direction of residual magnetism in each of the divided tracks is sequentially different from the S, N, S ... directions, and the N direction and The polarities of each other are made to be equal so that the total amount of the residual magnetism in the S direction is the same, i.e., the sum of the N part area and the sum of the S part area are the same in the residual magnetism characteristic curve of the widthwise position-magnetic tape of the recording track of FIG. It can be seen that the regeneration output is a distortion-free output if the demagnetizing head is composed of n different magnetic poles.

Next, as shown in FIG. 7, in FIG. 5, the length of the recording track t of the magnetic pole P ₂ (where the width " effective track width " is W) in the width direction, that is, the width of the divided track t ₁ (this is W ₁ ). When the width of the other divided track t ₂ is set to W ₂ , the distortion of the reproduction output is considered. After saturation magnetizing the entire width of the recording track t to the N pole or the S pole, the sinusoidal signal Msinwt (where M is the coefficient and W is each frequency and t is the time) is used as the magnetic recording head H _R. If the reproduction output (instantaneous value) eS or eN at the time of recording and reproducing them with the magnetic reproducing head H _P is assumed to be the second order high frequency only, as described with reference to Figs.

eN = E ₁ sin wt + E ₂ sin 2wt ............... (1)

eN = E ₁ sin wt-E ₂ sin 2wt ............... (2)

Where E ₁ and E ₂ are coefficients, the reproduction output e by this recording after erasing the recording track t as shown in FIG.

It becomes In the third meal

It becomes Here, X means the difference between the boundary lines L of the residual magnetizations having different polarities from each other by the self-erasing head H _E with respect to the center line L ₀ of the recording track t in FIG.

Therefore, the distortion rate D of the reproduction output is

It becomes When these 4th formula and 5th formula are shown graphically, it will become like FIG. 8 and 9th, respectively.

W/2이므로

로 되고, 또, 실용상은 E₁=1》E₂로 하면 왜곡율 D는,Where actually X is | X |

W / 2

Also, practically, when E ₁ = 1 >> E ₂ , the distortion factor D is

Becomes Therefore, if X is X = Xa when the maximum value of the practically acceptable distortion rate is Da and D = Da, then Xa is

It becomes When the seventh equation is shown in a graph, it becomes like the tenth degree. That is, this Xa becomes the difference tolerance of the boundary line L of FIG.

Next, as the magnetic erasing head, a pair of magnetic heads, which are DC excited, forms magnetic fields in directions opposite to each other in the longitudinal direction of the recording track of the magnetic tape. Based on the experiment, the influence of the widthwise position and the strength of the magnetic field formed from these magnetic heads on the generation of distortion of the reproduction output will be considered.

11 shows the arrangement relationship of the magnetic heads with respect to the magnetic tape in the experiment. In Fig. 11, T is a magnetic tape, in which the magnetic head H ₁ , the magnetic head H ₂ , the magnetic recording head H _R and the magnetic reproducing head H _P are arranged in order from left to right in the longitudinal direction, and the magnetic tape T Travels in the arrow a direction (from left to right). Thus, the magnetic erasing head H _E is constituted as the magnetic head H ₁ and the magnetic head H ₂ , and these magnetic heads H ₁ and H ₂ are supplied with direct currents reverse to each other in the coils, and the magnetic heads H ₁ and H ₂ The magnetic field is given to each other so that an erase magnetization trace which becomes a pair of divided magnetization traces magnetized so that the scanning direction components of the residual magnets are reversed by the cooperation.

Also, g is a magnetic head H _1, H _2, H _R of the pores, and perpendicular to the longitudinal direction of the magnetic tape T.

These magnetic heads H ₁ , H ₂ , H _R and H _{P use those shown} in the following table.

[table]

The recording bias current has a frequency of 34 KHz (bias point is 1 KHz peak), and the recording signal is a single frequency signal (sine wave signal) of 333 Hz, which is 11 dB or less in saturation. As for the magnetic tape T, the coercive force used was 1,036Oe and the magnetic layer coating thickness was 3.35 micrometers, and the running speed was 4.8 cm / S.

In Fig. 11, t is a recording track (track width is W), the magnetic head H ₁ and the magnetic recording head H _R are welded to the magnetic tape T such that their respective voids g match the width of this recording track t, The magnetic head H ₂ is welded to the magnetic tape by the gap g shifted in the width direction of the recording track t (above the drawing) (the distance between the lower end of the gap g and the centerline L ₀ of the recording track t is X). The magnetic regeneration head H _P is welded to the magnetic tape T such that the center of the width W 'of the regeneration track t' of the gap g is above the center line LO.

In the first experiment, a DC current large enough to give each coil of the magnetic heads H ₁ and H ₂ constituting the magnetic erasing head H _E (magnetic tape T large enough to saturate them) ), The magnetic head H ₂ was moved in the width direction of the recording track t to change X, and the distortion rate of the reproduction output (if no equalizer was installed in the reproduction system) was measured. . The results are shown graphically in FIG.

In the graph of FIG. 12, X (mm) is indicated on the horizontal axis and distortion rate (%) is indicated on the vertical axis. According to the graph of FIG. 12, it can be seen that X = 0, that is, the smallest distortion rate when the lower end of the gap g of the magnetic head H ₂ is on the center line L ₀ in FIG.

In the second experiment, a sufficiently large direct current (DC current so as to give magnetic tape T a sufficient magnetic field to saturate them) flows to one magnetic head H ₁ constituting the demagnetizing head H _E , and the other The magnetic head H ₂ on the side is fixed to the position where X is X = 0, and the direct current flowing through the coil is changed to change the magnetism given to the magnetic tape T therefrom, and the regenerative output at this time (the equalizer Distortion was measured).

This result is shown graphically in FIG.

In the graph of FIG. 13, the magnetic field given by the magnetic tape T by the magnetic head H ₂ is shown on the horizontal axis, and the distortion rate (%) is indicated on the vertical axis. In addition, Hc of this figure shows the coercive force of the magnetic tape T. As shown in FIG. According to this graph, the 13 degrees, the magnetic head by the magnetic field H ₂ is given to the magnetic tape T rapidly decreases outside the coercive force Hc of the magnetic tape T, and also He then even if a magnetic field by the magnetic head H ₂ over 1.5Hc, The distortion rate of the reproduction output is considered to be approximately constant.

It has a main magnetic pole and a negative magnetic pole arranged in parallel, such as scanning the same recording track of the magnetic recording medium in the preceding and the following, respectively, and the main magnetic pole effectively has a length or more in width in the width direction of the recording track, The magnetic recording medium can be provided with a DC magnetic field of sufficient strength to magnetically saturate them. The sub-pole has a length smaller than its width in the width direction of the recording track, and at the same time, the magnetic field has a DC magnetic field of more than its antimagnetic force. The digestion magnetization trajectory consisting of a plurality of divided magnetization trajectories magnetized so that the scanning direction components of the residual magnets are reversed by the cooperation of the main stimulus and the sub stimulus can be obtained as shown in the recording track. It is intended to be configured.

Some embodiments of the invention are described below with reference to the drawings. In FIG. 14, an embodiment of the magnetic head H _E is applied to a two-track tape recorder using a cassette, and the first and second bar magnets (NKS permanent magnets) M ₁ and M ₂ It is embedded in a head block BL made of a nonmagnetic material (brass). The head block BL has a circumferential tape-joint surface ST, and each of the magnetic poles that are end portions of the first and second bar magnets M ₁ and M ₂ , that is, the first magnetic pole (main magnetic pole) P ₁ and the second magnetic pole (sub) Magnetic poles) P ₂ are provided in parallel along the tape running direction a, and each cross section constitutes a part of the indigenous part of the head block BL. Thus, these first and second magnetic poles P ₁ and P ₂ are saturated and magnetized into N and S poles (of course, S and N poles are possible) in the thickness direction of the magnetic tape T, respectively. These first and second magnetic poles P ₁ and P ₂ have a spherical cross section having a long side in the width direction (the circumferential direction of the circumferential surface) of the recording track of the magnetic tape T, and the first magnetic pole P ₁ is the upper recording of the magnetic tape T. It has a length greater than the width of the recording track (the width in the width direction of the recording track), such as to treat the entire width of the track (except that the magnetic pole P ₁ may emerge from the upper edge of the magnetic tape T, but may not be caught by the lower recording track). Is). The second magnetic pole P ₂ has a length (width in the width direction of the recording track) equal to or greater than the width of the recording track (less than the length of the first magnetic pole P ₁ ), such that the second magnetic pole P ₂ is treated with the upper half width of the upper recording track of the magnetic tape T. (The magnetic pole P ₂ may come out of the upper edge of the magnetic tape T, but is not caught by the lower half width of the upper recording track). The magnetic tape T is approximately in contact with the first magnetic pole P ₁ and then travels in the arrow a direction to serve the second magnetic pole P ₂ .

The magnetic field distribution was the same as the curve of FIG. 15 at the magnetic tape longitudinal position (curve L phase in contact with the magnetic poles P ₁ and P ₂ ) of the magnetic field in the thickness direction of the magnetic tape T by the magnetic erasing head H _E of FIG. 14. In 14-degree magnetic erasing head _E to H in the width direction of the recording track of the magnetic tape T X (㎜) by measuring a change in total harmonic distortion (%) of the reproduction output in the case to move the result, like the degree of claim 16 curve. In this case, X = 0 is a case where the lower end of the second magnetic pole P ₂ is on a bisecting line in the width direction of the recording track. Magnetic recording head The magnetic reproducing head was one having a magnetic gap length of 1.4 mu and a width of 1.5 mm. The recording bias current has a frequency of 34 KHz (bias point is 1 KHz peak), and the recording signal is a single frequency signal (sine wave signal) of 333 Hz, which is 11 dB or less in saturation. The magnetic tape T used was 9,740 Oe of coercive force and 1.89 micrometers of magnetic layer application | coating thickness, and the running speed was 4.8 cm / s.

According to the graph of FIG. 16, it can be seen that the distortion rate is the smallest at X = 0.

Next, some modifications to the above-described magnetic erasing head H _E of FIG. 14 will be described. The 17-degree magnetic erasing head H _E has a first magnetic pole P ₁ is composed of a bar magnet M ₁ as in the 15 ° magnetic erasing head H _E, but the second magnetic poles P ₂ constitutes the most head Brock BL as a magnetic material This is a case where the magnet is formed by magnetizing in the opposite polarity to the _first magnetic pole P ₁ at a predetermined pole portion of the tape-joint surface ST. In the core block BL, the adjacent portion BLa of the bar magnet M ₁ is made of a nonmagnetic material.

The 18-degree magnetic erasing head H _E, the head Brock a case constituting the entire BL as a magnetic material, and the first and second magnetic poles P ₁ and P ₂ both, configured by magnetizing a predetermined intrinsic part of the tape treated surface ST .

The 19-degree magnetic erasing head _E is H, C 2 recommend the coil to the ring-like core of a common core of RH _1, RH _2, and configured with a case configured so as to direct current flow in the coil C. Thus, the first and second of the air gap g ₁ and g width of the _second (magnetic tape recording track in the width direction length) and the relative positional relationship between each of the first 14 degrees of the magnetic erasing head H _E consisting of a ring-like core RH _1, RH ₂ Corresponding to the lengths of the magnetic poles P ₁ and P ₂ (the widthwise length of the recording track of the magnetic tape) and the relative positional relationship. The magnetic fields generated in the gaps g ₁ and g ₂ are opposite to each other in the traveling direction of the magnetic tape.

The magneto erasing head according to the present invention is not only a permanent magnet or an electromagnet (a bar electromagnet or a ring electromagnet), but a combination of both of them.

In the magnetic erasing heads of the embodiments of FIGS. 14, 17, 18, and 19 described above, the recording tracks are arranged such that the first magnetic pole P ₁ is treated with the full width W of the recording track t as shown in FIG. a width direction length t as W or more, and a first widthwise length of the recording track t stimulation P ₁ and the second magnetic pole having a different polarity P ₂ is to treat an example of a recording track t g in the upper half width W / 2 Although the case where W / 2 or more is used, the magnetic head when the recording track is used as a single track and two tracks will be described with reference to FIG. When the recording track t is used as a single track, its full width W is used, and when it is used as two tracks, the single track t is two tracks t ₁ and t ₂ having a width W ₁ and these tracks t ₁ and t _It is divided into guard bands tg of width W ₂ between _two . Thus, the magnetic erasing head H _E has treated the entire width W of a single track, t, and the length of the bowl on the first magnetic pole P ₁ and the track t _1, each upper half-width of t ₂ W _1/2 less than W, the length is W _1/2 or more and ₁ W / 2 + W _2/2, the two first magnetic pole P ₁ and the second magnetic pole having a different polarity P _21, P ₂₂ composed.

A magnetic erase head H _E has, in view of the elimination of the two tracks t _1, t _2, respectively, equal to 20 degrees, the magnetic erasing head H _E. In consideration of the erasing of the single track t by the self-erasing head H _E , the single track t is divided into four width directions, and the direction of the residual magnetic field by erasing the respective divided tracks is, for example, S, N, The S and N directions are sequentially changed, and the sum of the widths of the current magnetic portions in the N direction and the S direction is the same, and the distortion of the reproduction output is reduced.

이상의 길이를 가지고 제 1 자극 P₁과 다른 자극, 제 2 자극 P₂와, 단일트랙 t의 상측 반폭 W/2에 대접하고, W/2이상의 길이를 가진 제 1 자극 P₁과 같은 극성의 제 3 자극 P₃와 트랙 t₁의 상측반폭

에 대접하고,

이상의 길이를 가지고, 제 1 자극 P₁과 다른 극성의 제 4 자극 P₄로 구성하여도, 제 21 도의 자극 소거 헤드 H_E와 같이 재생출력의 왜곡이 적은 소거를 행할 수 있다. 이 경우, 트랙 t에 관해서는 제 2 및 제 3 자극 P₂, P₃가, 트랙 t₁에 관해서는 제 3 및 제 4 자극 P₃, P₄가, 트랙 t₂에 관해서는 제 1 및 제 2 자극 P₁, P₂가 각각 주자극 및 부자극으로 된다.In addition, the magnetic erasing head H _E in the case of combination with a recording track with danyi track and a second track, as shown in claim 22 is also, treat the entire width W of a single track, t, and its width W is _the length of the serve at the first top edge portion of the magnetic pole P ₁ and the track t ₁ with a portion of the track over a center line L ₂ and t _2,

Has over the length the first magnetic pole P ₁ and the other magnetic pole, the second magnetic poles P ₂ and a third of the same polarity as the upper half width W / 2 treated on, and the first magnetic pole having a W / 2 or more in length P ₁ of a single track t 3 Upper half width of magnetic pole P ₃ and track t ₁

Entertain,

Has a length at least a first be composed of the fourth magnetic pole having a different polarity and the pole P ₄ P _1, it is possible to perform distortion cancellation of less reproduction output as in the 21-degree magnetic pole erasing head H _E. In this case, with respect to the track t of the second and third magnetic poles P _2, P _3, the track with respect to t ₁ is the third and fourth magnetic poles P _3, P _4, the first and comes to a track t ₂ The two magnetic poles P ₁ and P ₂ become the main magnetic pole and the negative magnetic pole, respectively.

In each of the embodiments described above, if the recording track of the magnetic tape is saturated by the first magnetic pole and the recording signal is erased, then the polarity of the half-width residual magnetic in the recording track is reversed by the second magnetic pole. The distortion of the reproduction output can be reduced.

However, when the magnetic tape travels with respect to the magnetic erasing head in the width direction thereof, the width of the portion where the polarity of the residual magnetic is reversed by the second magnetic pole of the magnetic erasing head disappears from the half width of the recording track, and the reproduction output is performed. The distortion will become large.

Here, some embodiments of the magnetic erasing heads in which the distortion of the reproduction output does not increase even when there is such a cross in the width direction of the magnetic tape will be described below. The 23-degree magnetic erasing head H _E has a first magnetic pole P and the length of ₁ larger than the width W of the recording track, t, of the first magnetic pole P ₁ and the other polarity second magnetic poles P _2, a length of a recording track t of the The width W is 1/2, that is, W / 2, so that the first and second magnetic poles P ₁ and P ₂ are arranged approximately in the center of the recording track t.

According to this self-erasing head, the total sum of the widths of the remaining magnetic portions of the recording tracks with different polarities is constant irrespective of the difference in the width direction of the magnetic tape, so that the distortion of the reproduction output may increase due to this difference. There is no.

In the 24-degree magnetic erasing head H _E, first a 23 degree second magnetic poles P ₂ in case of a cyclic (丸形) (diameter of W / 2), which when the circumferentially bar magnet is when smaller the diameter, the so-called Since a wire magnet is used, there is an advantage that it can be easily manufactured even with high dimensional accuracy.

As shown in FIG. 21, the magnetic erasing head H _E considering the difference in the width direction of the magnetic tape when the recording track is used as the single track and the two tracks is the total width of the single track t as shown in FIG. has a length that is greater than W, the first magnetic pole P ₁ are arranged substantially at the center of a single track and t, having a length of 1/2, W _1/2 of gakpok W ₁ of the track _1, t, t _2, each track substantially disposed at the center of the t _1, t _2, and has a first magnetic pole P ₁ and the second magnetic pole having a different polarity P _21, P ₂₂ and 1/2 of the width W ₂ of the guard band tg, i.e., the length of W _2/2 And a second magnetic pole P ₂₃ having a different polarity than the first magnetic pole P ₁ disposed approximately in the center of the guard band tg.

According to this self-erasing head H _E , even in a single track t and in each track t ₁ and t ₂ , the summation of the angular widths of the residual magnetic portions having different polarities is made constant regardless of the width direction difference of the magnetic tape. do. As for the track t, the first magnetic pole P ₁ is the main magnetic pole, and the second magnetic poles P ₂₁ , P ₂₂ , P ₂₃ are the negative magnetic poles. In regards to the track t ₁ is the first magnetic poles P _1, P ₂₁ is the second magnetic pole, with respect to the track t ₂ of the first magnetic poles P _1, a second magnetic pole P _22, each main magnetic pole and a sub magnetic pole.

In order to perform the same operation as that of the above-described magnetic erase head H _E of FIG. 23, as shown in FIG. 26, the entire width W of the recording track t is welded, has a length larger than the width W, and is disposed approximately in the center thereof. The first magnetic pole P ₁ and a portion of the recording track t that extends from the upper edge of the recording track t to the middle of the lower half width of the recording track t, and have a length greater than that of the first magnetic pole P ₁ , the polarity different from that of the first magnetic pole P ₁ . A second magnetic pole P ₂ and a third magnetic pole of the same polarity as the first magnetic pole P ₁ , having a length larger than that of the first magnetic pole P ₁ , the portion of the recording track t extending from the upper edge of the recording track t to the middle of the upper half width thereof; formed of a P _3, the second and third magnetic poles P _2, P ₃ and the interval between the lower end by W / 2 may be configured to self-erase head H _E. In this case, only the first magnetic pole P ₁ is composed of the main magnetic pole, but the secondary magnetic pole is composed of the second magnetic pole and the third magnetic pole P ₃ , and the lengths across the width direction of the recording track of the secondary magnetic pole are the second and third magnetic poles. The length difference W / 2 between P ₂ and P ₃ is obtained.

However, in each of the above-described magnetic erasing heads, the recording track of the magnetic tape is saturated as the first magnetic pole, and the recording signal is erased. After doing so, a part of the recording track is used as the second magnetic pole having a different polarity than the first magnetic pole. The magnetic field above the magnetic force of the magnetic tape is given to reverse the partial polarity of the residual magnetization caused by the first magnetic pole to perform the erasing. Thus, the boundary lines of the residual magnetics having different polarities by the magnetic erasing heads of the recording tapes of the magnetic tape were explained as coinciding with the trajectories of the ends of the second magnetic poles (the recording tracks, the ends of the side facing the center). . Here, as shown in FIG. 27, the recording track t is saturated at the first magnetic pole P ₁ that enters the entire width W of the recording track t, and has a width W or more, and then the upper side of the recording track t. Consider the case where the polarity of the residual magnetization magnetized in the first magnetic pole P ₁ of the recording track t is reversed in the second magnetic pole having a half width W / 2 and having a length of W / 2 or more. At this time, the magnetic field changes at the distance X (the lower side is positive in FIG. 27) from the end of the second magnetic pole P ₂ on the center line L ₀ of the recording track t as shown in the curve of FIG. 28a. In other words, as X becomes larger, the magnetic field decreases. In FIG. 28A, Hm indicates the maximum magnetic field. This maximum magnetic field Hm must be equal to or greater than the coercive force of the magnetic tape. Thus, when this maximum magnetic field Hm is slightly larger than the coercive force of the magnetic tape, the boundary lines of residual magnetization with different polarities are almost identical to the center line L ₀ .

Also, as the maximum magnetic field Hm becomes larger than the coercive force of the magnetic tape, the boundary line moves outward from the center line L ₀ than the end of the second magnetic pole P ₂ . Therefore, when the width W of the recording track of the magnetic tape is considerably small, the second magnetic pole P ₂ is moved in the width direction of the recording track t so that the boundary lines of the residual magnetics having different polarities do not coincide with the center line L ₀ . Distortion becomes large.

However, in the magnetic erasing head H _E of FIG. 27, the coercive force is different from Hc ₁ , Hc ₂ (Hc ₁ > Hc ₂ ), and the magnetic characteristics (BH characteristics) are spherical as shown in FIGS. 28b and c for simplicity. In consideration of erasing the recording track t of the magnetic tape, the boundary lines of the residual magnets having different polarities from each other become L 'and L "as in the twenty-seventh degree, and the positions of the boundary lines L' and L ' 28a is a help, as _{X = X 1, X = X} 2 (X 1 <X 2).

The positions of these boundary lines L 'and L "also change depending on the value of the maximum magnetic field Hm. Therefore, the plurality of magnetic tapes having different coercive forces are erased. If the second magnetic pole of the erasing head is matched with the position of the recording track, the distortion of the reproduction output becomes large when the other magnetic tape of the coercive force is erased.

Here, an embodiment in which the distortion of the reproduction output becomes small with respect to any of the plurality of magnetic tapes having different coercive force will be described. As shown in FIG. 20 or FIG. 27, in the self-erasing head H _E , the magnetization of the second magnetic pole P ₂ is appropriately selected, whereby the distortion of the reproduction output can be reduced. The decrease in the magnetic field on the increase of the X so close to 28a degrees as can be seen from the track, a second magnetic field at the position of the width direction of the recording track t of the magnetic pole P ₂ is, of the magnetic poles P ₂ end (X = 0) The sum of divisions becomes large. Therefore, in order to reduce the distortion of each of the reproducing outputs of a plurality of magnetic tapes having different coercive force, even if the magnetic field larger than the coercive force is close to the coercive force of the magnetic tape having the largest coercive force, the magnetic field larger than the coercive force is applied to the recording track t at X = 0. It can be seen that the magnetization strength of the second magnetic pole P ₂ may be set so as to be given. These are applicable to the magnetic erase heads as shown in FIGS. 23 and 24.

In the magnetic erasing head H _E of FIG. 27, the recording track by the first magnetic pole P ₁ of the magnetic erasing head H _E is used, using magnetic force Hc ₁ = 960 (Oe) and Hc ₂ -470 (Oe) as the magnetic tape. If the magnetic field at t is 2,700 (Oe) and the magnetic field (corresponding to Hm of the 28th) at approximately the center of the recording track t 'by the second magnetic pole P ₂ is 1050 (Oe), X (mm) The change in the distortion rate (%) of the reproduction output in the case of change is indicated by curves (1) and (2) in FIG.

In this case, -X ₄ is the end position of the second magnetic pole P ₂ when the boundary line L 'of the residual magnetization by the magnetic erasing head H _E coincides with the center line L ₀ in the magnetic tape of the coercive force Hc ₁ = 960 (Oe). Is displayed. According to the graph of FIG. 29, it can be seen that the difference in the value of X in which the distortion of the reproduction output is minimized in the magnetic tape is very small.

Next, with reference to FIG. 30, another example of the magnetic erasing head in which the distortion of the reproduction output is reduced with respect to the plurality of different magnetic tapes of the coercive force will be described. The self-erasing head H _E is provided with the first magnetic pole P ₁ , which has a length equal to or greater than the full width W of the recording track t, has a length greater than this width, and saturates the magnetic tape, and in the middle of the recording track t at the upper edge of the recording track t. The position of the lower end of the second magnetic pole at the upper edge of the recording track t and the second magnetic pole P ₂ having a different polarity than the first magnetic pole P ₁ and having a length greater than that of the recording track t leading treat the portion of the recording track than t up to a position close to the top edge portion, and has a length more than the treat width, made of a third magnetic poles equal in polarity to the first magnetic pole and P _1, coercive force Hc _1, Hc _{2 ... ... When} using magnetic tapes of {Hc _{1 /} Hc _{2 ......} }, the maximum magnetic field given to the magnetic tape by the second and third magnetic poles P ₂ and P ₃ is Hc ₁ or higher and the antimagnetic force Residues with different polarities in magnetic tapes of Hc ₁ , Hc _2. Boundary of the group _{L 1 '-L 2', L} 1 '-L 2 "..... gap between Wd _{1, 2} ..... Wd such that a substantially equal to each other, the second and third magnetic poles P _2, P The magnetization strength of ₃ and the distance Wd ₀ between the lower ends thereof are set.

The relationship between the first and second and third magnetic poles P ₁ , P ₂ and P ₃ and the main stimulus and the sub stimulus is the same as that of the second b degree. In this case, when the magnetization strengths of the second and third magnetic poles P ₂ and P ₃ are the same enough to saturate the magnetic tape, they may be selected such that Wd ₀ ≒ Wd ₁ ≒ Wd ₂ ≒ W / 2. If the upper end of the magnetic pole P ₂ is above the lower end of the magnetic pole P _3, the same effects as described above can be obtained.

In the first, second and third magnetic poles P _1, P ₂ and P ₃ may be the following: as to the transformation of the 30-degree magnetic erasing head _E H shown in Figure 31.

로 되도록 선정하면 좋다.The first magnetic pole P ₁ is the same as the case of FIG. Even if the length of the second magnetic pole P ₂ is smaller than the width W of the recording track t, the second magnetic pole P ₂ is allowed to enter the inner portion from the upper and lower edges of the recording track t. The third magnetic pole P ₃ is shorter than the length of the second magnetic pole P ₂ and enters the recording track t inside both ends of the second magnetic pole P ₂ . In the magnetic tape having the coercive force Hc ₁ , Hc ₂ ..., The boundary lines L ₁₁ '-L ₂₁ ' of the residual magnets having different polarities at both ends of the second and third magnetic poles P ₂ , P ₃ . L ₁₁ "-L ₂₁ " ...... spacing Wd ₁₁ , Wd ₂₁ ... and L ₁₂ '-L ₂₂ ', L ₁₂ '-L ₂₂ "...... spacing Magnetization of the second and third magnetic poles P ₂ , P ₃ such that the respective sums of Wd ₁₂ .Wd ₂₂ ... Wd ₁₁ + Wd ₁₂ , Wd ₂₁ + Wd ₂₂ ... The strength and the distance between each corresponding end Wd ₁ , Wd ₂ are set, in which case the magnetization strengths of the second and third magnetic poles P ₂ , P ₃ are large enough to saturate the magnetic tape, for example

It is good to select so that.

The magnetic erasing head HE in FIG. 30 is a case where a single recording track is erased. However, when the recording track is used as a single track and two tracks, the magnetic erasing head H _E may be configured as in the 32nd degree. That is, in FIG. 32, the recording track t is used as a single track and its entire width W is used, and when it is used as two tracks, the single track t has two tracks t ₁ and t ₂ having a width W ₁ and these tracks t. ₁ and is divided as a guard band of tg width W ₂ between t _2.

Here, the self-erasing head H _E is welded to the full width W of the single track t, the length of which is equal to the first magnetic pole P ₁ of W or more, and the upper portion of the track t ₁ , and has a length equal to or greater than the width of the _first track t. The first magnetic pole P ₁ and the second magnetic pole P ₂₁ having a different polarity are treated along the guard band tg in the middle of the track t ₂ , and the second magnetic pole P ₂₂ having a different polarity from the first magnetic pole P ₁ and the upper side of the track t ₁ . The portion of the second magnetic pole P ₂₁ is shorter than that of the second magnetic pole P ₂₁ , the third magnetic pole P ₃₁ having the same polarity as the first magnetic pole P _1, and the middle of the track t ₂ along the guard band tg; In the track t ₂ and the guard band tg, each treat width is shorter than that of the second magnetic pole P ₂₂ , and is composed of a third magnetic pole P ₃₂ of the same polarity as the first magnetic pole P ₁ . Thus the distance between the lower ends of the second and third magnetic poles P ₂₁ , P ₃₁ Wdo ₁₁ , the distance between the lower ends of the second and third magnetic poles P ₂₂ , P ₃₂ Wd ₀₁₂ and the second and third magnetic poles P ₂₂ , P ₃₂ The magnetization strengths of the magnetic poles P ₂₁ , P ₂₂ , P ₃₁ , and P ₃₂ in combination with the distance between the upper ends of the tracks Wd ₂ are the conditions for the recording track t of the magnetic erase head at the tracks t ₁ , t ₂ and the guard band tg, respectively. Select to satisfy the following conditions.

In addition, although the width direction length of the recording track of the second magnetic pole is determined according to the magnetization intensity, it is important to determine the magnetization strength and the length so that the distortion (distortion rate) is less than or equal to the desired value in the reproduction output. 30, 31 and 32, the distortion of the reproduction output does not increase even if there is a difference in the width direction of the magnetic tape, as shown in FIGS.

In addition, when the third and fourth magnetic poles are set in addition to the first and second magnetic poles, the second, third and fourth fourths may be used so that the distortion of the reproduction output becomes less than a desired value. The magnetization strength of the magnetic pole of ..... and the width direction of each recording track may be selected.

In addition, the shape of the first, second, and third cathodes is not limited to spherical and circular, but may be any shape, and these magnetic poles may be permanent magnets or electromagnets, In addition, the magnetic erasing head can be configured by combining them.

According to the present invention described above, the structure is simple, the erasing is assured, the size can be reduced, the erasing power is not required, and the erasing power can be used as compared with the AC erasing, and the distortion of the reproduction output can be reduced. A magnetic erasing head can be obtained.

Claims (1)

As described in the text and shown in the drawings, the main magnetic poles and the sub-poles are arranged in parallel, such as scanning the same recording tracks of the magnetic recording substitutes, respectively, before and after, and the main magnetic poles in the width direction of the recording tracks. At the same time, it is possible to obtain a direct current magnetic field of sufficient strength to magnetically saturate them in the magnetic recording medium, while having a length of two or more widths, and the negative magnetic pole is approximately the width of the recording track in the width direction of the recording track. It has a length of about half and at the same time gives the magnetic recording medium a DC magnetic field equal to or greater than the coercive force, and magnetizes the components in the scanning direction of the residual magnets in opposite directions by the cooperation of the main and sub-poles. The main stimulus and the negative as the erase magnetization trajectory, which is a plurality of divided magnetization trajectories, are formed in the recording track. A magnetic erasing head, characterized in that the magnetic pole is configured.

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