DE1524751A1 - Magnetic recording heads - Google Patents

Description

iir SYLON RuSJiARDH AND DJdVJiLOJfMIaNT COMPANY LIMITiSD, Faggs Road, Bedfont, Feltham, Middlesex, England

Magnetic recording heads

.ώ-finding applies to magnetic recording heads of the type such as for corporate purposes in recording speech Music and pictures, i.e.! TV pictures and also for knowledge economic purposes, such as the recording of data and information, that are not language or music are used.

Efforts have long been made to record very high frequencies on magnetic tape and at the same time reduce the speed at which the bar must be moved to record a given upper frequency, as this reduces the amount of tape required for the These attempts have been made in two directions, one being directed to making recording heads with ever decreasing gap widths and, second, aiming to improve the tape so that the same signa can absorb ie hönerer frequency, the final Zie ricritung in any case there needs to increase the .Packdichte, ie the number of complete Flußumkehrvorgänge that £ eüene length in a £ Q, such as 2.5 cm of tape, can be added Previously, 10 such reversals of magnetic fluxes per 2.5 cm were considered an acceptable pack dense considered unu this V / ert was more or less a c Standardwe

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In order to achieve a frequency of 15,000 phases / sec. to record The lowest belt speed was 58 cm / sec * At the moment However, significantly higher packing densities are required, and the essential problem on which the invention is based exists therein to provide a recording head which in aer Ia ^ e records must be made on a magnetic tape with a very high packing density.

The magnetic recording head of the present invention is thereby gekennzeicn.net that a primary magnetic circuit with a Recording gap and with a winding, and a secondary magnetic circuit with two arranged in aostand to each other Legs and are provided with a bond, the magnetic Circles are arranged so that one leg of the secondary circle is opposite to the part of the primary circle, which has the gap, vt if a part of the one tavern is on the weft side of the center line of the gap and the other Legs of the secondary magnetic circuit are arranged opposite the surface of one leg of the primary circuit and there is a gap between the magnetic K-irons which is sufficient to allow the magnetic to pass through To enable tape, the signals to be recorded are passed through both windings.

An impedance can be switched in series with one or both windings and the impedance can simply aroeiten as resistance or can contain recative elements. By both turns or by separate turns of the two circles, a Bias current are passed through.

The invention is hereinafter referred to by way of example explained on the attached drawings:

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Fig. 1 shows diagrammatically the recording flow as it is in FIG Oxide layer of the recording area with a recording head conventional design according to the state of the art

Fig. 2 is a of FIG. 1 similar diagram, and shows the same recording head according to the prior l'technic with Winer higher Aufzeichnungsfiußdichte in the Spait _o Fig. 3 shows the effect of applying diagrammatically shows the shape of an outer auxiliary field on the head of FIGS. 1 and 2.

FIG. 4 is a diagram showing how the flow distribution is changed by the arrangement of FIG.

Fig. 5 is a diagram showing the band in which the recording flow density between two and three hundred oersteds,

Fig. 6 diagrammatically shows a recording head according to the invention.

Fig. 7 shows the recording head of Fig. 6, the Direction of the recording field is reversed.

In all of these diagrams the proportions between are different Elements have been chosen to facilitate the following explanations and they are not in agreement reproduced with the practical requirements. One of the development directions given above for the purpose of Increasing the packing density consisted of increasing the length of the recorder. opening gap progressively decrease, whereby it is natural understands that the actual recording is caused by leakage takes place outside the actual gap because the tape does not pass through the gap. This leakage flow can spread over cover a relatively large area. In the course of this development, so-called Mfckro columns were finally developed been where the length of the actual recording column

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is reduced to a few microns. It has been found, however, that with a progressive reduction of the gap the drainage the improvement became progressively smaller, so that the intended results could not be achieved by simply the width of the recording gap has been reduced. The development of magnetic tapes has reached the stage where it was known that higher densities, as far as tape is concerned, could be achieved than through the recording headers could be achieved with a microgap. It was then found that the difficulty was caused by at least partial demagnetization of the recorded object was caused, sooald the same passes through the hand field after leaving the recording gap.

Fig. 1 shows diagrammatically a recording head 11 of conventional design having a recording gap 12, the flow O in the gap being 1000 Oerstedt. The magnetic layer IJ of the magnetic tape is bent past the gap 12. The base material of the tape is not shown. The leakage flow out of the gap 12 is not uniform and consists of a band 14 in which the flux density is less than 1000 Oerstedt, a band 15 where the flux density is 200 Oerstedt, a band 16 in which the flux density is above 300 Oerstedt lies and continues a band 17 "outside of which the flux density again falls below 300 Oerstedt.

Modern recording tapes are made to have a coercivity such that a flux density of 200 Oerstedt is required to determine the direction of magnetization the oxide particles of the coating during the recording process to change. Assuming that the oxide layer 13 moves in the direction of the Pi'eila 18 according to FIG. 1, the result is

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that a particle A in the layer completely escapes the magnetization, since the part of the layer in which the eloe is located passes through the field with a flux density of less than 100 oerstedt. On the other hand, a particle B, which is located approximately in the middle of the coating 13, is magnetized in the direction of the field, since it passes between the outlines 15 and 16 and is subjected to a flux density of about 250 oerstedt. A rope 0, which is much closer to the surface adjacent to the recording gap, is also completely magnetized, since it passes through two separate areas of the tape bounded by the outline 16 and 17, where the magnetization of 30 ^ Oerstedt lies. The distance between the centers of these areas is given by dimension 1 in the Pig. I reproduced.

It will be understood that the magnetic layer 13 is not to its full extent in the arrangement according to the Pig. I is used because the leakage flux from the gap 12 in the head is not sufficiently strong to broaden through the entire thickness of the magnetic layer. If the flux density in the recording gap is now increased to 2000 Oerstedt, ύύτ hand flux will be strong enough to magnetize the entire thickness of the magnetic layer, since an outline 19 "which shows a flux density of 300, closely adjacent to the far edge of the coating runs. For this reason, even the most distant particle in the oxide coating is subjected to a recording flow greater than 200 oerstedt. However, increasing the flux density and spreading of the Mandflueeee for recording increases the dimension 1 very considerably. As soon as the dividing B by this

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If hand flux passes through it, it will be magnetized when it is at point 21, but if at the point in time it has a point 22 on the opposite side of the 2OO / 3OO Oerstedtbandes reached, the direction of flow in the Head upside down, as there is a response to the second half of an AC curve, the first half of which is magnetizing at point 21 and then of course the tape is completely demagnetized. This effect leads to one Loss of information when using the tape for recording data is applied and still causes distortion when the tape is used for recording speech and music and images will. The only technical solution is to increase the tape speed or the greatest recording frequency so that such demagnetization cannot occur.

Figure 3 shows diagrammatically the effect of applying a field 0q through the gap 23 of a recording head 241 and simultaneously applying a second field O in a direction perpendicular to the direction in which the flux passes through the gap. A Urar scissor line 25 indicates a specific flux density of, for example, 200 Oerstedt in the hand river. At point 26 of outline 25 the direction of the edge flux is perpendicular to face 31 of the recording head and the auxiliary flux acts in the opposite direction with the same flux density so that the resultant flux at that point is only zero. At point 27 on contour line 25, the marginal flow acts in the direction of line 28 and leads to a flow component having a size 30 in a direction perpendicular thereto. Thus, the resulting flux acting at this point in a direction perpendicular to the face 31 of the head is represented by the line 32. Acts at point 33

the flow 0q ifl the direction indicated by line 34, while the auxiliary flow has a direction and magnitude as represented by line 35. At the point 36, the flow 0 _{& has} a magnitude and direction as represented by the line 37 and the two components are represented in a corresponding manner by the lines 38 and 39. Of course, the flux component 39 is added to the flux due to the auxiliary field, as shown by the line 40. At the point 41 the entirety of the field 0n is represented by the line 42, the auxiliary field 0 ** as represented by the line 43 is added.

The result of the vectorial addition of the main field and the auxiliary field is shown in FIG. 4, based on which it it is apparent that the flux density on the left side of the recording tape 23 is very small and easily so insignificant can be made that no change whatsoever in the magnetization the belt surface occurs. On the other hand, there is a

Split small area 44 on the right side of the recording steae "i-ee 23, where there is a concentrated high flux density and this flux density can be considerably above the minimum, such as it is entirely necessary for magnetizing the magnetic layer of the tape.

Figure 5 shows that the effect of distorting the field is to form a single narrow band 44a in which the flux density is sufficiently high to change the magnetization of the magnetic layer 13. This tape extends through the entire thickness of the magnetic layer, and the distance 1 is now very small. FIG. 6 shows one possibility in which the object according to the invention can be achieved in practice

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The recording head comprises a primary magnetic circuit 45 with a core 46 having an excitation winding 47 and a recording gap 48. A secondary magnetic circuit 49 has two legs and is positioned adjacent the primary magnetic circuit such that a leg 50 which forms a focusing pole is opposite the recording gap 48 with a portion of leg 50 on either side of the centerline Recording gap is angeordeet. The other leg 51 of the magnetic secondary circuit 49 is adjacent to the left leg 52 of the primary circular core. The tape (not shown; passes between the primary and secondary circuits. The secondary circuit is provided with a winding 52, and the excitation signal appearing at terminals 53 and 54 is applied to both winding 47 and winding 42, and an impedance 56 is connected in series with the winding 52. Optionally, there can also be an impedance in series with the winding 47 on the primary magnetic circuit. The impedance 56 can have a resistance or can have a reactive (inductive or capacitive) element through that the flow phase formed by the recording head and the auxiliary head can be adjusted to achieve the effective results.The connections of the windings are such that the main _{recording flow j # R} in the direction of the arrows 57 and the auxiliary flow 0> at the same time in the direction of the arrows 58 The gap between the arrangement of the primary magnetic circuit 45 and the two legs of the secondary magnetic circuit are such that the majority of the recording flux passes through the gap 48. However, a (bearing of the flow in the primary circuit occurs in the sonic 51 of the secondary

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circle one. A small portion of the flow in leg 52 of the primary circuit enters the leg 50 via the part of the gap at 59 and returns to the leg 60 of the primary circuit at that part of the spaloes 61, while that part of the flow of the primary circuit that flows into the leg 51 of the secondary circuit enters, also exits via part 61 of the gap and thus returned to leg 60 of the primary circuit wira. The result is that a single bana is formed on the portion 61 on the two heads where the magnetizing flux is highly concentrated and its density isx sufficiently high to change the magnetism of the magnetic section of the tape over its entire length

JjJs sicti naturally understands that the main part of the river of the secondary magnetic circuit passes through the primary circuit.

In the part 61 of the gap between the primary and secondary magnetic circles can also be explained in other ways. If at a specific point in time the end of the leg 50 Has N polarity, the pole 62 of the primary circuit also has Η polarity and two poles repel each other and only a small magnetic flux occurs between them. On the other hand, if the pole 63 of the primary circuit has Sr-pairing, a tightening takes place between the same and the end of the leg 50 and this results in a high concentration of the ma # g netic flow.

6 shows the conditions as they are in an inventive Head, with the field acting in one direction in the two magnetic circles, and this would be act in the state where half a phase of the applied

drawing signals is present.

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Fig. 7 is a repeat of Fig. 6 and shows conditions during the other half phase where the flow due to the Signal in the direction of arrows 64 in core 46 of the primary circle and acts in the direction of arrows 65 in the secondary circuit ", using the explanations relating to FIG. 6 on the head shown in Fig. 7 it appears that the main part of the flow is still through the part 61 of the gap between passes through the heads and only a small part between the part 59 and this gap, the relative sizes these parts are equal »This means that the flux in the part 61 is capable of the material in the magnetic rail to completely magnetize while the flux density in the * ieii 59 of the gap does not matter to the magnetic state to change the magnetic layer.

So far, the description of the head according to the invention is on the application of a recording signal has been limited. If it is now necessary, a bias signal tbtnffall To bring into use, the same is also applied to both windings 47 and 52. If applicable · can an arrangement for regulating the size of the preload »» stream to be provided on the two heads, and swar Bi $$ iiel * »r ~ wise with another separate arrangement for controlling of the bias current in the second circuit 49 * This bias current is normally an alternating current with a »frequency higher than the highest signal frequency to be recorded.

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Claims (7)

Patent Attorneys Dipi.-ing. Walter Meissner -> | J. Dipi.-ing. Herbert Tischer BERLIN 33, HERBERTSTRASSE 22 MUNICH ■ Speaker: 8 87 72 37 - Wire word: Invention Berlin debit account: W. Meissner, Bertin West 12282 credit account: W. Meissner, Berliner Bank A.-G., Depka 36, Λ _, __, ,., __, ", w 7 KA ι 1 Berlln-Halensee, Kurf0rstendamm13O ΐ BERLIN 33 (GRUNEWALD), the · * &. ^ * 'i4psylon üeseardh and Development Company Ltd. Claims 1. Magnetic recording head, characterized in that a primary magnetic circuit (45) with a recording gap (48) and with a winding (47) »and a secondary magnetic circuit (49) with two legs (50, 51) arranged at a distance from one another. and a winding (52) are provided, the magnetic circuits (45, 49) being arranged so that a leg (50) of the secondary circuit (49) is opposite to that part of the primary circuit (45) which is the gap (Aö) , with a part of the one leg (50) on each side of the center line aes .Spaltes present and the other leg (51) of the secondary magnetic circuit (49) is arranged opposite to the Ooerfläche of one leg of the primary circuit, and there is a gap between the magnetic circuits which is sufficient to allow passage of the magnetic tape, the signals to be recorded being guided through both windings (47 * 52). 2. Magnetic recording head according to claim 1, characterized in that that an impedance is connected in series with a winding (47). 3. A magnetic recording head according to claim 2, characterized in that a further impedance is in series with the other winding (52; gencüal Lcjb. 009840/1591 4. Magnetic recording head according to claims 2 and 3 »thereby marked. » that the impedance or at least one of the impedances is a pure resistance. 5. Magnetic recording head according to claims 2 or 3 »daduroh, that the impedance or at least one of the impedances is reactive so as to be able to adjust the relative phase of the current through the two windings (47» 52). 6. Magnetic recording head according to any one of the preceding Aneßrüohe, characterized in that an arrangement for applying a bias voltage to the windings (47 »52) is provided let. 7. A magnetic recording head according to claim 6, characterized in that there is provided means for controlling the magnitude of the bias current in the windings (47152). θ · Magnetic recording head according to claim 7, characterized in that an arrangement for the control of the voltage current is provided in the second winding (52) 009840/1591