FR2554624A1 - MAGNETIC TRANSDUCTIVE HEAD - Google Patents

Abstract

THE MAGNETIC TRANSDUCER HEAD INCLUDES A RETURN FLOW PATH 19, TWO EXTERNAL POLAR ARMS 11, 14 FORMING A CONTINUOUS MAGNETIC CIRCUIT WITH THE FLOW PATH 19 AND HAVING POLAR ENDS 15, 17 MUTUALLY SEPARATED TO FORM AN INTERFERENCE PREDETERMINED LENGTH L, AND A CENTRAL POLAR ARM 9 FORMING A CONTINUOUS MAGNETIC CIRCUIT WITH THE FLOW PATH 19 AND HAVING A POLAR END 16 ARRANGED BETWEEN THE POLAR ENDS 15, 17 OF THE EXTERNAL POLAR ARMS 11, 14 IN ORDER TO FORM AN GAP BETWEEN IT- EVEN AND THE RESPECTIVE POLAR ENDS OF THE EXTERNAL POLAR ARMS. THE POLAR END OF THE CENTRAL POLAR ARM HAS A SENSITIVELY SHORTER LENGTH THAN THE POLAR ENDS OF THE OUTER POLAR ARMS.

Description

The present invention relates to transducer heads.

magnetic trices.

  Magnetic data recording according to current practice ordinarily uses a magnetic transducer head for writing and reading data on a magnetic recording medium. A magnetic transducer head comprises a small magnetic flux transport rod comprising a core typically formed of ferrite or a magnetic material deposited and incorporating an air gap, and a small winding through which an electrical current signal passes during a writing operation and from which a current signal is received during a read operation. The parts of the nucleus which are adjacent to

  the air gap are often referred to as the poles or

  polar mites, while the parts adjacent to the polar ends are referred to as the polar arms. The write operation requires a significant current intensity to produce a sufficient flow to write a magnetic data configuration on a magnetic recording medium. Typically, the flux path or the core of the magnetic transducer head

  will be brought very close to magnetic saturation during the operation-

  writing. However, kernel saturation is not desirable since the configuration of written data is distorted

by this saturation.

  A new type of magnetic recording technique uses the vertical orientation of the configurations of

  magnetic data created on the magnetic recording medium

  instead of the older horizontal magnetic data patterns that are now almost universal. The magnetic recording medium used in one type of vertical recording technique has an outer layer in which the actual data is recorded and an inner layer which provides a flux path for closing the magnetic circuit between the pins of the head. To avoid saturation of the core, it is necessary that the polar ends are relatively long (by convention, the length of an air gap is the dimension giving the spacing between the polar ends and, to remain consistent, the length of the ends is measured next polar

  the direction in which the air gap length is measured).

  It is now known that a magnetic transducer head having a relatively long polar end can be used to write extremely dense vertically recorded data as long as the polar ends do not

  not saturate and the posterior corner of the posterior pole end

  is not defined very precisely. However, the long pole ends are not suitable for reading due to the

  difficulty solving extremely tight data. An explanation

  A very useful cation of these considerations is presented in IBM Technical Disclosure Bulletin, Vol. 23, no 5, October 1980, p. 2148-2149, "Design of Separetely Optimized Thin Film Read / Write Magnetic Recording Heads". The solution proposed in this article consists of placing read and write heads cSte to cste

  on a substrate, each being optimized for its particular function

  then simply shift the composite transducer radially depending on whether you want to read or write. Other relevant references are IBM Technical Disclosure Bulletin, Vol. 14, no 4, September 1971, p. 1283-1284,

  "Composite Read / Write Recording Head" and US Patents

  United States of America No. 3,399,393, 3,881,191 and 4,277,809.

  According to the invention, a trans-

  magnetic conductor comprising a return flow path, two external pole arms forming a continuous magnetic circuit with the flow path and having the pole ends which are spaced from one another so as to form an air gap of predetermined length, and a central pole arm forming a continuous magnetic circuit with the flux path and having a pole end interposed between the pole ends of the outer pole arms in order to form an air gap between itself and each pole end of the outer pole arms, the polar end of the central polar arm being significantly shorter in length than the polar ends of the polar arms

external.

  Preferably, the magnetic transducer head comprises two windings each surrounding the flux path which includes the central pole arm and one different from the pole arms

  external, the windings being connected.

  The connection between the windings can be such

  that it produces opposite orientations for the windings.

  The polar ends of the outer pole arms

can be the same length.

  The polar end of at least one of the polar arms

  external must have a length between 1 and 10 pm.

  Preferably, the polar end of the polar arm

  central has a length of between 0.05 and 1 µm.

  Preferably, the ratio of the lengths of the most

  short of the pole ends of the pole arms external to the end

  polar mite of the central polar arm is at least about 5.

  During writing, the relatively large amount

  Aunt of flux produced by the strong writing current in the windings can quickly cause saturation of the central pole arm and it becomes substantially transparent vis-à-vis the magnetic flux. Thus, writing occurs only at the posterior corner of the pole end of the posterior outer pole arm. Reading occurs between the pole end of the center pole arm and the pole ends of the pole arms

  external, which allows a very high resolution of the configuration

  magnetic data recorded on the surface of a magnetic recording medium. The common connection of the windings being used as earth, one can simultaneously connect the free ends of the windings to the same terminal of a bipolar current source in order to produce a magnetic flux in the core

during the write operation.

  Consequently, the invention aims to propose a magnetic transducer head comprising a core which does not saturate

  during the writing operation, presenting a relative resolution-

  high during the write operation, using a bipolar write signal and having different pole arms for reading and writing, all of which form part of the

same flow path.

  The following description, intended as an illustration

  tion of the invention, aims to give a better understanding of its characteristics and advantages; it is based on the appended drawings, among which: - Figure 1 is a simplified sectional view and

  enlarged scale of a magnetic transducer head according to the invention

  tion; - Figures 2a and 2b are respectively a view

  side view in section of a first embodiment of a trans-

  magnetic duct according to the invention and a projection view of a transduction face of the head; and - Figures 3a and 3b are respectively a view

  side view in section of another embodiment of a trans-

  magnetic conductor according to the invention and a projection view of a

transduction face of the head.

  We first refer to Figure 1. A trans-

  magnetic conductor according to the invention has a core 10 comprising a return flow path 19 at each end of which there is an external pole arm 11, 14. The pole arms 11, 14 form a continuous magnetic circuit with the flow path 19. At their ends, the pole arms 11 and 14 have respectively the pole ends 15 and 17. The pole ends 15 and 17 are mutually separated from each other so as to form an air gap of a length L. Solidly with the flow path 19, there is a central pole arm 9 having a pole end 16 which is placed between the pole ends 15 and 17 and the surface of which

  is substantially coplanar with that of the pole ends 15 and 17.

  The length of the pole end 16 (the lengths of the pole ends are measured in the same direction as the length of the air gap) is substantially shorter than that of the pole ends 15 and 17. This is an important and crucial aspect of the invention. 'invention. It is convenient that the pole ends 15 and 17 have the same length. Two windings 12 and 13 surrounding the flow path 19 are respectively represented as comprising segments of turns 12b, 13a, 13c, directed, as indicated by the symbol "x", so as to enter the plane of FIG. 1 , and of turn segments 12a, 13b, 12c directed, as indicated by the symbol "'", so as to leave the plane of FIG. 1. The segments 12a, 12b, 12c together constitute the winding 12, and the segments 13a, 13b, 13c constitute the winding 13. A

  conductor 18 connects the windings 12 and 13 with orienta-

  opposite states, so they provide a bipolar signal during a write operation. Thus, the coil segments 12c, 13c respectively form the free ends of the windings 12

  and 13 intended to be connected to the outside.

  To use the magnetic transducer head of

  Figure 1 in a write operation, it is best to use

  read the windings 12 and 13 in the form of a single winding with central grip. The conductor 18 is connected to one terminal of a current source and the connection of the other terminal of the current source is electronically switched between the ends

  free of the segments of turns 12e and 13c. This produces a return

  flow path in the path comprising the outer pole arm 11, the flow path 19, the outer pole arm 14 and the air gap between the pole ends 15 and 17. Since the smallest cross-sectional area of the pole arms 11 and 14 is much larger than that of the central pole arm 9, almost all of the flow passes through the pole arms 11 and 14 and

  the writing is carried out in a conventional manner at the level of the posterior

  outer laughter of the core 10. The relatively large area of the outer pole arms 11 and 14 prevents the magnetic saturation of the core by the passage of current through the windings 12 and 13 During the reading operation, a current signal is produced

  in windings by moving a recording medium

  magnetic already recorded in front of the polar ends 15,

  16 and 17. Due to the very short length of the end -

  polar 16, during a reading operation, the resolution is appreciably improved by the use of the polar end 16 of the central polar arm 9. The central position of the polar arm 9 and the fact that the flow leaves the polar arm 9 and is divides between the outer pole arms 11 and 14, and vice versa, leads to the production of the signal in the windings 12 and 13 during the reading operations. Since the flux signal passing through the central pole arm 9 divides almost equally in the flux path 9, the opposite orientation of the windings 12 and 13 has the effect that the signal passing through the end of the segments 12c and 13c for the read operation is approximately the sum

  signals passing respectively through the windings 12 and 13.

  We then refer to Figures 2a and 2b. A first embodiment of a magnetic transducer head according to the invention is shown as being formed of a magnetic ferrite substrate 20 which forms a polar arm (corresponding

  to the pole arm 11 of FIG. 1) having a pole end 27.

  A central pole arm 22 forms a continuous magnetic circuit with

  the substrate 20 in the vicinity of a return flow path 40.

  Likewise, an outer pole arm 24 having an end

  polar mite 31 forms a continuous magnetic circuit with the central polar arm 22, which has a polar end 29, and,

  also, with the substrate 20 and comprises the flow path 40.

  The pole arms 22 and 24 and the substrate 20 can have

any suitable form.

  As shown in the projection view of the transduction face of FIG. 2b, an air gap 28 is formed between

  the substrate 20 and the central pole arm 22 by an iso- layer

  lante 21. The insulating layer 21 also serves to isolate from each other and from the central pole arm 22 the turns segments 25a, 25b, 25c of a first winding 25. The winding 25 is disposed between the substrate 20 and the central pole arm 22 and it surrounds the flow path which comprises the central pole arm 22, the flow path 40 and the substrate 20, while being substantially

  in the plane of the flow path 40. The insulating layer 21 is represented

  felt in Figure 2a to be discontinuous and, in fact, may be so, but it is more desirable that it be continuous via areas not shown in Figure 2b. In the same way, an insulating layer 23 forms the second air gap 30 between the pole arms 22 and 24 and also serves to insulate segments of turns 26a, 26b and 26c from a second winding 26 each.

  vis-à-vis others and vis-à-vis the pole arms 22 and 24.

  The insulating layer 23 is also shown to be discontinuous, and it can be, but it is better to have it

  either continuous with itself via areas not shown

  felt in FIG. 2b and with the insulating layer 21. Each of the insulating layers 21 and 23 is typically formed in at least two separate deposition or coating operations. The winding 26 surrounds the flow path which includes the central pole arm 22, the flow path 40 and the outer pole arm 24. A conductor 32 electrically connects the inner end of each of the coil segments 25b, 26b so as to produce opposite orientations between the windings 25 and 26. It must also be understood that electrical access to the conductor 32 is naturally necessary,

  and this can easily be done during manufacturing.

  Electrical connections are therefore established with the conductor 32 and with the terminal sockets of the windings 25 and 26 which are formed

  by the respective ends of the turns segments 25c and 26c.

  As shown in the lower projection view

  in figure 2b, the dimensions indicated for the trans-

  duction are L1, L2, L3, L4 and L5o The dimensions L2 and L4 are the lengths of the air gaps 30 and 28 and can be of any suitable value. The dimensions crucial for the implementation of the invention are the relative values of the dimensions L1 L3 and L5. The length L3 of the pole end 29 of the central pole arm 22 must be substantially smaller than the dimension L5 which is the thickness of the substrate 20 (the "length" of the pole end 27) constituting one of the pole arms external, and that the dimension L1 which is the length of the pole end 31 of the other external pole arm 24. As explained in relation to FIG. 1, this makes it possible to avoid saturation of the core during

  a write operation while allowing higher resolution

  during a read operation, as can be

  made using a short polar end.

  Figures 3a and 3b show another embodiment of a magnetic transducer head according to the invention

  which is very similar to that shown in Figures 2a and 2b.

  However, a substrate 34 is made of a magnetic material, which requires the initial formation of a layer

  magnetic 35 on the substrate 34, the magnetic layer 35 constitutes

  killing a first external polar arm which has a polar end 37 whose dimension is given by L5. Advantageously, a more balanced reading of the signals is carried out when L1 = L5, as indicated. For everything else, the structure presented is identical to that of Figures 2a and 2b and the comments made

  about Figures 2a and 2b apply here in the same way.

  -The operation of the magnetic transducer heads-

  ticks of Figures 2a and 3a is identical to that described for the magnetic transducer head of Figure 1. During the writing operation, the relatively large writing current saturates the central pole arm 22 and allows writing to occur at the rear edge of the outer pole arm 24. During the reading operation, the much shorter pole end 29 increases

  the reading resolution of the data.

  In a typical head of the type presented in FIGS. 2a and 2b, and more especially in FIGS. 3a and 3b, constructed according to the techniques indicated, L1 is worth 6 pm, L3 is worth 0.3 pm,

  and L5 is 6 pm. It is currently preferred that the range of long

  polar ends 27,31 or 37,31 is from 1 to 10 pm, and that the range of lengths of the polar end 29 is from 0.05 to 1 pm. The ratio L1 / L3 must in any case be at least substantially equal to 5 in order to provide the desired improvements of eliminating the saturation of the polar ends during the writing operation and improving the resolution during the 'read operation. The actual values of L2 and L4 are not important, but are typically much more

  smaller than L3, allowing high resolution for the opera-

reading tion.

  Of course, those skilled in the art will be able to ima-

  giner, from the devices whose description has just been

  given for illustrative purposes only and in no way limitative, various other variants and modifications which are not outside the scope

of the invention.

2554624-

Claims (7)

  1. Magnetic transducer head characterized in that it comprises: a return flow path (19; 40); two external pole arms (11, 14; 20, 24; 35, 24) forming a continuous magnetic circuit with the flux path (19; 40) and having pole ends (15, 17; 27, 31; 37, 31) mutually separated so as to form an air gap of predetermined length   (L); and a central pole arm (9; 22) forming a magnetic circuit   continuous tick with the flow path and having a polar end (16; 29) disposed between the polar ends (15, 17; 27, 31; 37, 31) of the external polar arms (11, 14; 20, 24; 35, 24) so as to form an air gap (28, 30) between itself and each pole end (15, 17; 27, 31; 37, 31) of the outer pole arms (11, 14; 20, 24; 35, 24 ), said pole end (16; 29) of the central pole arm (9; 22) having a length substantially shorter than the pole ends (15, 17; 27, 31; 37, 31)   external pole arms (11, 14; 20, 24; 35, 24).   2. Head according to claim 1, characterized in that it comprises two windings (12, 13; 25, 26) each surrounding the flow path consisting of the central pole arm (9; 22) and one different from the arms external polar (11, 14; 20, 24;   , 24), the windings being connected (18; 32).   3. Head according to claim 2, characterized in that the connection (18; 32) between the windings (12, 13; 25, 26)   produces opposite orientations in the windings.   4. Head according to claim 1, 2 or 3, characterized in that the pole ends (15, 17; 27, 31; 37, 31) of the outer pole arms (11, 14; 20, 24; 35, 24) have equal lengths.   5. Head according to any one of claims 1 to 4,   characterized in that the pole end (15, 17; 27, 31; 37, 31) of at least one of the outer pole arms (11, 14; 20, 24; 35, 24)   has a length between 1 and 10 µm.   6. Head according to any one of claims 1 to 5,   characterized in that the pole end (16; 29) of the pole arm   central (9; 22) has a length of between 0.05 and 1 µm.   7. Head according to any one of claims 1 to   6, characterized in that the ratio of the lengths of the shorter of the pole ends (15, 17; 27, 31; 37, 31) of the outer pole arms (11, 14; 20, 24; 35, 24) to the pole end (16; 29) of the central pole arm (9; 22) is at least about 5.