NL8601277A - Magnetic transducing head having clad core faces - has non-magnetisable gap extending between core faces and coil passing through winding aperture - Google Patents

Abstract

The magnetic transducing head comprises a magnetic core having two core limbs formed from a ferrite. The core limbs have two faces facing each other with at least one provided with a cladding consisting of a layer of an Fe-Si-Al-based alloy. A non-magnetisable transducing gap extends between the core faces. A winding aperture with an electric coil passing through is provided around a core limb. The cladding also comprises a layer of an Ni-Fe-based alloy which is provided on the core face while the layer of an FE-Si-Al based alloy is provided on the layer of Ni-Fe-based alloy. The width of the central core face parts is at least equal to the width of the gap boundary faces.

Description

PHN 11,754 1 N.V. Philips "Incandescent lamp factories in Eindhoven" Magnetic head with crevice coating. "

The invention relates to a magnetic head for recording, displaying and / or erasing magnetic information in a track of a flexible magnetic information carrier, comprising a magnetic core comprising two core parts formed from a ferrite and a contact surface along which the information carrier contacts the magnetic head is movable in a predetermined direction of movement, a non-magnetic transfer gap formed between the core parts, two coating layers of magnetic material applied to the core parts with a higher saturation magnetization than the ferrite, the coating layers of parallel widths of equal width for defining the slit width of the transfer slit, and in which central core planes running obliquely to the slit boundary planes and obliquely disposed on either side thereof, forming an angle with the central core planes, forming between the core members and the cladding layers surfaces, and a coil chamber with an electric coil passing therethrough around a part of the magnetic core.

The invention further relates to a magnetic head for recording, displaying and / or erasing magnetic information in a track of a flexible magnetic information carrier, comprising a magnetic core provided with two core parts formed from a ferrite and a contact surface along which the information carrier contacts the magnetic head is movable in a predetermined direction of movement, a non-magnetic transfer spit formed between the core parts, two coating layers of magnetic material applied to the core parts with a higher saturation magnetization than the ferrite, the coating layers of parallel widths of equal width for the defining the slit width of the transfer slit and in which core surfaces extending parallel to the slit boundary surfaces extend between the core parts and the cladding layers, and a coil chamber with a part of the magnetic core passing therethrough fitted electric coil.

3 S 3! 2 7 7 ----- «* i PHN 11,754 2

Such magnetic heads are known from European patent application EP 0125891 (herewith incorporated by reference).

It is well known to use ferrites, especially monocrystalline Mn-Zn ferrites, as magnetic core material for magnetic transfer heads, because ferrites have a number of advantages. As advantages can be mentioned, a high wear resistance, a relatively high specific resistance and good magnetic properties with regard to coercive force and permeability.

10

The magnetic heads used in today's video recorders usually have a core of Mn-Zn ferrite. Mn-Zn ferrite has a saturation magnetization of about 0.5 Tesla at room temperature, which is sufficient to meet the requirements of writing on conventional video tapes, such as CrOp tapes with a coercive force Hc of about 56 kA / m . However, if magnetic tapes with a higher coercive force are used to improve the quality of the video recording, such as Fe tapes, which have an Hc of roughly 80-160 kA / m, such magnetic tapes can no longer be described properly. The magnetic fields, which are generated by the magnetic head at the location of the transfer slit to write information on the magnetic tape, are indeed limited by the relatively low saturation magnetization of the ferrite in the core of the magnetic head. The strength of the writing field of the magnetic head is therefore not high enough to optimally describe magnetic tapes with a high coercive force.

In said EP 0125891, the problem described above is addressed by covering the core of a magnetic head on at least one side of the transfer slit with a thick coating of magnetic material with a higher saturation magnetization than the ferrite of the core, the coating layer being at least is mainly arranged on two core surfaces sloping with respect to the slit-bounding surface formed by the covering layer and mutually positioned such that a core surface running parallel to the slit-bounding surface is formed between the sloping-bounding surface, the width of which is at most equal to half the width of the transfer slit, but is preferably minimal. Namely, it is stated in the aforementioned European patent application that with increasing width of the central core plane, a side gap effect (contour effect) occurs at the transition between the core and the cladding layer in such a way that the frequency characteristic of the magnetic head in is increasingly disturbed, while the side-slit effect is hardly disturbing when the width of the core plane is as small as possible or the core plane is completely absent. However, the side slits in the known magnetic head still produce magnetic potential losses and therefore signal losses.

The known magnetic head is provided with thick coating layers, of the order of magnitude corresponding to half of the slit width of the magnetic head or half of the track width on the magnetic tape. Thick coatings have the disadvantage that they are difficult to apply and therefore require a complicated manufacturing technique. In addition, the formation of a very narrow between the oblique core surfaces is

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empty central core plane difficult to achieve with the usual cutting techniques.

The object of the invention is now to provide magnetic heads using coating layers, which have better properties for writing information on highly coercive recording media and which can be manufactured in an economically more attractive manner than the known magnetic heads.

The magnetic head according to the invention for recording, displaying and / or erasing magnetic information in a track of a flexible magnetic information carrier, comprising a magnetic core 25 comprising two core parts formed from a ferrite and a contact surface along which the information carrier contacts the magnetic head in a predetermined direction of movement movable i3, a non-magnetic transfer gap formed between the core parts, two coating layers of magnetic material applied to the core parts with a higher saturation magnetization than the ferrite, the coating layers of parallel width of the same width for defining of the gap width of the transfer splset, and in which central core planes running parallel to the gap boundary planes and extending obliquely forming an angle with the central core planes extending parallel to the gap boundary planes and a coil chamber with an electric coil arranged around a part of the magnetic core 8601277 0 to PHN 11.754 4 for this purpose, characterized in that the said central core surfaces have a width which is greater than half the width of the gap boundary surfaces .

With the magnetic head according to the invention indicated above, it has proved possible, contrary to what is stated in EP 0125891, to obtain a frequency characteristic which is not, or hardly at all, adversely affected by the said side gap effect, because there are no annoying oscillations as a result of constructional and destructive interferences occur in the frequency characteristic.

10

Measurement results show that the existing bias regarding the presence of a core section running parallel to the slit, which is between the sloping core surfaces and which is wider than half the slit width, is unfounded.

In the magnetic head according to the invention, the coating layers are considerably thinner than is the case in the known magnetic heads. This has the advantage that the coating layers can be applied to the core surfaces without complications by known methods, such as sputtering. The broad central core surfaces can also be formed using the usual mechanical techniques.

An embodiment of the magnetic head according to the invention, which is favorable from a production engineering viewpoint, is characterized in that the width of the central core surfaces is at least substantially equal to the width of the slit-bounding surfaces.

A further favorable embodiment is characterized in that on both sides of the transfer gap between the core parts and the covering layers, further core surfaces extending parallel to the central core surfaces and connecting to the oblique core surfaces extend. This embodiment, which is easy to manufacture, is particularly interesting if the magnetic head on either side of the transfer gap 30 need not be provided with recesses for locally narrowing the tread. This is possible, for example, if no long wavelength signals need to be recorded. The absence of said recesses obviously means a reduction in the number of manufacturing steps.

35

Particularly favorable results are achievable if the above-mentioned embodiments are also characterized in that the thickness of each of the coating layers is determined by the relationship: 8601277 ΡΗΝ 11,754 5 D1 ^ 1/3 · W-jC 1 —Mf / "M ^ 3 where Dj is the thickness of one of the coatings, W) the soleet width, the saturation magnetization of the material of the coatings, and Mr is the saturation magnetization of the ferrite.

An alternative magnetic head according to the invention for recording, displaying and / or erasing magnetic information in a track of a flexible magnetic information carrier, comprising a magnetic core comprising two core parts formed from a ferrite and a contact surface along which the information carrier contacts the magnetic head. is movable in a predetermined direction of movement, a non-magnetic transfer gap formed between the core parts, two coatings of magnetic material 15 applied to the core parts with a higher saturation magnetization than the ferrite, the coatings being parallel to each other with gap widths of equal width for defining form the gap width of the transfer gap and wherein core surfaces 20 extending parallel to the gap boundary surfaces extend between the core parts and the cladding layers, and a coil chamber with a coil passing therethrough around a part of the magnetic core a smooth electric coil, characterized in that the aforementioned intended purpose is characterized in that the said core surfaces have a width which is greater than the width of the slit boundary surfaces, the coating layers on either side of the transfer slit having side surfaces extending from the slit boundary surfaces to the aforementioned core surfaces and which make an acute angle with the core surfaces.

With this magnetic head according to the invention, a high efficiency and a frequency characteristic, in which the side fleck effect is barely perceptible, is also attainable. The particularly good measurement results are therefore so surprising, because the constructional measures used in the magnetic head are completely contrary to the direction indicated in the prior art.

An additional advantage of this magnetic head according to the invention is the absence of sloping core surfaces. After all, the surfaces on which the covering layers are applied do not need to be profiled, which does not considerably simplify the manufacture of the magnetic heads 8501277 PHN 11.754 6. The side surfaces of the covering layers can be formed by a laser technique known per se, during which treatment the slit is also applied to the desired width.

The angle which the said side surfaces make with the core surfaces will preferably be approximately 45 °, however good results have also been achieved with angles between 20 ° and 70 °.

The rag magnet head according to the invention, indicated above as an alternative magnetic head, is preferably also characterized in that the width of each of the core surfaces is determined by the relationship: 1/2 D2 ^ 1/2. ((Mjj / (Mf. Sin <x.)) - 1) W2. where D2 is the thickness of one of the coatings, W2 is the gap width, the saturation magnetization of the material of the coatings, Mf is the saturation magnetization of the ferrite, and x is the angle between a side face and a core face. The thickness of the coating layers determined according to the given relationship, which in practical applications is incidentally smaller than the thickness of the coating layers in the known magnetic heads, guarantees high-quality magnetic heads.

Metallic materials with a higher saturation magnetization than ferrite, which are suitable for use in the coatings of the magnetic heads according to the invention are, for example, Ni-Fe base alloys, such as Nigo Fe2g, and amorphous magnetic alloys, such as CoFeSiB, CoZrNb or FeAlSi.

The invention will be explained in more detail with reference to the drawing, in which

Figure 1 is a schematic perspective view of a first embodiment of the magnetic head according to the invention, 30

Figure 2 is an enlarged plan view of part of a magnetic head according to the first embodiment,

Figure 3 is an enlarged plan view of part of another magnetic head according to the first embodiment,

Figure 4 is a schematic perspective view of a second embodiment of the magnetic head according to the invention, and

Figure 5 is a top view of part of a magnetic head according to the second embodiment.

8601277 2 ^ ¾.

PHN 11,754 7

The magnetic head t shown in Figure 1 is suitable for writing and reading magnetic tapes with a high ewe-force. The magnetic head 1 has a magnetic core made up of two core parts 3 sn 5, which is provided with a play chamber 7 through which a coil 9 is wound. The core parts 3 and 5, which consist of a one-crystal Mn-Zn ferrite, are bonded together in regions 11 and 13 by means of an adhesive material such as glass. A transfer slit 15 is thereby formed in region 11. The core parts 3 sn 5 are provided with a contact surface 17 along which, during operation of the magnetic head 1, a magnetic tape, not shown here, is advanced in the direction of the arrow A drawn.

The parts of the magnetic heads shown therein which are visible in Figures 2 and 3 are provided with the same reference numeral as the parts of the magnetic head according to Figure 1 corresponding to the parts referred to.

As Figs. 1, 2 and 3 show, on the core parts 3 and 5, coatings 23 and 23, respectively. 25 applied. The coating layers 23 and 25 consist of a. magnetic material, for example the metallic alloy Nigo Fepn, with a considerably higher saturation magnetization than the Mn-Zn ferrite of the core. The coating layers 23 and 25 form

two parallel limiting surfaces 23A resp. 25A

(see in particular figures 2 and 3) of equal width. These slit boundary surfaces 23A and 25A define the slit width W1 of the transfer slit 15, which is filled with a non-magnetic material such as glass or quartz. At least in these examples, the direction in which the gap width is defined is oriented perpendicular to the direction of travel of the magnetic tape. Embodiments in which both said directions are not exactly perpendicular to each other are of course also possible.

30

According to the invention, between the core parts 3 and 5 on the one hand and the covering layers 23 and 25, on the other hand, central core surfaces 3A and 5A and, on both sides, adjoining these core surfaces, form oblique core surfaces 3B and 53 forming an angle with the central core surfaces. The central core surfaces 3A and 5A are almost equal to the width of the slit boundary surfaces. In the exemplary embodiments shown in Figures 1, 2 and 3, further core surfaces 3C and 5C adjoining the oblique core surfaces are further arranged, which S6Ö1277 *% PHN 11.754 8 extend parallel to the central core surfaces 3A and 5A. It is advantageous for the flux supply to the gap 15 on the contact or end face 17 to cover not only the magnetic surfaces 3A, B, C and 5A, B, C located at the level of the transfer gap. material of the indicated type, but also the other surfaces of the magnetic core adjacent to the said core surfaces adjacent the transfer gap 15, so that the core parts 3 and 5 on their side facing the gap 15 over the entire height h of a coating

are provided low. The coatings 23 and 25 can be fabricated during fabrication

The magnetic heads are applied to the core parts 3 and 5 by, for example, sputtering, electro-deposition or vapor deposition, after said core surfaces have been formed by, for example, sawing. After the covering layers 23 and 25 have been applied, the core parts 3 and 5 can be bonded together.

15

The magnetic head indicated in figure 3 has undergone an additional processing, in which two recesses 19 are provided with the aid of, for example, a laser to narrow the contact surface 17 in the vicinity of the transfer gap 15.

2β For determining the thickness D1 of the covering layers 23 and 25, use can be made of the relationship already given in the description introduction. In the embodiment according to figure 1, the thickness D1 is 3 µm. The saturation magnetization Mb of the Nigo-ejO alloy of the coating layers 3 and 5 is 1.0 Tesla and the saturation magnetization Hf of the Ni-Fe ferrite of the magnet core is 0.50 Tesla. The gap width W1 is then preferably less than 18 µm.

The magnetic head 101 according to the invention shown in Figures 4 and 5 has in principle the same properties as the magnetic head 1 already described. The magnetic head 101 comprises two core parts 103 and 105 of ferrite, which together form a magnetic core with a contact surface 117, along which an information carrier is movable in the direction indicated by arrow A for magnetic cooperation with the magnetic head 101. Around the core part 105 an electric coil 108 passing through a coil chamber 107 is arranged. The core parts 103 and 105, which are connected to each other by an adhesive layer 113 of, for example, glass, each have a core surface 103A rsp. 105A. Core planes 103A and 105A face each other and are parallel to each other. On both core surfaces 103A and 105A, a cladding layer 123, respectively. 125, 8601277 PHN 11.754 9, of a material having a higher saturation magnetization than the ferrite of the magnetic core. The coating strokes 123 and 125 have a gap-limiting surface 123A, resp. 125A of a predetermined width, the direction in which the width is defined in this example is transverse to the direction indicated by the arrow A. The joint gap limiting sections define a transfer gap 115 with a gap width W. The transfer gap is formed by a layer of a non-magnetizable material, such as quartz, which can also serve to adhere the coating layers 123 and 125 to each other.

The two core parts 103 and 105, as seen in the pipe direction A, have a wedge-shaped course in front of and behind the transfer gap 115, respectively, according to the invention it is essential that this wedge-shaped course is also present at the coating layers 123 and 125. This means that the facing layers 123 and 125 have side surfaces 123S and 125B respectively which make an acute angle ¢ ¢ with the core plane 1Q3A and 105A, respectively. The side surfaces 123B and 125B of the facing layers 123 and 125, as well as the remaining wedge-shaped course of the core parts, can for instance be realized using laser techniques known per se. In this example, angle 06 is equal to 2Ö 45®. The thickness D2 of the coating layers 123 and 125 can be determined with the relationship already mentioned in the description introductions.

In the present embodiment, wherein the saturation magnetization Mb of the Ni-Fe alloy of the coating layers 123 and 125 is 1.0 Tesla, and the saturation magnetization Mf of the ferrite of the magnetic core is 0.50 Tesla, and the gap width V2 20 µm and said angle is 45 °, 5 µm is a favorable value for the thickness D2.

Of course, the invention is not limited to the above-described embodiments and many embodiments are possible within the scope of the invention.

35 8601277

Claims (7)

Magnetic head for recording, displaying and / or erasing magnetic information in a track of a flexible magnetic information carrier, comprising - a magnetic core comprising two core parts 5 formed of a ferrite and a contact surface along which the information carrier contacts the magnetic head in a predetermined direction of movement is movable, - a non-magnetic transfer gap formed between the core parts, - two coating layers of magnetic material applied to the core parts with a higher saturation magnetization than the ferrite, the coating layers of parallel widths of equal width for defining the gap width of the transfer gap, and in which central core planes extending parallel to the gap -15 planes and inclined core planes forming an angle with the central core planes extend parallel to the gap limiting planes and - a coil chamber with an electric coil arranged therethrough around a part of the magnetic core, characterized in that the said central core surfaces have a width which is greater than half the width of the gap boundary surfaces. 2. Magnetic head according to claim 1, characterized in that the width of the central core surfaces is at least substantially equal to the width of the gap-limiting surfaces. Magnetic head according to claim 1 or 2, characterized in that on both sides of the transfer gap between the core parts and the covering layers, further core surfaces extending parallel to the central core surfaces and connecting to the oblique core surfaces extend. 30 Magnetic head according to claim 1, 2 or 3, characterized in that the thickness of each of the coating layers is determined by the relationship: D -] ^ 1/3 · W ^ (1 -Mf / Mjj), where 35 D · ] is the thickness of one of the coatings, W] is the gap width, M is the saturation magnetization of the material of the coatings and the saturation magnetization of the ferrite. 8601277 PHN 11,754 11 Magnetic head for recording, displaying and / or erasing magnetic information in a track of a flexible magnetic information carrier, comprising - a magnetic core provided with two core parts 5 formed from a ferrite and a contact surface along which the information carrier contacts the magnetic head in a predetermined direction of movement is movable, - a non-magnetic transfer gap formed between the core parts, - two magnetic material coating layers applied to the core parts with a higher saturation magnetization than the ferrite, the coating layers of parallel widths of equal width for defining the slit width of the transfer slit and wherein core surfaces extending parallel to the slit boundary surfaces extend between the core parts and the cladding layers, and - a coil chamber with electrodes passing therethrough around a part of the magnetic core Ic coil, characterized in that said core faces have a width greater than the width of the gap boundary faces, the coatings on either side of the transfer gap having side faces extending from the gap boundary faces to said core faces and at an acute angle with the core planes. Magnetic head according to claim 5, characterized in that said angle has a size between 20 ° and 70 °. 25 Magnetic head according to claim 5 or 6, characterized in that the width of each of the core faces is determined by the relationship: 1/2 D2> 1/2. ((Mb / (Mf .sin »-)) - 1) Sf2. tan <*, where 3Q D2 is the thickness of one of the coatings, W2 is the gap width, Mb is the saturation magnetization of the material of the coatings, Mf is the saturation magnetization of the ferrite, and >> - is the angle between a side face and a core face. 35 8601277