DE3121792A1 - Magnetic head arrangement and process for its production - Google Patents

Abstract

Magnetic head arrangement which serves for carrying out multi-channel recording is specified. The magnetic head arrangement has for this purpose a rotating head wheel, on the circumference of which at least one group of magnetic heads is arranged in such a way that the distance of the head gaps is smaller than the sum of the width of neighbouring legs and the latter touch one another. Furthermore, a process for the production of a particularly advantageous embodiment of the magnetic head arrangement is specified, in which ingots are used for forming the individual magnetic head arrangements from three mutually parallel layers, cutting them open at a predetermined azimuth angle for forming the working gaps.

Description

Magnetic head assembly and method for their

Production of prior art The invention is based on a magnetic head arrangement according to the genre of the main claim.

From DE-OS 29 52 627 a rotating magnetic head assembly is already with a plurality of magnetic heads aligned essentially in the scanning direction known for a multi-channel magnetic tape recorder and / or reproducer. That Device contains several rotatable magnetic heads, which essentially simultaneously Write several oblique and parallel tracks on a magnetic tape.

The magnetic heads are as independent transducer units on one Head support plate attached so that it is substantially aligned with the scanning direction are. The known magnetic head assembly has the disadvantage that the distances of the effective head split in the scan direction by the physical expansion of each Converter arrangement are limited downwards and thus the desirable tight arrangement is not feasible.

From DE-OS 29 34 969 a magnetic head is also known in the parts of the magnetic core are cut away on the sides of the working gap However, it concerns measures for the subsequent application of a certain Molten glass for the purpose of releasing tensile stresses in the material used as a magnetic head monolithic ferrite crystal.

Advantages of the Invention The Na gnet} plunger arrangement according to the invention with the characteristic features of the main claim has the advantage over this, that the distances between the transducers in the scanning direction can be very small. As another The advantage is that the assignment of the both working column to one another, in particular their distance a across the written tracks of completion and therefore not unwanted by external influences can be changed.

The measures listed in the subclaims are advantageous Developments and improvements of the magnetic head arrangement specified in the main claim possible. It is particularly advantageous that many magnetic transducers are produced in a monolithic manner A high yield with a very uniform result can be achieved in one operation is.

Exemplary embodiments of the invention are shown in the drawing shown and not in the following description; explained. It shows Fig. 1 is a highly schematic representation of the tape run around the scanning device of a magnetic tape recorder, in which the magnetic head arrangement according to the invention can be used, FIG. 2 shows an exemplary embodiment a magnetic head arrangement with two separately manufactured magnetic cores and working gaps, Fig. 3 shows a magnetic head arrangement with a three-legged magnetic head, FIG. 4 shows a ferromagnetic head Block in different processing stages for the preparation of an arrangement according to Figure 3.

Description of the invention In Fig. 1, a magnetic tape 5 is through (not shown) deflection and guide elements guided around a head wheel 6 that it this wraps around at an angle of slightly more than 1800 and forms half an elix, so that the arranged on the head wheel 6 magnetic heads 1, 2, 3, 4, the magnetic tape 5 in a sequence of oblique to the tape edge and parallel track cuts describe. Of the I-Ilgnetköpfe arranged on the head wheel 6 each form heads 1 and 3 and 2 and 4 a recording and reproducing channel, respectively.

In the case of a channel recorder, it is because of the division the information on at least two parallel tracks expediently that both magnetic heads have a small distance from each other in the scanning direction so that in slow motion or time-lapse playback or if there is insufficient guidance in the neighboring lanes approximately the same information is laid down, which defeats the structure of the image or is only disturbing to a small extent It is still he wishes, that to achieve high recording densities the tracks with very little or completely can be recorded without mutual gaps. To avoid crosstalk from neighboring To keep tracks within limits during playback, it is necessary that in adjacent Traces of similar information are included. For the same reasons it is desirable that all line sync signals are recorded in adjacent tracks side by side will. from this it follows that the Spaltab was an integer b in the scanning direction It should be a multiple of the recorded line length so that the two are parallel the video signals to be recorded meet the above requirements. The amount b must be computationally insignificant due to the influence of the belt speed vector Getting corrected. A similar correction is also made when dimensioning the distance a in the cross direction to the main scanning direction because of the tape speed vector necessary.

To further reduce crosstalk, it is known to use the azimuth angle to design the head column differently for the recording of adjacent tracks, This means that if there is a lane deviation, as little information as possible about the undesired information is available Track is read. With a head distance a across the track direction of 1.3.5 ...

Track spacings must therefore be the azimuth angles α, ß of the two adjacent magnetic heads 1, 2 or 3, 4 are different, while with an amount a argon 2,4,6 ... track spacings the azimuth angle α of both Magnetic heads can be the same. In this case the azimuth angle arrangement is the opposite required for the head pair on the opposite side of the head wheel.

In the magnetic head assembly of Figure 2, the two are magnetic heads 1, 2 arranged so that the distance b of the head gaps 5, 6 is greater in the scanning direction is than the width of one core half 7, 8, 9, 10. The two outer core halves 7, 10 are wound by the excitation coils 11, 12, while they face each other on core halves 8, 9 of the two magnetic heads 1, 2 lie close to one another.

The distance b is therefore smaller than the head width.

The heads each touch one half of the core. The occurring magnetic crosstalk must be compensated for by suitable circuit dimensions. Such compensation circuits are known per se and are state of the art.

If the distance b is further reduced, according to Pig. 3 the two mutually facing core halves 8, 9 fused into one unit. It This creates a three-leg magnet head with the width of the inner leg corresponds to the distance b in the scanning direction. The azimuth angle is expedient α of the two working columns 21, 22 chosen to be the same, which makes a special one expedient Arbeitsverfabren for the production of such a maguet head arrangement can be applied.

The three legs 23, 24, 25 are formed in a known manner of the working column 21, 22 connected to one another. Through recesses 25 in the area of the working gap 21 and 26 in the area of the working gap 22 becomes the gap width brought to the desired wetness and at the same time realized the track spacing a.

The outer legs 23, 25 of the three leg magnetic head arrangement are wrapped by the excitation windings 27, 28. Here, too, must through the application suitable compensation circuits the occurring magnetic overspread as a result of the common third leg 24 are suppressed.

Fig. 4 shows that to produce a magnetic head assembly according to Fig. 3 A block consisting of three layers 31, 32 3 @ after the introduction of the Bores 34, 35, which in the finished magnetic head arrangement, the winding window represent, can be connected with glass solder, whereby the working gaps 37, 38 are formed. With the help of parallel cuts leave at the angle α A number of individual magnetic head assemblies result from the block shown. 40, 41, 42 win. The processing steps corresponding to the recesses 25, 26 in FIG. 3 to determine the head gap width and the track spacing a can be made by introducing of blind bores, of which leu / L, 3, 44. 45 some are indicated, already before perform the cutting of the single magnetic head assemblies.

Claims (13)

P a t e n t a n s p r ü c h e 1. Magnetic head arrangement for a magnetic tape recorder, especially for a multi-channel magnetic tape recorder for scanning a magnetic tape in oblique, mutually parallel, tracks through one on the circumference with several magnetic heads equipped head wheel, characterized in that the bs-tantl of Konfstalte G 6, 21, 22) k @ one selected as the sum of the width of adjacent head legs (8, 9) and this one is touching. 20 magnetic head arrangement according to claim 1, characterized in that the mutually benign thighs of the two articular fissures (21, 22) -provided Magnetic head arrangement formed in one piece (24) in the manner of a three-legged magnetic head is. 3. Magnetic head arrangement according to claim 1 or 2, characterized in that that the distance (b) of the working column in the scanning direction is essentially one line of the recorded video signal or an integral multiple thereof. 4. Magnetic head arrangement according to one of claims 1 to 3, characterized in that that the track spacing (a) is essentially an integral multiple of the track width is equivalent to. 5. Magnetkopfanordndng according to one of claims 1 to 4, characterized in that that at a track spacing (a) a measure that essentially the track width or corresponds to an odd multiple thereof, the azimuth angle C P ft), one Magnetic head arrangement are selected unequal. 6. Magnot head arrangement according to one of claims 1 to 4, characterized in that that at a track spacing (a) which is approximately an even multiple of the track width corresponds, the azimuth angles (db) of a magnetic head arrangement are chosen to be the same. 7. Magnetic head arrangement according to claim 6, characterized in that b Arrangement of several measuring head arrangements around the circumference of a head wheel, the azimuth angles successive magnetic head assemblies are chosen differently. 8. Magnetic head assembly according to claim 3, characterized in that Track width and track position through different recesses (25, 26) on each different sides of the working column (21, 22) are formed. 9. Magnetic head arrangement according to claim 3 or 8, characterized in that that the azimuth angles (α) of each working gap are chosen to be the same. 10. A method for manufacturing a magnetic head assembly according to a of claims 3, 8 or 9, characterized by the production of an ingot three mutually parallel layers (31, 32, 33) by melting to form the working gap (37) 8) and cutting the ingot through several lXarcillel cuts at a predetermined azimuth angle (4) to form the individual magnetic head arrangements 11. The method according to claim 10, characterized in that the recesses (25, 26) after the ingot has been separated. 12. The method according to claim 10, characterized in that the recesses (43, 44, 45) are formed before the ingot is fused. 13. The method according to claim 10, characterized in that the recesses (43, 44, 45) to form the track widths through a grinding process after melting and before the ingot is separated.