DE1962544C - Pole mirror surface of a magnet head - Google Patents

Description

!! Reduce the area of the parallel guide of the magnetic tape device,

changes continuously at the polar mirror surface (FIG. 8). To avoid the difficulties mentioned

2. Pole mirror surface according to claim 1, characterized it was also known in the area of the working gap characterized in that in a manner known per se on the one hand and on the incoming or outgoing on the other hand, on the pole-mirroring surface of the magnetic head (310) on the other hand, various to use the entire width of the magnetic tape in a radius of curvature, which is the angle to the recording track grooves (312) stand changes / between magnetic tape and pole arranges are. Take into account the mirror surface in these areas. It

it turned out, however, that this arrangement also does not meet the requirements, because between two

successive areas changing the

Radii of curvature is discontinuous. This also results in discontinuous changes on the magnetic tape acting forces, through the effect of which the ma-

The invention relates to the polar mirror surface of a 30 gnetband flutter movements. These result in a magnetic head, which along the recording track results in a non-uniform signal transmission between the areas of the working gap and its open-ended magnetic head and magnetic tape,
The disadvantages of the known devices have radii, for recording / sensing of according to the invention, that signals on a magnetic tape of high transport speed 35 the radius of curvature of the pole mirror surface as a whole, which is in the the Ben i area of the parallel guidance of the magnetic tape at the surfaces of the working gap and its tapering / starting from the pole mirror surface changes continuously. Due to the constant running sides at different distances to the pole change of the radius of curvature of the pole mirror surface mirror surface is guided. It is known (US Pat . area is kept exactly constant,
An embodiment of the invention is explained in more detail on magnetic tape between the pole mirror surface of the hand of drawings.
gnetkopfes and the magnetic tape an air film from 45 F i g. 1 shows the known embodiment of a Mab figure. These devices have a gnethead on both sides, the radius of curvature R being constant; Magnetic head tape guide means provided by F i g. 2 shows the known design of a Madie the tape with the transport means at a standstill on the gnetkopfes, which is placed in different, η different pole mirror areas of the magnetic head. have the same radii of curvature
However, there is an increasing 50 F i g for the belt movement. 3 also shows the form. i ^ a Magnetmende transport speed, so forms between a known type, the pole mirror surface of which the strip surface and the pole mirror surface has different radii of curvature;
of the magnetic head, an air film which shows the tape of FIG. 4, which lifts off in different areas of the pole mirror surface of the magnetic head and which is attached to FIG. 3 indicated angle of inclination of the polar mirror this in the case of the working gaps in a very 55 area with respect to the horizontal;
small distance transported in parallel. In this FIG. 5 shows the manner in the different areas by maintaining a distance existing values of the radius of curvature of the Mades between pole mirror surface and magnetic tape a gnetkopfes, which in FIG. 3 is indicated;
long service life of the Magnetban Jes due to a very f i g. 6 shows, on the basis of a diagram, the reduced wear of the magnetic strip coating of the second derivative of the pole surface area. On the other hand, however, there is a change in work;

gap is the distance between the magnetic tape and the pole F i g. 7 contains the diagram of the surface ne-

mirror surface so small that the quality of the signaling angle of a pole mirror surface according to the present

Recording / playback is hardly affected. lowing invention, the pole face change in

It was found that the 65 F i g. 6 is shown;

Air bearing formed distance h between pole mirror F i g. 8 shows the poismatic surface of a magnetic head

The surface of the magnetic tape and the surface of the curvature, which are indicated by the diagrams in FIG. 6 and 7

radius R is directly proportional to the pole face. Since everyone is described.

■ never polsp'icgel area of the in Fig.! shown üfflMietkopfcs! 0 has the constant curvature pathdfus / ?. In the middle of the Polspicgclflache 14 the 'working gap i2 is arranged. Due to the rapid transfer of the magnetic tape 16 from the pay-off reel 18, the take-up reel 20, an air film is created between the pole mirror marriage 14 and the magnetic tape 16 indicated sector a, b the wrap angle λ. The in Fig. 2 illustrated known embodiment magnetic head cs ItO contains a pole mirror surface with different radii of curvature. The Magnet-S is divided into a read head 112 and an onf 114, which are separated from one another by the magnetic separation 116. In the area of the mounting gap 118, the magnetic tape 120 is made from the pole mirror surface 122 by the effect of an i ftf. Im kept at-a-distance. The distance between the magnetic tape, which is carried by the action of a tension-tensioning reel 124 /. To the winding reel 126 ″, results at the converging Se through an area 128 which has a relatively fine radius R _1. The air bearing Srd in area 130 which "has a large radius of curvature and which maintains the working gap 118 ent-S. On the trailing side of the magnet head there is an area 132. the

& fe

X., which in turn has a certain radius, which preferably has the S ' ^CIC »°» like the radius of curvature of the A »^ 218. Finally, there follows a flat part *** ™ ^x . ° mirror surface between point X ,, unu ocr am. » (ends page 226 of the magnetic head.

The diagram shown in FIG. 4 shows the course of the gradients S, which exist between the various points of the ", o mirror surface of the magnetic head 210" shown in FIG to the point * ,. DicMcigung ermau .sich L between the points X and X and We bt in the range 220 up to the point aT _{3 konstan;?} between> ₅ points X ₃ and X, takes this as-.cigung to in the field 222 and remain ■ between the point X and the trailing edge 226 konstnD c Fig. 5 shows the diagram of the AbleitunBsCunKUon gradients shown in Figure 4 _n of g in F i.. De Kurv .K * o has the value of 0 between the leading edge M6 and the point X _v Able.tungswert remains konsun between points X and a%. then takes again the value <> until χ to the point and be holding up /.um point X a K ons below <value · Off * ₅ the diagram shows ^^^, ^ 4 ^ function between the flat ™ ^L "™ ^{l" "c"} _n V_ at the incoming side and Zvi ^ cndcn "chen Area parts 220 and 224 paragraph orm g changes.

head and thus creates a distance between the magnetic tape and the pole mirror surface. At the point where the radius of curvature / i changes to a radius of curvature /?.,. there is a sudden change in the forces acting on the magnetic tape, so that the position of the magnetic tape becomes unstable in this area middle part of the polar mirror surface has a large radius, these parts of the polar mirror surface do not produce the normal bearing forces that are necessary to maintain the desired distance between the magnetic tape and the polar mirror surface in front of and behind the short parts of the polar mirror surface, which have the small radii of curvature R _t and / ?. Under the dynamic conditions, air bubbles can form, which change the position of the magnetic tape with respect to the pole mirror surface in the working gap area.

The disadvantages of the known device according to FIG. 2 can best be explained with reference to the illustration according to FIG. In this illustration, the pole mirror surface 212 of the magnetic head 210 consists of a flat part 214 on the tapered side 216 up to a point X ₁ , which is followed by a surface part 218 between the points X "and X ₁ , which has a certain constant radius of curvature. This is followed by the area 220 in the working _gap area between the points X., and Χ. _Λ up to the area 222 between the points A ₁ and n _{pc {} ■ _md , _c dcs Mazum midpoint between

fg _A Ssspalten, urd the smallest bend ^both "^ ^e ' ^tS ' rV ^l ' _n ■ _{dcn Rcrcich} cn the radius of curvature results in each case

De Fig. Ή shows
second derivative ^
head «> according to the
the curve λ in

emerges result

Diagram of the function of the magnet

ig, being yourself

Areas in the I. As from F i g. 6th

_o transitions

a big crook

, Jen side of the magnet

Koples una the area of a small radius of curvature in the area of the working gap. The normal loading of the magnetic tape may be at a low point start with gradual increase up to a maximum stress at the working gap between the points X 'and X _('. The result is that the existing between magnetic tape and Polspiegelfläche far the tapered Area that is precisely controlled in the transition area and in the working area. For example, the distance between the magnetic tape and the pole mirror surface changes in the tapering area from 2.5 to 0.5 μ in the area of the working gaps. In the area of the working gaps, the magnetic tape is subject to great stress essential to obtain a stable air bearing. This is achieved by the small radii of curvature, which are provided in the areas of the working gaps, while between the working gaps ^ by appropriately. '

5 6

can be achieved, which gnetkopf a lower band wear under the effect of a tensile stress

have as a consequence. Forms the angle of wrap from the previous explanation, between the

tion it can be seen that along the whole of Fig. 8 the magnetic tape and the magnetic head generate a pressure,

Pole mirror surface 311 shown here would be a discontinuous If the magnetic tape were fully flexible, this would be

Change in surface curvature does not take place, 5 pressure equal to belt tension divided by the

that further at any point along the polar mirror radius of curvature. Has on exemplary embodiments

surface has only a single radius of curvature it has been shown that with a radius of curvature of

is, and that finally the whole shape of the pole mirror is 2.5 cm or larger between the magnetic tape and

Geififläche is determined by radii of curvature R ' , the magnetic head is a large distance. This

which extends uniformly along the polar mirror surface can according to a further embodiment of the invention

change. can be reduced by a series of grooves

The mentioned conditions are obtained further 312 over the entire width of the pole face for from the representations according to Figures 7 and 8. The Bandlaufrichtcng at a right angle angeord diagram of the pitch shown in Figure 7 ,? ' the net are. This results in a clear difference to 15 bearing within the air pole mirror surface, that the grooves absorb the air congestion caused by the tape movement in the diagram of the slope 5 of the pole mirror surface and reduce the bearing of the known design of a magnetic head pressure / the between magnetic head and measured of Fig. 4. The pole mirror surface of the distance existing in Fig. 8 magnetic tape is thereby rendered magnetic head is symmetrical of the two small ones. The grooves 312 are located on areas of the POI side of the line X '- O, according to this form ER-% o mirror surface having a radius of curvature R' to aufweigibt the symmetrical diagram of the slopes Sen. The distance between the magnetic tape and Polder Polspiegelflächc to Fi g . 7. Mirror surface can be used by the number of

By the fact that the Magrietband on Ma-Nuten are changed.

1 sheet of drawings

Claims (1)

1 2 but on the incoming and outgoing patent claims side of the working gap the magnetic tape is fed to the magnetic head at variable intervals or 1. Pole-mirror surface of a magnetic head, which is derived from it, results in the past the recording track in the areas of the 5 area for the proportionality of the two values Working gap and its tapering / expiring - an interruption when the radius of curvature Different radii of curvature on the sides - also kept constant in these edge areas Know how to record / sense signals. The forces acting on the magnetic tape weran a magnetic tape with high transport speeds as a result non-uniformly, so that in the area of the This is ensured by an air bearing in the areas of the working gap between the magnetic tape surface of the working gap and its tapering / ablaii- and polar mirror surfaces cannot exist Pages can be kept at different distances from the stant. This results in Pole-mirror surfaces are guided, thereby causing fluctuations in signal transmission and contact η η ζ c ί c h η e t that the curvature between the magnetic tape surface and the pole mirror radius (/? ') of the pole mirror surface (311) in the whole 15 surface of the magnetic head, vclchc the effectiveness of the