CS252260B1 - Magnetic polyvalent ferrite head - Google Patents

Abstract

The purpose of the solution is a magnetic head designed to increase the efficiency of magnetic circuits by shortening them while reducing the sensitivity of the head to external interfering magnetic fields and also designed to allow the front part of the pole pieces worn out during operation to be replaced with a new part. The stated purpose is achieved in that the rear part of the magnetic needles is assembled from a rear needle holder with a rear shielding plate, which is provided with V-grooves, vertical grooves and horizontal grooves, into which the rear V-shaped yoke with wound coils is glued, between which the inner shielding plates are inserted, these parts being reinforced with the help of inner side reinforcing plates and inner front reinforcing plates and cast with a potting compound with minimal shrinkage into a compact part and that the components of the front part of the pole pieces, which is assembled from active pole pieces and inactive pole pieces, from non-magnetic spacer plates and side connecting beams are soldered to each other with glass solder into a second compact part and these two parts are connected together via polished contact planes using outer side connecting shielding plates and front connecting plates shielding plates into one unit.

Description

BACKGROUND OF THE INVENTION The present invention relates to a magnetic multi-track ferrite head design for sensing and eventually recording very low wavelength signals on a magnetic carrier.

The known construction of multi-track alloy heads cannot be used in the production of multi-track magnetic heads from ferrite due to the different formation of working slots · For alloy heads, the magnetic circuits are mostly divided according to symmetry axis and glued into non-magnetic housings. these parts are joined together by non-magnetic metal foil forming the front working slot in known manner, for example by means of bolts, shaped clips, screws or, conversely, flexible wedges or flat-shaped springs which are inserted between the housings and the magnetic head cover. · This design of the working slots is not suitable for the construction of a magnetic multi-track ferrite head, since the ferrite in the working slots formed at the edges during the machining of the forehead and during operation breaks down, thus destroying the working slot.

For ferrite heads - unless these are ferrite lubrication heads with a gap of several tenths of a millimeter - the front working slots must be soldered with a suitable glass solder at temperatures around 600 ° C. Since it is not possible to wind the coils c in multi-track ferrite heads. the magnetic circuit of the head is divided into at least three parts, namely two front pole pieces with a working slot and a part of the rear yoke with a wound coil · The actual connection of the front pole pieces with the rear yoke is carried out in a number of ways, the difference of which depends mainly on the head structure · In principle, however, it is possible to fix the individual magnetic yoke to the front pole pieces in two ways. working slot either from the side or from the front ·

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The lateral fixation is relatively advantageous due to its large contact surface, disadvantageous in that it cannot be polished in the case of multi-track heads. Incomplete contact of these parts creates undesirable scattering, which reduces the efficiency of the head. The advantage of the front fixation of the rear yoke and the front pole pieces is the possibility of polishing both contact surfaces. However, the contact area is limited by the width of the individual tracks and the slightest deflection of the fixed yoke results in the formation of a wedge-shaped gap and thus also reduces the efficiency of the magnetic head circuit thus created.

The above-mentioned drawbacks are eliminated by the construction of a multi-track magnetic ferrite head intended for the mass storage devices of the present invention. Its essence is that the rear part is assembled from a rear needle holder to which the rear shielding plate is glued. This holder is provided with vertical grooves / V-grooves for coils and horizontal grooves for gluing the rear needles. The rear shield plate is glued with two spacer bars and a printed circuit board connection. The rear needle holder with glued back yokes with wound spools is reinforced by two glued inner side reinforcement plates, which are connected at their ends to the rear needle holder with two internal front reinforcements. Between the individual yokes are inserted inner shielding plates, which are fixed in this back part by the sealing compound with minimal shrinkage in one compact unit. The contact plane of this back panel is polished to the plane. The front piece is formed such that a non-active pole piece is formed from each side of the row of active pole extensions. Between the active and inactive pole pieces there are non-magnetic spacers and on both sides of the front part there are connecting bars, all these parts of the front part being soldered to each other by a glass solder into one compact unit. The back panel is provided with bevels to prevent glue from penetrating by capillary forces between the joint planes of the front and rear panels to be joined.

The invention will be explained in more detail and the accompanying drawings in

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- 3 examples of the construction of the magnetic 16-foot ferrite head for a magnetic carrier 1 "wide.

Fig. 1 - Fig. 3 is a front, plan and side view of the front piece of the pole pieces; Fig. 4 shows sections A - A and BB of the front piece of the pole pieces shown in Fig. 2; Fig. 5 - Fig. Fig. 13 shows details of the rear part of magnetic needles, Fig. 14 is a plan view of the rear part of magnetic needles, Fig. 15 is a side view of the rear part of magnetic needles, Fig. 16 is cross-sectional views A-A and β - O 14 in FIG. 17, the principal parts of the entire magnetic multi-track head are shown in a plan view.

Fig. 1 is a plan view, Fig. 2, and Fig. 3 in side elevation of a front piece of pole pieces 1 consisting of 16 active pole terminals 2 ^and an inactive pole nipples 6 of the working slots 8 of the seventeen. spacers and two pairs of connecting beams. All joints between the individual parts of this front piece of pole pieces 1 are soldered by glass solder.

In FIG. 4 are sectional views AA and B - B of the front portion of the pole pieces 1 depicted in FIG. 2. In section AA are shown the active pole pieces 2 ⁸ working gap Q and the side connecting the beams 2 »in cross-section B - B then define 2 ® side connection beams

In Fig. 5, a plan view of a non-magnetic ceramics lane 9 with a backshield 22 adhered, having two V-grooves 10 forming a coil space 19, is shown in plan view and in FIG. 6, sixteen horizontal grooves 11 for stitching the rear needles. 13 and thirty-two vertical grooves 12 for extending outlets 20. It further has two shoulders 23 for gluing the inner side reinforcement plates 21.

In Fig. 7, sections A-A and B-B are provided by the rear needle holder ²⁸ '

In FIG. 8 and FIG. 9, the printed circuit board 16 with sixty-six targets 28 and apertures 27 for soldering terminals 20 is shown in plan and plan view.

In FIG. 10, the shape of the inner face reinforcement plate 17 with a cross-sectional view having a bevel 25 is shown in a plan view.

Fig. 11 is a front elevational view of the inner shielding plate 18 with a cross-sectional view.

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FIG. 12 is a front elevational view and plan view of a V-shaped rear yoke 13 with coils 19 and outlets 20 wound.

Fig. 13 is a side view of the inner side reinforcement plate 21 with a bevel 25 and a cross-sectional view.

Fig. 14 is a plan view of the rear of the magnetic needle assembly 2; and Fig. 15 is a side elevational view of the rear of the magnetic needle assembly 2 with partial section BB shown in Fig. 14 consisting of the saddle holder 2β bonded by a backshield 22; the horizontal grooves 11 are glued to the sixteen rear needles 13 and thirty-two wound bobbins 19. The whole is reinforced by gluing two inner side reinforcing plates 21 whose ends are reinforced by gluing two front reinforcing plates 17 with a bevel 25. A printed circuit board is glued to the back screen 22 16 through two spacing beams 15. Throughout the holes 27 of the printed circuit board 16, thirty-two vertical grooves 12 extend through sixty-four outlets 20 from the thirty-two spools 19 where they are soldered. Between the individual rear yokes 13 with wound coils 18 are inserted twelve inner shield plates 18, which are fixed with potting compound with minimal expansion and which fill the remaining space between the inner shield plates 18, the rear yokes 13 and the rear needle holder 2. FIG. 15 is not shown for the sake of clarity.

In Fig. 16, sections A-A and C-C show the assembly of the rear part of the magnetic needles 2 shown in Fig. 14. The sections show the shapes of the individual components. These are the inner side reinforcing plates 21, the rear needle holder 18, the rear yoke 13, the rear shielding plate 22, the printed circuit 16, the outlets 20 extending into the holes 27 of the internal shielding plate 18, the V-groove 10 and the coil 1g.

Fig. 17 shows the shape of the main parts of the magnetic multi-track ferrite head before final assembly, namely the front part of the pole pieces 1, the rear part of the magnetic needles 2 with polished contact planes 26, the shape of the two outer side junction shields of the shielding plates 14 with a recess 24 for optionally checking the depth of the working slot 4 when polishing the head face.

Claims (2)

A magnetic multi-track ferrite head formed of a front pole piece and a rear pole of magnetic needles, characterized in that the rear face of magnetic needles (2) consists of a rear face holder (9) of non-magnetic ceramics with a backing screen (22) adhered thereto; to which two spacing bars (15) are glued with a printed circuit board (16) of the outlets (20) glued, the rear needle holder (9) having vertical grooves (12) for the outlets (20) of the coils (19), V-grooves (10) (for coils (19) and horizontal grooves (11) for rear yokes (13)) which are glued into these horizontal grooves (11) and which are further reinforced by gluing the inner side reinforcement plates (21) to the sides of the rear needles (13) and into the shoulder (23) of the rear needle holders (9), the ends of the inner side reinforcement plates (21) being reinforced by gluing the front reinforcement plates (17) to the rear needle holder (9) and between On the days of the yoke (13), inner shielding plates (18) are inserted, which are fixed by a sealing compound with minimum shrinkage and this rear part of the magnetic needles (2) is beveled on the inner side reinforcement plates (21) and the front reinforcement plates (17). 25) and is connected to the front pole piece (1) by means of external side shield plates (3) and face shield plates (14) in one unit, wherein the front pole piece (1) has a series of active sides on each side and the inactive pole pieces (7) and the inactive pole pieces (6) are provided with working slots (8) in a straight line without any angular deviations and between the individual active pole pieces (7). (and the inactive pole pieces (6) are non-magnetic spacer plates (5) and on both sides before The first part of the pole pieces (1) are side connecting beams (4), wherein all of these parts of the front part of the pole pieces (1) are soldered to one another by a glass solder into one compact unit. 2. Magnetic multi-track ferrite alloy according to claim 1, characterized in that the rear yokes (L3) are produced in the form of a cru V and in that the outer side connecting shield plates (3), the connecting wiper plates (14) with a recess (24) and the rear shadow of the dssticya / 32 / forms the outer magnetic shield of the entire head · 7 drawings