DE1098746B - Magnetic foil storage - Google Patents

Description

Magnetic film memory The invention relates to a after magnetographic principle working memory with circulating, a magnetizable Layer supporting disc-shaped film.

One known arrangement of this type is one of a motor driven shaft firmly connected at its lower end with a disc-shaped film, which carries a magnetizable layer and is located a short distance above a stationary one moving flat plate. This fixed plate, its distance from the foil disk is adjustable in the axial direction, has in its center, coaxial with the motor-driven Shaft, an opening through which air can pass when the film disc rotates can. Due to the friction on the side of the foil disc facing the fixed plate air is carried along in the circumferential direction of the rotating disk, at the same time a centrifugal force acts on the entrained air as a result of the rotation, which the air pushes outwards in a radial direction. In this way it forms between the fixed plate and the foil disk that runs a short distance above it an air flow, the resulting direction of which is from a circumferential direction extending and a radial component composed. So it will be based on this Way, air is constantly sucked in through the central opening of the fixed plate and to the outside between the fixed plate and the circumferential sheet of film driven. This air flow has a stabilizing effect on the sheet of film and has the consequence that this is constantly at a very small and constant distance is held by the fixed plate.

Information to be saved for recording and retrieval is either at a suitable distance above the foil disk or in a recess the fixed disk a magnetic head system is provided, which after the magnetographic Principle impulses according to the information to be stored on the magnetizable Layer of the sheet of film .zuzeichen or be allowed to remove from her again.

The invention is based on the object of the shortcomings of these known To fix arrangement and in particular the structure and handling significantly improve, so that a device suitable for the practice of storage technology is created.

This is achieved according to the invention in that in a magnetic film memory with magnetic heads embedded in a fixed flat plate, their active pole parts with the plate surface completely or almost complete, and one above this head support plate circumferential, on the surface facing the plate, a magnetizable layer supporting disc-shaped film, which is due to the between it and the plate surface The air flow that forms is stabilized and at a constant distance from the plate surface is held, the shaft carrying the magnetic foil disk through a central opening the head support plate passed through and the drive means of the shaft on the Magnetic film disc facing away from the head support plate is arranged.

This arrangement ensures that the drive of the magnetic film disk bearing shaft can be arranged particularly favorably and protected and the foil disk is easily accessible and easily exchangeable even if necessary. In particular the invention can be developed in such a way that the middle Opening of the head support plate, stub shaft passed through a support surface and Easily detachable fastening means for central fastening of the magnetic sheet disc having.

The drive means can consist of a motor, the fixed Part connected to the head support plate and its rotor shaft through the middle Opening of the head support plate is passed.

Another embodiment is that the camp of the shaft carrying the magnetic film disk are connected to the head carrier plate and on the shaft as drive means for the lateral supply of the drive force a drive pulley, preferably a belt pulley or cord pulley, is attached. the advantages achieved by the invention in the construction and in the handling of the magnetic film memory also give the possibility of building a larger memory, the two or has several circumferential foil disks.

A preferred embodiment of this type is that two with their active surfaces facing away from each other head support plates parallel and centrally to one another with a common drive means lying between them Shaft are structurally united and on each of the two through a central opening of the two head support plates passed through ends of the common shaft each have a magnetic sheet disc is attached (two-film memory).

To get from this version to a memory with a larger storage capacity to arrive, several of the aforementioned two-film memory can form a multiple memory be united. Here, too, it is useful to design the structure so that the individual two-film memory arranged interchangeably within the multiple memory are.

In order to also have the option of replacing it as required To create the individual film storage, the arrangement can be made so that in each two-film store the bearings of the two magnetic film disks bearing common shaft are connected to the two head support plates and between the two head support plates on the shaft one with a collective drive of the multiple storage detachable drive pulley, preferably a belt or cord pulley attached is.

Further features of the magnetic film memory according to the invention are to be found in the subclaims. Some of them are shown below with reference to the figures Embodiments of the magnetic film memory forming the subject of the invention described.

Fig. 1 shows a two-film memory in side view and top view with direct motor drive of the shaft carrying the disks, Figure 2 shows the structure of a Multiple storage from, for example, three two-film storage with cord or belt drive.

In Fig. 1, G designates a base plate on which two flat plates P 1 and P 2 are fastened with the aid of studs B1, B2 and B3. The spatial distribution of these fastening screws can be seen in the lower part of the figure in the top view, while in the upper part in the side view the screw B2 is shown offset for a better overview. As can be seen from this side view, the two plates P 1 and P 2 are held at a certain distance from one another and from the base plate G by means of sleeves H 1 and H2 inserted between them.

On the inside of the plate P 2 is with the help of suitable spacers, of which only the intermediate pieces Z 1 and Z 2 are shown in the side view, the support plate T of a motor M attached, for example in a known form can be designed as an external rotor motor.

Through central openings in the two plates P 1 and P2, of which only the upper opening 0 1 can be seen in section, the two stub shafts W 1 and W 2 of the motor shaft are passed so far that their flat end faces the outer surfaces of the plates P 1 and P 2 protrude only by a small amount, which is exaggerated in the drawing. On these flat boundary surfaces of the two stub shafts W 1 and W 2 , a foil disk F 1 or F 2 is releasably attached with the aid of a cord screw S 1 or S 2. These film disks are covered at least on the side facing the plates P 1 or P 2 with a magnetizable layer of a known type.

In each of the disks P 1 and P 2 there are multiple magnetic head systems K 1 or K 2 embedded in such a way that its working air gap with that facing the foils Finish the surface of the plate P 1 or P 2 flush. The embedding can be known in Way done by applying a hardening synthetic resin, and the flush finish the working air gap of the magnet systems can also be used in a manner known per se can be achieved in that the surface of the head support plate facing the film disk P 1 or P 2 ground after embedding the magnetic head systems and if necessary is lobed.

The plan view in the lower part of Fig. 1 leaves in a cutout of the foil disk F 1 the position of the multiple magnetic head system K 1 and the working air gaps recognize the individual heads contained in it. A multiple system is shown with twelve such individual heads, but both the number and the shape and the distance between the individual systems deviating from the drawing as required to be changed.

In order to accommodate a larger number of magnetic tracks, can in a different angular position, for example as indicated by the dashed rectangle K 1 'shown in the lower part of FIG. 1 is a further multiple magnetic head system be arranged, which is executed in the same way as the system K 1, but is arranged radially offset by a certain amount d. This measure would if total two offset systems K 1 and K l 'are provided, half the center-to-center distance of the single heads correspond.

A more detailed representation of the execution of the multiple magnetic head systems superfluous, since such systems are based on sound film technology and multi-track magnetic tape technology are known.

When the motor M is started, the two foil disks come F 1 and F 2 in rapid rotation. In doing so, they stretch as a result of the Rotation generated centrifugal force, and any distortions that might be present at rest or curves disappear. It also takes place through the friction of the air on the Foil surface entrains a certain layer of air in a tangential direction instead, but at the same time there is also air movement due to the centrifugal force caused in the radial direction outwards. In the space between the Finely machined surface of the fixed plate P 1 or P 2 and the magnetically active surface of the foil disk F facing the plate 1 or F 2, an air movement forms as a result of the aforementioned air entrainment, which has an in-out component, d. i.e., it will go through the middle opening of the plate P 1 or P 2 is constantly sucked in air and through the Rotation of the film F 1 or F 2 promoted to the outside.

This air flow, in conjunction with the tightening of the film caused by centrifugal force at a suitable speed, stabilizes the film disk F 1 or F 2 relative to the fixed plate P 1 or P 2 while maintaining an extremely small and very constant distance. This keeping the distance constant over almost the entire area covered by the film also occurs when the axis of the motor shaft is not exactly perpendicular to the surface of the head support plates P 1 and P 2 or these two plates are not attached exactly parallel to one another. The required, very small distance between the magnetizable layer of the film disk F 1 or F 2 and the facing surfaces of the magnetic head systems K 1 or K 2 is therefore stable and permanent in any case.

As the illustration in FIG. 1 shows, there is a great advantage the arrangement is that the two film disks F 1 and F 2 on the top or the underside of the two-film storage unit is easily accessible and with the help of the cord screws S 1 and S 2 are easily interchangeable. This is especially true when using the arrangement important as a program memory, because then it is easy to use foil disks with different programs can be kept in stock and exchanged as required. The required Centering is easy thanks to the precisely calibrated center hole in the foil discs to be observed while the desired distance of the magnetizable layer from the surface of the magnetic head systems in each case by the air flow mentioned adjusts by itself.

Fig.2 shows an embodiment for a larger memory, the here z. B. is composed of a total of three two-film stores. After this Any number of foils can of course be accommodated according to the same principle.

In the embodiment in FIG. 2, it is assumed that each two-film memory does not have its own drive motor, but has a cord or belt pulley R from a drive shaft, not shown, which is expediently common to several accumulators is powered off.

Otherwise, the structure of each of the three two-film stores essentially corresponds to the arrangement shown in FIG. 1, which has already been described in detail. The six head support plates are, with the interposition of suitable spacers H 1 and H2 with the aid of bolts B l, B2, etc., and nuts 171, M2, etc. mounted on a base plate G. The pairs of head support plates belonging to a two-film store can expediently be screwed together again at another point, so that after loosening the nuts M1, M2, etc. the individual two-film stores can be removed and inserted as a whole.

The top two-film memory is, as far as it is of the same type Parts are given the same reference numerals as the arrangement in FIG. As already mentioned, the difference is that it is driven by a cord or belt pulley R instead of its own motor M. Accordingly, the shaft on which the Cord or pulley R is attached, in the two associated head support plates P 1 and P 2 stored, as shown in section for the plate P 1. here the storage is indicated by a ball bearing L 1, but any one is just as well other suitable storage applicable. A corresponding warehouse L2 for the lower one Stub shaft W 2 is located in the lower plate P2, but is in the drawing not visible.

The magnetic head system K 2 in the head carrier plate P2 is opposite here the magnetic head system K 1 in the plate P 1 offset by 180 ° to the overall height to keep the two-film memory as small as possible. For the passage of air, As can be seen in the sectional view of the plate P 1, several passage openings D 1 provided because the central opening of the plate P 1 is covered by the bearing L 1 is.

The attachment of the two foil disks F 1 and F 2 on the flat The ends of the stub shafts W 1 and W 2 can also here again, as in FIG. 1 shown, take place by means of cord screws S 1 and S 2. The replacement of the Foil can be done by hand without special tools after the nuts M1, M2 etc., solved and the desired two-film memory was lifted off.

The accessibility of the individual two-film storage can still be essential be relieved, if in place of the common, by all the head support plates Passing screw bolts B 1, B 2 etc. Individual fastenings for each two-film storage unit be applied.

Claims (7)

PATENT CLAIMS: 1. Magnetic film storage device with magnetic heads embedded in a fixed, flat plate, the active pole parts of which are completely flush with the plate surface. or almost complete, and a disk-shaped film which runs over this head support plate and carries a magnetizable layer on the surface facing the plate, which is stabilized by the air flow that forms between it and the plate surface and is kept at a constant distance from the plate surface, characterized in that the shaft (W1, W2) carrying the magnetic film disk (F1, F2) is passed through a central opening in the head support plate (P1, P2) and the drive means (1T, R) of the shaft (bf'1, g-'2) are mounted on the Magnetic film disk (F1, F2) facing away from the head support plate (P1, P2) is arranged. 2, magnetic film storage device according to claim 1, characterized in that the stub shaft (W1, W2) guided through the central opening of the head support plate (P1, P2) has a support surface and easily detachable fastening means (S1, S2) for the central fastening of the magnetic film disk (F1, F2 ) having. 3. Magnetic film memory according to claim 1 or 2, characterized in that the drive means consists of a motor (M) whose fixed part (T) is connected to a head support plate (P1, P2) and whose rotor shaft (W1, W2) passes through the central opening the head support plate (P1, P2) is passed through. 4. Magnetic film storage device according to claim 1 or 2, characterized in that the bearings (L 1, L 2) of the shaft (LV1, W2) carrying the magnetic film disk (F 1, F 2) are connected to the head carrier plate (P1, P2) and on: a drive pulley, preferably a belt pulley or cord pulley (R), is attached to the shaft (W1, W2) as a drive means for the lateral supply of the drive force. 5. Magnetic film memory according to one .der claims 1 to 4, characterized in that two with their active surfaces facing away from each other @ head support plates (P1, P2) parallel and centered to each other with a drive means (M, R) lying between them of a common shaft (W1, W2) are structurally combined and on each of the two ends of the common shaft (W1, W2) passed through a central opening of the two head support plates (P1, P2) a magnetic film disk (F1, F2) is attached (two-film memory). 6. magnetic film memory according to claim 5, characterized characterized in that several two-film memories are combined to form a multiple memory are. 7. Magnetic film memory according to claim 6, characterized in that the individual two-film memory are arranged interchangeably within the multiple memory. B. Magnetic film memory according to claim 6 or 7, characterized in that in each two-film memory the bearings (L 1, L 2) of the common shaft (W1, W2) carrying the two magnetic film disks (F1, F2) with the two head carrier plates (P1, P2 ) and a drive pulley, preferably a belt pulley or cord pulley (R), that can be coupled to a collective drive of the multiple storage device is attached between the two head support plates (P1, P2) on the shaft.