DE1245422B - Data storage device - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

GlIc

German class: 21 al - 37/06

Number: 1245422

File number: N17847IX c / 21 al

Filing date: February 6, 1960

Opened on: July 27, 1967

The invention relates to a data storage device with a non-magnetic, with a having ferromagnetic coating with a preferred direction of magnetization provided carrier Storage body, the surface of which is groove-shaped, which determines the preferred direction of magnetization Has depressions.

Such a magnetic data storage device, generally referred to as a “twistor”, is known. It consists of a piece of non-magnetic electrically conductive wire as a common core as well a coaxial layer of a saturable ferromagnetic material deposited on the surface of the Core is extruded. The core is tensioned together with the ferromagnetic layer, at the same time twisted and held its ends in a fixed position during the operation of the device. This creates a spiral-shaped preferred magnetic direction. To be the device several coils of the same type wound at certain intervals so that they have a corresponding number delimit helical track sections of ferromagnetic material. Storing a Information is provided by applying a half-dial pulse to the conductive wire core and a half-dial pulse to the selected bobbin. The resulting vector sum of the two magnetic fields points in the same direction as that of the preferred magnetic direction of the coating.

In the earlier German patent 1161586 is a Twistor claimed, in which the carrier is "pre-rotated" during the manufacturing process and then returns to its original position, causing the magnetic layer to twist will. In the case of the so-called "wound transistor", the preferred magnetic direction is spiral-shaped Wrapping a carrier with a thin magnetic wire or tape is created.

In the case of this data storage device, the manufacturing process is relatively complex and special very difficult when using very thin wires and ribbons.

In addition to these "pre-twisted" twistors, devices are also known in which a magnetic Preferred direction is generated without the use of tensile or twisting forces.

Belgian patent 569 044 shows a data storage device in which magnetic preferred directions be generated by the fact that in the conductor made of magnetic material attaches helical depressions on its surface.

Data storage device

Applicant:

The National Cash Register Company,

Dayton, Ohio (V. St. A.)

Representative:

Dr. A. Stappert, lawyer,

Düsseldorf, Feldstr. 80

Claimed priority:

V. St v. America 6 February 1959 (791695)

In the above-mentioned data storage devices, the solid wire used there creates relatively

^a ° large eddy currents, which have an unfavorable effect on the reversal of magnetization and thus on the operating speed as well as on the size of the output signal.

The object of the invention is to produce an improved data storage arrangement which has the aforementioned Does not have any disadvantages.

This is achieved according to the invention in that the groove-shaped depressions on the surface of the storage body are arranged parallel to one another, closely adjacent to one another and that the surface shape of the storage body through corresponding groove-shaped depressions in the surface of the carrier, on the surface of which the thin ferromagnetic coating adapts exactly, is conditional.

The invention is described below with reference to the drawings showing preferred exemplary embodiments explained. In these show the

F i g. 1 to 8 oscillograms of magnetic hysteresis loops the ferromagnetic devices constructed according to the present invention,

F i g. 9 and 10 are examples of cutaway magnetic data storage devices according to the invention;
Figure 11 is a section of the magnetic data storage device of Figure 10 taken along line 11-11.

In a preferred method of making magnetic data storage devices of the present invention Invention, the ferromagnetic coating is electroplated onto the carrier, which consists of any electrically conductive material, such as a copper, silver, aluminum, brass,

709 618/398

3 4

Bronze alloy etc. or any of the magnetic properties which can be produced according to the present invention with a detailed description of the known electrically conductive elements. The external shape of the surface type of the magnetic storage medium produced in the present invention is not decisive, so that it is started cherelemente, it should be determined that this is a tube, a ring, a plate, a 5 designation "longitudinal" hysteresis loop for rod or a band can act. This carrier has the ß-i / characteristic of the shown ferromagnetic !! A very thin electrically conductive film of the element can also be used, which is passed through, which is sent through an insulating material, such as when an alternating current is passed through a winding placed around the element, for example glass, plastic, ceramic material, so that that is deprived. In the illustrated embodiment, the standing magnetic field of H Oersted in one play (FIGS. 9 and 10), however, the carrier has the axial direction with respect to the element runs in the form of a hollow wire 20 made of phosphor bronze, and which is induced in a similar winding which has an outer diameter of about 0.4 mm EMF the magnitude of the change in that flux and an inner diameter of about 0.2 mm component that has with respect to the ElefHeTfl. 15 runs in the axial direction; the integral of this

As in Fig. 9, the hollow wire 20 is shown to - EMF is proportional to the flux density B. Let the outwardly with a number of V-shaped and uniformly pressure "transverse" hysteresis loops run more spirally than the BH characteristic of the ferromagnetic groove 21 Mistake. The grooves 21 can be on Mentes, for the alternating, commonly known method, such as a current generated magnetic field from H Oersted, etching, engraving or the like, flowing on a winding running around its the hollow wire 20 by means of one of the numerous circumferentials. be formed. The element also extends in an axial direction in terms of dimensions and the cross-section of the grooves 21, and in the case of the hollow wire this is critical to a certain extent. EMF induced in the carrier 20 was a result of the, however, already magnetic data storage device change in that flux component that was successfully built in genes in which the grooves ran a depth with respect to the applied field. (D) between 2 to 25 μ, a width (W) of 25 μ in FIG. 4 shows the transverse hysteresis loop or less, a distance (S) of about 2 to a ferromagnetic element at which 400 μ and an inclination (Φ) of about 45 °. before electroplating in the carrier in a spiral shape. The distance between the grooves is as small as 30 in order to keep these right-hand grooves as possible. The theoretical minimum of the det were, and that in a bath, the 5 g ferric groove spacing (S) would be the width of a single chloride, 20 g nickel chloride, Ig sodium molybdate, 10 g crystals of ammonium citrate and 50 g ammonium chloride per magnetic material . Liters of water has been galvanized. F i g. 5

After the grooves 21 have been formed on the hollow 35, the transversal hysteresis loop shows the ferrodraht20 the latter receives in a galvanizing magnetic pre-bath galvanized in the same bath a ferromagnetic coating. The coating direction, but none before electroplating should have a thickness on the order of about grooves according to the present invention in the 2 μ have so that current losses occurring in it carriers were attached. F i g. 6 finally shows be kept as low as possible and the 40 the transverse hysteresis loop of the for F i g. 5 are nevertheless dense enough to be used as a storage element ferromagnetic element, the jeeine to ensure sufficient reading voltage. but, like the "Twistor" mentioned at the beginning, after

The coating 22 is formed over the entire circumference of the electroplating of a mechanical torsion hollow wire 20 which has been subjected to pre-stressing to the contours, conforming to its surface. Such a coating clearly shows that by attaching the device, it not only has an essentially right-hand groove in the carrier before electroplating in the angular hysteresis loop, but also a ferromagnetic "light" direction of magnetization in the manner just described Essential element arises, which runs essentially the same borrowed in the same direction as the grooves has magnetic properties as the older 21. The reference number 23 denotes a protective cover 50 »Twistors«, which, however, neither before nor during the train is made of copper or a similar non-magnetic electroplating or its use of a tortoiseshell material which must then be subjected to over-biasing. Without train 22 is formed. the grooves or without a torsional prestress,

It is assumed that such a "slight" magnetization 55 not running in a certain direction, ie a twist, is remotely a rectangular hysteresis loop, not only the direct result of a mechanical and is therefore suitable for use as a magnetic reshaping of the coating is unsuitable, formed by the storage device in the carrier table, but also that the In F i g. 7 shows the transverse hysteresis loop of ferromagnetic grape-shaped formations of a device which in the aforementioned bath, during electroplating, tend to "grow" in the same direction, however, from which the sodium molybdate is omitted, as that which was electroplated next to it, and in the one in front of the adjacent grooves in the carrier. Regardless of electroplating in the carrier in a spiral shape around the appearance to which this is attributable, right-hand grooves of this type are formed, such devices have excellent machinability. F i g. 8 shows the transversal hysteresis-magnetic properties and are excellently suited for this purpose as storage elements in modern electronic devices, in which the grooves, however, installed in countercomputers and data processing devices, run in the set direction, i.e. left-hand in counter-pointer. It follows that by erae,

"Change" of the groove course a corresponding change or reversal of the hysteresis loop of the Device is achieved.

F i g. 1 shows the longitudinal hysteresis loop of the device, the hysteresis loop of which in FIG. 7th is shown. F i g. 2 shows the longitudinal hysteresis loop of an electroplated in the first-mentioned bath ferromagnetic device without grooves. F i g. 3 finally shows the longitudinal hysteresis loop a ferro- ίο magnetic device galvanized in the first bath, but in which before the Electroplating a number of longitudinal grooves 21 which, as shown in FIG. 10 shown to be parallel to the Axis of the hollow wire 20 extend, were formed.

A number of conclusions can be drawn from the foregoing. Most of all it shows that it is by making grooves in the carrier before electroplating is possible, a ferromagnetic Coating does not only give magnetic hysteresis properties, as indicated by a rectangular hysteresis loop are expressed, but also the magnetic properties of ferromagnetic To improve coatings that previously had an approximately rectangular hysteresis loop. Want the change in the longitudinal flow component with respect to the element is used, so it is appropriate that the grooves, as shown in Fig. 10, in the longitudinal direction and not, as in Fig. 9 illustrates, run in a spiral. One wants to change the in terms of the item use transverse flow component, it is zv / angular that the grooves, as in FIG. 9 shown spiral and not, as shown in FIG. 10, run in the longitudinal direction.

Those skilled in the art will recognize from studying the present invention that the inventive magnetic data storage devices in any form, such as plates, rods, tubes or rings, can be manufactured and built in a simple and economical manner. she have significantly better magnetic ones compared to previous data storage devices and other properties and are ideally suited for installation in modern data processing systems. If you use an electrically conductive, deposited on a dielectric core such as glass, ceramic material, plastic Film, then, when formed, has a number of longitudinal grooves on the surface of the flat described core before or after deposition of the silver film on this the ferromagnetic Coating, which is then electroplated onto the silver film, has significantly improved properties compared to the aforementioned arrangement.

Claims (5)

Patent claims: 1. Data storage device with a non-magnetic, with a ferromagnetic Storage body having a coating with a carrier having a preferred direction of magnetization, whose surface is groove-shaped, the preferred direction of magnetization determining depressions having, characterized in that the groove-shaped depressions on the surface of the storage body are arranged parallel to one another, closely adjacent to one another and that the surface shape of the storage body by corresponding groove-shaped depressions in the surface of the carrier, on the surface of which the thin ferromagnetic coating is located fits exactly, is conditional. 2. Apparatus according to claim 1, characterized in that the coating is on the carrier is electroplated. 3. Apparatus according to claim 1 or 2, characterized in that the carrier is cylindrical and the grooves formed in its surface take the form of a multi-start thread to have. 4. Apparatus according to claim 1 or 2, characterized in that the carrier is cylindrical and the grooves formed in its surface extend parallel to the cylinder axis. 5. Device according to one of the preceding claims, characterized in that the The carrier is a hollow cylinder through which at least one electrical conductor is passed. Considered publications:
Belgian patents nos. 569 044, 573 063. 1 sheet of drawings 709 618/398 7.67 © Bundesdruckerei Berlin