DE1191860B - Magnetic core memory - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

Number:
File number:
Registration date:
Display day:

H 03 k

German KL: 21 al - S7 / 60

A38841IXc / 21al
November 20, 1961
April 29, 1965

The invention relates to a magnetic core memory with perforated cores that are attached to a support body are held non-slip by means of recesses and are inductively coupled to them by the one Winding is performed.

It is known to insert perforated cores into slots of a support body, which are located in a side surface of the Support body located, in such a way that they are arranged in rows and columns and their holes so in So that the winding is to be threaded straight through the holes. First of all, the Perforated cores poured onto the side surface of the support body provided with the slits, and then the Support body shaken so that the perforated cores in the order mentioned in the slots provided slide.

Then a film provided with adhesive is placed on it, which is as large as the area of the support body, which picks up the kernels. The parts of the perforated cores protruding from the slots remain adhere to the foil, and by lifting the foil it is possible to remove the cores from their Pull out slots in the desired arrangement; then the perforated cores are threaded through. Finally, the adhesive is dissolved by means of a solvent, and the hole cores are with their windings lifted from the foil and stretched on a frame.

During the threading process, the wire must pass through an alignment of at least partially exposed perforated cores which is difficult and the cores can therefore be easily damaged.

The object of the invention is to fix perforated cores on a support body in a simple manner and the To simplify threading of the perforated cores so that the perforated cores are less easily damaged can.

To solve this problem, a magnetic core memory of the type mentioned at the beginning is characterized in that that the support body extends in opposing surfaces in these surfaces first recesses that a plurality of transverse to the recesses extending second Recesses in these opposite surfaces of the support body is provided that the perforated cores are inserted into the first recesses so that their holes are in alignment with the second recesses lie, and that they by means of a helically placed around the support body winding on the support body are held.

To produce a magnetic core memory according to the invention, the perforated cores can initially be on Magnetic core memory

Applicant:

Ampex Corporation, Redwood City, Calif.

(V. St. A.)

Representative:

Dipl.-Ing. F. Weickmann,

Dr.-Ing. A. Weickmann, Dipl.-Ing. H. Weickmann and Dipl.-Phys. Dr. K. Fincke, patent attorneys,

Munich 27, Möhlstr. 22nd

Named as inventor:

Martin Luther Hoover, Inglewood, Calif.

(V. St. A.)

Claimed priority:
V. St. v. America November 23, 1960
(71 247)

a wire to be threaded and, while the wire is placed helically around the support body, in the manner mentioned in the recesses of the support body be plugged. There is no shaking into the holes, it also contains the needle guide through a whole flight of cores, the perforated cores can therefore not be damaged as easily as with the production of the well-known magnetic core memory.

The perforated cores are also practically located in the magnetic core memory itself when the invention is used not free and therefore cannot be damaged, in contrast to the well-known magnetic core memory, where they are threaded onto a grid formed by the winding and are exposed on all sides within the grid.

The invention is particularly suitable for magnetic core memories that are to be constructed from perforated cores, whose dimensions are very small, whose outer diameter is, for example, about 0.8 mm and whose Inside diameter is about 0.5 mm.

Further details of the invention emerge from the following description with reference to the figures.

1A shows a top view of a frame or carriers according to the invention;

Fig. 1B shows an elevation view of the same;

Fig. IC shows a side view of the same;

509 567/116

F i g. Fig. 2 shows a diagram explaining a type of wiring that can be used according to the invention at Use of the frame shown in Fig. 1A is used is;

Fig. 3 shows the appearance of the embodiment of the object according to the invention in the assembled, wired state;

F i g. 4 shows the appearance of a complete accumulator assembled according to the invention; and

Fig. 5 shows part of a frame according to the invention and the wiring for multi-hole cores can be used.

In Figs. 1A, IB and 1C are three views of a portion of a beam or frame according to the invention. This includes one rectangular strip of material 10 made of any suitable plastic material can. The frame has a top and bottom surface 12, 14 and two opposing surfaces 16, 18. An elongated groove 16 Λ, 18 Λ is in each of the opposite ones Areas provided parallel to the edges of the areas therein. These grooves can be made deep enough to completely submerge a magnetic core. the When inserted into the frame, cores are in an upright position. If desired, can a cavity or a similar depression is formed in said surfaces for each individual core however, a groove is easier to manufacture and is therefore preferred. The word "groove" as it is here is used but is to be understood to include depressions after all of this only short grooves are.

A plurality of formed in the frame, transverse to the grooves recesses 16 B, 18 B, which have the form of notches along each of the surfaces 16, 18, and extending between the upper and lower surfaces 12, 14. The opening such a "notch" should be large enough so that when a core with wiring is inserted into the groove, the wiring can be brought through the notch opening. The slots should be made so that a core can be easily inserted therein and, similarly, the notch width should be such that wiring can be easily passed through the core.

The opposed recesses 16B , ISB are shown offset from one another, although this is not necessarily required. This can be seen particularly clearly in FIG. 5 (notches 112, 114). The frame 10 is shown in such a way that it has an opening 20. This can be provided so that, if desired, a stack of these frames can be produced by means of suitable bolts and suitable nuts, in which all frames are parallel to one another. The frame is also shown having a tab 22 at one end which can also be provided at both ends if desired so that the frame and its cores and wiring along with other frames into a slot in a retainer ( 90 in Fig. 4) can be used to form a complete memory.

F i g. Figure 2 shows a wiring diagram used in an embodiment of this invention that was built and has been operated. This wiring scheme is not intended to be a limitation on the invention but is just one example of what can be accomplished using the invention can. The store that was built was a "word-wehk store". This means that at of information inserted into memory one word at a time or one word at a time is read from the memory. It was a 72-bit or binary digit word memory.

ίο Any frame that held the type shown in Fig. IA 144 cores. There were 36 frames. In the design there were a number of propulsion systems of the cores through the main or central openings of a group of 72 cores inserted through. Wires were also threaded through a second set of 72 other cores. Two groups of cores were mounted on each frame.

Since there is no spacing requirement between the cores threaded onto the wires in this connection of the Assembly, threading the wires through the cores is very easy to do. For example, a hollow needle is dipped into a box containing the cores, then inclined parallel to the bottom of the box and then pulled out. It usually follows that several cores are added to the needles. This process is repeated until the desired one Number of cores has been attached to the needle. After that, the wires for the winding can be used inserted into the hollow needle. Eventually, the cores from the needle get down onto the wire drawn. Optionally, a vibration device is known that the cores in a single Row and then transfer them to a needle.

The wire on which the first group of 72 cores is strung is then wrapped around the frame in such a way that one core is located in each recess (notch) of the frame. Figure 2 shows the general setup of the cores and wires, with the frame omitted for clarity. The kernels for a word are designated with 30, 31, 32, 30 + (NI), 30 + N in this regard. The kernels for the other words are denoted by 40, 41, 42, 40 + (N- 1) and 40 + N. It should be noted that the cores for a word are alternately arranged as the winding proceeds helically along the frame.

For example, in the embodiment of the invention described herein, two turns of the read drive winding were coupled to each core and a single turn of the winding was used for the write winding. A wire was used for the test and inhibit functions. Thus, in Fig. 2, the read drive winding 50, used for the cores in one word, can be passed from the far left of the drawing through core 30, then core 31, then core 32, and so on, eventually passing through cores 30+ (N. - 1), winds 30 + N. Using the reference number 50A , the winding is then passed through all of the cores of the word in the same way as the reading drive winding 50 and finally terminates at terminal 52. The second turn of the winding 50 has the reference number 50.4 to identify it to facilitate.

In the same way as windings 50 and 5 (M, the second read drive winding, which consists of a first turn 54 and a second turn 54 A , goes through the second group of 72 cores 40 to 40 + JV, and finally ends at the Terminal 52. It should be noted that the cores of the two groups 30, 40 are attached adjacent to one another, but the adjacent cores are assigned to two words which are stored.

The third winding coupled in the cores comprises the write windings 56 and 58, respectively. The write winding 56 for the first group of cores runs from the right side of the drawing from successively from the last core 30 + JV of the word to the first core 30 of the word and then back to a connection with the reading winding at terminal 52. Runs in a similar manner the write winding 58 sequentially through the last from the right side of the drawing Core 40 + JV of the word to core 40 and then to core 41 and then back to terminal 52. The Arrows on the reading and writing wires indicate the direction of current flow that is being used.

A separate winding 60 to 60 + JV, and 70 to 70 + JV is provided for each core. These windings serve as digit level windings to enable the drive exerted on cores, when the write winding is energized, so that intelligible information storage takes place can. The digit level windings just mentioned also serve as the reading winding in the Reading operation. Here the arrows again show the current flow which occurs during this read operation.

An arrangement for selecting and applying a drive current to the memory is not shown, there this is well known in the art.

F i g. 3 shows the appearance of a core frame 10 with cores 30 to 30 + JV and 40 to 40 + JV, which are attached in it. It can be seen that a core at each recess transversely to the groove in the Frame 10 lies. The cores are protected by the frame, and the opening of the recess is sufficient to allow the wires to pass through the cores to get through the frame and being wrapped around him. The assembly of the cores on the frame is extremely simple and extremely quick. The frame is held in a device that can be operated to rotate the frame continuously. After this a core is pushed into a groove in a recess, the frame is rotated, whereby the winding around the frame is created. The frame serves the function of the correct distance of the kernels, protects them and holds them, so that the reading windings through a simple threading operation can be inserted.

F i g. 4 shows a plurality of these frames 80, 82, 84, 86, 88. These are parallel to one another Insertion held in slots which are provided in two holding brackets 90, 92. To this Way can the combined digit level windings or reading windings very easily through the Cores on each of the frames are threaded through which the corresponding bits of a separate Form word. Holding the frames by parallel brackets 90,92 is just one example like this can be executed. Many other aids are known that can be used for this purpose. For example, a bolt can pass through holes in the frame, one of which is hole 20 in FIG. 1 shown is to be passed through. The stud becomes a spacer have and will be used in such a way that a nut closes the gaps on the Frame can decrease. The arrangement shown in FIG. 4 facilitates storage very many words.

ίο The invention has been shown so far as it is used with annular cores having a single opening. The usefulness of the invention is not limited thereto, however, since, as shown in FIG. 5, multi-hole cores according to the invention can be wound onto a frame. In Fig. 5, a partial section of a frame 100 for holding multi-hole cores 102, 104, 106, 108 is shown. Grooves are cut in the opposite surfaces of the frame, as described for the previous embodiments of the invention. In addition to the recesses 110, 112, 114, 116, which are provided to handle the wiring for the main openings of the cores, recesses 110 ^ 4, 112 A, 114 A, 116 A are provided for the wires passing through the small Go through the openings of the cores. Only a recess for a small opening is shown. Another recess can be used for another small opening located on the side of a recess for a main opening that does not already have a recess.

A single wire 118, 120, 122, 124 is shown passing through the corresponding large and small openings through it. These individual wires represent one or more wires, which, as FIG. 2 shows, can be used as a winding. Other windings (not shown) can be passed through the cores perpendicular to the plane of the core frame. The procedure of Mounting the cores on a frame can be the same as previously described. The number of cores to be attached to a frame is picked up on a hollow needle. Another The needle can be passed through the small openings. Wires are threaded through the hollow needles. The needles are then removed, leaving the cores strung on the wires, which go through the large and small openings. The cores then become sequential inserted into the recesses, with the wires serving to keep the cores properly in each recess align, and the wires are also wrapped around the frame in the manner shown.

It is accordingly a novel and useful arrangement for assembling cores and wire has been shown and described on a frame to provide magnetic core memory. By the arrangement described here is not required for the production of a magnetic memory with small cores much greater difficulty than that with larger cores. The kernels are in that Frame protected, held correctly in it and yet not so constricted that magnetostrictive Effects would be produced. The large diameter hole in the core is available for wiring made. The »word-wahk winding arrangement described and shown here is intended only as an

game and not serve as a limitation of the invention. Experts are able to determine the winding arrangements to change within the scope of the invention.

Claims (6)

Patent claims: 1. Magnetic core memory with perforated cores, which are held non-slip on a support body by means of recesses and through which a winding inductively coupled to them is guided, characterized in that the support body (10, 100) in opposing surfaces in these extending first recesses (16 A, 18Λ) has that a plurality of second recesses (16 B, 18 B, 110 to 116, 110 Λ to 116A) running transversely to the recesses are provided in these opposite surfaces of the support bodies, so that the perforated cores (30, 40, 102, 104, 106, 108) are inserted into the first recesses in such a way that their holes are in alignment with the second recesses and that they are connected by means of a winding (50, SOA, 56, 54, 54 Λ, 58 , 118, 120, 124, 128) are held on the support body. 2. magnetic core memory according to claim 1, characterized in that two groups of Perforated cores (30, 40) are held on the support body (10) by means of windings assigned to them. 3. Magnetic core memory according to claim 2, characterized in that perforated cores of the one Group (30) and perforated cores of the other group (40) lie alternately in a row. 4. Magnetic core memory according to claim 1, characterized in that the recesses (16 A, 18A) have the shape of a continuous groove for receiving a plurality of perforated cores. 5. Magnetic core memory according to claim 1, characterized in that the notches (110, 112, 114, 116) are offset from one another in the opposing surfaces of the support body. 6. Magnetic core memory according to claim 1, characterized by additional recesses (110 A, 112 A, IUA, 116A) for receiving windings (120, 124) guided through eccentric holes in the perforated cores. Considered publications:
German Auslegeschrift No. 1 024 270,
029 875, 1063 205, 1070 411, 1076 972;
German utility model No. 1832228;
U.S. Patent No. 2,985,948;
French patent specification No. 1 250 472. 1 sheet of drawings 509 567/116 4.65 © Bundesdruckerei Berlin