DE2143327A1 - MULTIPLE IMPULSE GENERATOR - Google Patents

Description

Multiple Pulse Generator The invention relates to a multiple pulse generator and a method of generating multiple pulses.

The present invention relates to improvements over those which are described in the American patent specification 3,223,987. Typical magnetic memory cores, such as those used in computers are circular and up a path along the perimeter of the core either clockwise or counterclockwise magnetized, when a reading signal is acted on, a logic one becomes one Pulse generated when the magnetomotive force generated by the reading current counteracts the earlier magnetic path. If the generated by the reading current magnetomotive force does not counteract the earlier magnetic path no reading pulse output, which is to be regarded as a logical zero. The known Memory cores can therefore only be used to display two logical states will.

The invention relates to a memory device having a contains magnetic core and by means of which a large number of pulses from the Core can be read, increasing the usefulness and versatility of the device is increased.

The core consists of a cylindrical bundle of specially treated Wires. An applied magnetic field is used to read the signal. One converter winding adjacent to the core absorbs an electromotive force, generated by sudden changes in the intensity of the flow in the core.

When the magnetic field is intensified, a point is reached at which one of the wires aligns its magnetic area with the acting field. This process is regenerative within the individual wire, so that the change the flux intensity (B) in the winding is sudden and relatively large. This The output pulse is then independent of the extent or passage of the magnetic field intensity. The gradual function increase of the magnetic field intensity is of a corresponding one Accompanied decrease in magnetomotive force (H) across the core. The run must then continue to the same extent, until the same again the magnetomotive Force happened which caused the first wire to reach its magnetic range aligned with the acting field. Shortly after this point there will be another of the wires align their magnetic area with the acting field. This Operation continues until all of the wires in the core align with their magnetic areas and therefore all output pulses have been registered by the Umformderwickel are.

An important advantage of the invention is that a large predetermined number of output pulses can be derived from the core, the is determined by the number of wires in the core. The disturbance / benefit ratio of the Output pulse is quite high, so the output pulse has no ambiguity be included. Either positive or negative impulses can come from the core can be obtained depending on the direction (polarity) of the applied magnetic field The device has a relatively simple construction and uses Components of high reliability -> * The generation of the reading pulses can caused electronically or electromechanically by a push button-like construction will. The formation of the core is such that the number, shape, amplitude and Separation of the reading pulses can be effectively predetermined.

The invention therefore relates to a multiple pulse generator from consists of a large number of straight, pre-stretched wire segments in the axial direction, which helically evenly twist and in a dielectric Bodies are included to form a cylindrical core. All around the core a wire winding is arranged. When a magnetic field of variable intensity acts on the wires, a series of pulses is generated in the winding. That Magnetic field can be created by applying an electric current of variable Starch passing through another winding wound around the core or by a permanent magnet located adjacent to the core in a lateral direction is moved.

The invention is described below with reference to the drawing described in more detail, in which shows: Fig. 1 partly schematically and partly obliquely Side view of an embodiment of a pulse generating device according to the invention, 2 schematically in vertical longitudinal section another embodiment of the pulse generating device, FIG. 3 shows a cross section along the line 3 - 3 in FIG. 2.

Figures 4 and 5 are graphic diagrams for explaining the theory the operation of the device according to the invention.

Referring to Fig. 1, there is a pulse generating device intended for a magnetic memory 10 which includes a cylindrical core 12. The core consists of one A plurality of parallel wires 14, which are relatively short and preferably are straight in the axial direction. The wires are kept together in a bundle by embedding them in a solid dielectric body 16 made of Epoxy resin or another plastic or an appropriate cement can.

Two conductive wire windings 18, 20 are arranged adjacent to the core, both wound in the same direction.

The same extend over the entire length of the core and are isolated from each other. The windings have input terminals 22 and output terminals 24 on. The winding 18 is used to bring about a magnetic field to act, what the memory signal gives. The winding 20 senses the reactions of the wires of the core and generates output current pulses.

The magnetic wires 14 of the core consist of a corresponding one ferromagnetic material and can be made from a commercially available nickel alloy are made, which preferably consists of nickel and iron, with a higher percentage of nickel than iron. The wire generally has a circular cross-section and a diameter of approximately 0.3 mm. Preferably the cross-section should approximate the round shape as practically achievable is. The wire should also have a grain size of not less than 6,000 grains each Square millimeters and preferably a grain size of at least 8,000 grains per Have square millimeters. If for a given diameter of the wire the As grain size decreases, so does the slope of the portion of the B-H curve which is the orientation of the magnetic area of the wire with the acting field, to (see Fig. 4) and the impulse increases. The resulting induced pulse duration however, it is reduced in the converter winding. The optimal grain size is as a result a function of the application for which the wire is intended.

For the present application, the preferred grain size is 10,000 Grains per square millimeter if an alloy with 48, isen and 52 tX nickel is used and the diameter of the wire is approximately 0.3 mm.

The wire is treated to be a relatively soft magnetic middle part and a relatively hard magnetic outer part (jacket) to form, which have different magnetic properties. The middle one Part is magnetic anisotropic with one parallel to the wire axis Axis of magnetization and has a relatively low magnetic remanence and coercive force. The coat has a relatively high remanence and Coercive force and is magnetically anisotropic with one parallel to the wire axis Magnetization axis. The sheath is magnetized to work on its opposite Ends to form north and south poles. The sheath magnetizes the middle part in a direction opposite to the jacket, so that the central part is a magnetic Forms return path or shunt for the coat.

The core 12 can be made by the wire 14 substantially to the desired size-is drawn, while the same on a correspondingly increased Temperature is maintained to form a wire having a desired fine grain. A wire made of an alloy of 48% iron and 52% nickel and with a diameter for example, from about 25 to 37.5 mm is drawn by the wire with a Speed of about 22.5 m per minute through successive pulling stations is passed through, which individually result in a twenty percent reduction in cross-sectional area cause. The wire is hardened at room temperature to harden the wire jacket, while the middle part is left relatively soft. Then the coat magnetized in the desired direction. The wire can be hardened by the same is stretched a little (for example by 2.5). Then the wire is twisted while it is under tension so that the wire has a helical shape with equally spaced turns.

Then the wire is cut into segments of equal length, each of which is equal to the length of the core to be made. A number of cut ones Wire segments 14 are then gathered together to form a cylindrical bundle. The number of wires 14 is determined by the maximum number of output pulses, that are desired during each reading cycle. the Wires will be then permanently connected in parallel to one another by inserting them into a corresponding dielectric KunststofSkörper 15 or another potting compound are embedded. The opposite ends 17 of the core can be ground to smooth To obtain end faces. Then the windings 18 and 20 are made of copper wire wrapped around the core in the same direction and cemented in place.

Fig. 1 illustrates a storage device that electronically can be operated. If output pulses are desired, the reading signal stream IR are continuously strengthened. This creates a variable magnetomotive force in the core 12 Force induced, which causes in the winding 20 output current pulses IS be generated. Since the absolute inert of the reading signal current IR is just above the Is increased beyond the point at which the first pulse is due to the magnetic response one of the wires 14 is generated on a signal, the current IR can be reversed, so that no further pulses in the series are read. The current I can be continuous are amplified until all output pulses that are generated by the device in a Row can be generated, have been generated. For proper operation must the core 12 will initially be affected by a stronger current than normal positive and negative currents in the reading winding 18.

Later, normal flow currents can then be used in the reading winding 18 can be used to generate output pulses in the winding 20.

Figures 2 and 3 show another embodiment of the device according to the invention, which can be operated electromechanically. The storage device 25 contains a cylindrical core 12a, which is similar to the core 12 of Fig.

1 is designed and arranged and of a multitude of twisted contains parallel wires 14 which are gathered together to form a cylindrical bundle and which are permanently held together in a dielectric body 16a will. Of the The core is enclosed by a single converter winding 20.

The winding is connected to output terminals 24. The whole unit The core and winding are then embedded in a flexible dielectric block 30. A permanent bar magnet 32 is also embedded in the block, which leads to the core 12a is parallel and spaced by a flexible portion 34 of the block will. A rigid push button plate 36 is * in a cavity 38 on the top of the block is inserted and touches the magnet 32.

When the button 36 is depressed, the distance changes of magnet 32 from core 12a because portion 34 of the block flexes. A magnetic field then acts on the core to create a magnetomotive force, which activates the wires 14. When the magnetic field of the magnetic Aligning wires one after the other with the acting magnetic field becomes electromagnetic a series of output pulses is generated in the converter winding 20. When the button 36 is released, the pulse series is generated again.

The theory of operation is explained below with reference to FIG FIGS. 4 and 5 are described. If a wire in a similar mush as each of the Wires 14 helically twisted becomes an easy path for magnetization generated. when this wire is initially magnetized or pretensioned all magnetic areas aligned in a linear direction. but they do magnetomotive force H in a special place, they all snap Areas regenerative or like a chain reaction within the wire in the helical line pattern a. This then gives a remanent magnetism BR in a helical shape (see Fig. 4). In Fig. 4 a b-1i curve for a linear wire 14 is shown, where 2 is the flux intensity and H is the magnetomotive force. A j% steresis effect is shown in quadrant I. However, the same limitation can be applied in the quadrant III can be achieved when B and H are reversed after preloading with a Force -H.

In the core 12 or 12a, two wires 14 do not switch at the same time.

When a wire switches, it tries to insert the other wires Short-circuit core. This step effect is through the step curve M of a whole Kerns shown in Fig. 5. The arrangement of the group of impulses relative to the acting Field H, which is generated by the flow-through current IR or by depressing the button 36 is caused primarily by the type of wires used in the wires 14 Materials determined. The separation of the impulses within each group is primary a function of both the material of the wires and the extent of the wire given twist. The greater the twist per unit length of the wire, the closer the impulses are to one another. The size of the indicated in FIG Change in the flow intensity BR, which is caused by the alignment of the magnetic Area with the acting field is mainly influenced by the amount of initial stretching of the wires before twisting and through the Grain size of the wire.

In summary, the device according to the invention has in general the following properties: 1. The magnetic flux flow switches between two different magnetic paths, creating an electromotive in the converter winding Impulse is generated.

2. This circuit is caused by a * occurring magnetomotive Force field with directional effect, which is different from the light static field.

3. The magnetomotive force field can be generated electronically, by passing a reading current signal through the magnetic core, or the magnetomotive Force field can be created by changing the distance between the nucleus and a permanent magnet.

4. The switching of the magnetic flux flow takes place in one way suddenly and fast and is independent of the speed at which the reading signal passes or the rate of change in the distance between the core and the Magnets.

5. As a result of the rapid activation, the disturbance / user relationship is in the converter winding is quite high.

6. From a core consisting of several wires becomes a number generated by output pulses due to a multitude of magnetic switching operations he follows.

7. The amplitude, separation, arrangement and number of pulses in a row are all changeable and by the material of the wire, the wire diameter, the amount of twist, the amount of stretching, the grain size, etc. determinable.

8. The reading signal can run through at such a point reversed so that fewer than a whole series of pulses are generated.

3. The magnetic circuit phenomenon draws a hysteresis path in one of two quadrants of a B-H magnetization curve.

10. Either positive or negative output pulses can be obtained from a core and none of two output pulses occur at the same time.

The described storage devices form information storage and reading units of high reliability. Every catch of a system can have an identical circuit and / or ideal Linbauvorrichtungen, and physically equivalent cores, regardless of number or properties the output multi-channel system, in which all push-button units a feed common Dr & jit and still each unit different signals transmits. The units can be in any magnetic core storage system or computer can be used in which it is desired for a storage unit more than read a logical zero and a logical one. If desired, the the storage cores containing holding devices are attached so that in the same arranged individual magnetic cores can be easily removed and replaced by others can, so that from each holding device a different number of pulses can be obtained. When making the core it is possible to use the wire segments to stretch and twist individually before they form a cylindrical core be shaped.

P a t e n t a n s p r ü c h e

Claims (13)

PATENT CLAIMS ffl. ' Multiple pulse generator, consisting of a Variety of magnetic wires, each of which has a central part of wire relatively low magnetic remanence and coercive force as well as an external one Has jacket with relatively high magnetic remanence and coercive force, characterized in that the jacket has a magnetic field which the central Can magnetize part in a first generally axial direction, namely such that the magnetization of the central part by the action of a second Magnetic field is reversible with at least a predetermined strength and that the magnetic field of the jacket when the second magnetic field is reduced below the predetermined one Strength that can magnetize the middle part again in the first direction a dielectric device the wires in stationary, laterally adjacent positions attached in a bundle to form a cylindrical core, and that one to the core adjacent first device samples flux changes, so that in the first Establishing a series of electrical impulses is generated when the wires run one exposed to a second magnetic field with at least a predetermined strength, where the manual number of pulses in the series is the number of wires in the core is equal to. 2. Multiple pulse generator according to claim 1, characterized in that that the wires have a uniform helical connection and are of the same length. 3. Multiple pulse generator according to claim 1 or 2, characterized in that that the first device consists of a conductive wire winding adjacent to the core consists. 4. Multiple pulse generator according to one of claims 1 to 3, characterized by a second device adjoining the core for generating the magnetic field. 5. Multiple pulse generator according to claim 4, characterized in that that the second device consists of a field-generating conductive wire winding, which is wrapped around the core to create the magnetic field when electric Current passes through the field-generating winding. 6. Multiple pulse generator according to claim 4, characterized in that that the second device consists of a permanent magnet in the side Distance from the core is arranged, -and that a device for changing the distance between the magnet and the core is provided to the core the magnetic field of the exposed to permanent magnets. 7. Multiple pulse generator according to one of claims 1 to 3, characterized by a support for the core, by a permanent magnet, by a Device which supports the magnet movably relative to the core, and by a device that moves the permanent magnet in the lateral direction of the core moved to expose the core to the magnetic field of the permanent magnet. 8. Multiple pulse generator according to one of claims 1 to 3, characterized by a permanent magnet, by a flexible dielectric block, the encloses the core and the magnet, the magnet at a lateral distance from the Core lies and wherein a magnetic field maintained by the magnet the core wiped when the magnet and the core are within the block relative to each other be moved. 9. Multiple pulse generator according to one of claims 6 to 8, characterized by a push button on the block, which is arranged so that the same the permanent magnet moved laterally relative to the core. 10. A method for generating a pulse, characterized in that that the wires of the multiple pulse generator according to claim 1 or 2 to the second magnetic field are exposed and that an increase in the strength of the second magnetic field over the predetermined strength is effected beyond. 11. A method for generating pulses, characterized in that the wires of the multiple pulse generator according to any one of claims 1 to 3 to the second Be exposed to a magnetic field, the one above the predetermined strength Has strength, and that the strength of the second magnetic field below the predetermined Strength is decreased. 12. A method for generating a series of pulses, characterized in that that the wires of the multiple pulse generator according to claim 5 to the second magnetic field of variable strength by passing an electric current through them field-generating winding is conducted. 13. A method for generating a series of pulses, characterized in that that the wires of the multiple pulse generator according to one of claims 6 to 9 dem Second magnetic field can be exposed by moving the permanent magnet relative to the core is moved in the lateral direction. Blank page