NO157901B - CORROSION PREVENTION PAINT CONTAINING MANGANOMANGANOXYD SOUTH PIGMENT. - Google Patents

Description

Circuit for storing and transmitting drive current pulses.

in

The invention relates to a circuit for storing and transferring drive current pulses with a high repetition frequency for recording information in or reproducing information from a magnetic thin-film storage device which comprises a conductive base plate serving as a common return conductor for the drive pulses, on which a thin-film storage element is directly placed, and which has a large time constant in relation to the time interval between two successive drive pulses,

as well as at least one drive pulse line which is magnetically connected with the thin film elements and connected to the base plate at one end.

The purpose of the invention is to provide a thin-film storage device with very simple wiring and which can work faster than the known device described above.

This is achieved according to the invention by a drive device connected to the other end of the drive pulse line, which comprises a drive pulse generator which partly emits the normal drive pulses directly to the drive pulse line and partly via a device connected between the output of the drive pulse generator and the drive pulse line, which comprises a delay circuit, and a in series with this connected phase inverter circuit emits a pulse with, in relation to the drive pulse, the opposite polarity to the drive pulse line after the occurrence of a normal drive pulse, as these pulses of opposite polarity serve to eliminate residual strSm originating from the normal drive pulses in the base plate. Due to the fact that there is no additional loss of time while waiting for the residual currents in the retroconductive base plate to arise, the increased working speed is achieved.

Preferably, according to the invention, the phase inverter circuit is a transformer, whose primary winding is connected to the output of the delay circuit, and whose secondary winding is connected to the drive pulse line, the transformer windings being connected so that the secondary voltage has the opposite polarity to the primary voltage.

Advantageously, according to the invention, the delay circuit can be arranged to cause a pulse delay, which is somewhat greater than the length of a normal drive pulse.

An embodiment of the invention will be explained in more detail with reference to the drawing.

In the drawings figo 1 is a flat film storage structure with a metallic base plate, but only one element is shown. Fig. 2 is a diagram with the waveform of the magnetic field acting on an element as it usually occurs. Fig. 3 shows diagrams with waveforms that illustrate the operation of the embodiment in fig. 1 in accordance with the invention. Fig. 4 shows the flow diagram for a drive device that works in accordance with the invention.

To understand the reasons for and the effects due to current in the base plate, reference is made to fig. 1, where an element position is shown for a simplified storage device with flat film. Element 10, which is supported by earth plating 28, is a thin nickel-iron film, which has anisotropic characteristics, i.e. it has stable "light" directions of magnetization oriented as indicated by arrows 12 and 14" oriented perpendicular to the " hard" directions of orientation, as indicated by a double-headed arrow l6. Above the element 10, there are three wires which effect the storage, reading and decoding of a data element. Line 18 is a word line, which when energized/causes element 10 to be oriented in its hard, unstable direction 16. Line 20 is a drive pulse line, and is arranged to be energized in a bipolar fashion to enable element 10 to be oriented in one or the other of its two stable states, e.g. as indicated by arrows 12 and 14" The drive pulse line 20 is energized from the drive member 24 via switch 22. The line 26 is a deflection line, which provides a signal indicating the rotating flux variations inside the element 10 when the drive pulse line 20 and the word line 18 are energized at the same time. Each of the conductors 18, 20 and 2b is connected to the conductive base plate 28, which serves as a ground return when the respective conductors are energized. The drive member 24 is also connected to the base plate 28 via ground wire 30*

In order to cause element 10 to adopt the light magnetization direction indicated by arrow 12, it is necessary to simultaneously energize the word line 18 and the drive pulse line 20. As indicated above, the energization of word line 18 causes the magnetic orientation of element 10 to assume the hard direction 16. By closing the switch 22, a negative potential is applied between the drive pulse line 20 and the ground line JO by means of the drive member 24. This causes a strSm (opposite to that indicated by the arrows) to flow across the ground line 30, the ground plate 28, the drive pulse line 20 and back to the driver 24. The resulting added fluxes in the element 10 cause its magnetic orientation to be rotated counterclockwise so that when the word line energization is interrupted, the element 10 assumes the magnetic state indicated by arrow 12. If it is desired that the element 10 is to assume the stable state indicated by arrow 14, it is only necessary to apply a positive potential to drive p the uls line 20 and at the same time energizing the word line l8„

In practice, the drive pulse line 20 is energized for a considerably longer period of time than the word line 18, as the energization of the drive pulse line 20 extends over the time both before and after the energization of the word line 18. This working technique ensures that the element 10 always assumes the desired magnetic orientation state when the word line energization is concluded. In order to carry this out, however, it is necessary to keep the drive pulse line 20 energized for a considerably longer part of the cycle time for storage.

As the drive pulse line 20 during each storage cycle is energized either in a positive or a negative phase (depending on the information that is desired to be stored in the element 10), a significant earth current is induced in the base plate 28. If the worst case were to occur, namely where a long series of pulses of one polarity occur, the aforementioned earth current becomes quite significant. When, in addition, it is clear that a current storage comprises hundreds and even thousands of similar drive pulse lines, the magnitude of the ground current in the ground plate 28 will be very noticeable.

It has been determined that the overall flux acting on the element 10 is the sum of the flux generated by the current in the drive pulse line 20 and the current passing under the element 10 in the base plate 28 (as indicated by arrows J2). Let's assume that you have an output with a positive potential from the drive member 24. The closing of switch 22 then causes current to simultaneously flow into the drive pulse line 20 and out of the base plate 28 via line JO. It is at this time that the flux density is greatest at the element 10, as the current in the base plate 28 (apart from the current in the base plate from previous pulses) is limited to a discrete area below the element (as indicated by arrows J2). With reference to fig. 2 where the flux density at element 10 is indicated in relation to time, the maximum flux ratio can be as indicated at point 50 on the waveform.

After the switch 22 has been closed for a short period of time, the current in the base plate 28 begins to spread, as indicated by the arrows 34". This effect causes a slight weakening of the flux applied to the element 10, as indicated in fig. 2 at point 52 on the waveform. When the element 10 assumes the desired remanent state at the end of the word drive, switch 22 is opened to remove the drive pulse line influence. Due to the self-induction occurring in the base plate 28, however, current continues to flow there, but when the switch 22 is open, the current does not enter the wire 30, rather it appears to change direction and goes under the element 10, such that indicated by arrows 36 • The reverse current 36 is therefore seen to induce a subtracting flux in the element 10, as indicated by 54 in fig. 2. As the time constant for the base plate 28 is long in relation to the cycle time of the storage device (1-2 microseconds in relation to 100-300 nanoseconds), the reverse current 36 is not consumed when the next function of the driver 24 occurs. Assuming (as indicated in Fig. 2) that a series of positive pulses is applied to the drive pulse line 20, it is clear that the magnitude of the reverse current 36 increases with each successive drive pulse line energization. This results in increasing higher subtracting polarity fluxes 56, 58, 60 etc.

is impressed on the element 10 as the storage device is still working. As this effect is directly opposite to the desired flux direction,

it is very harmful to the way the system works. The size of the reverse current 36 in the base plate 28 has been found to be directly proportional to the duty cycle of the pulses that appear on the drive pulse line 20. In other words, the percentage of time in a storage cycle during which element pulses appear on the drive pulse line 20 is in direct relationship to the magnitude of the current in the base plate. In the currently used storage systems, the working period for the cycle is approximate. 20%.

Since the flux that occurs at the element 10 is shared in equal proportions by the current in the drive pulse line 20 and the return current in the base plate 28, the damage in the impressed field can be expressed as follows:

where K is a constant and I is the element volume.

The expression given above shows the effect of the reverse base plate current resulting from the energization of a single drive pulse line. However, it must be remembered that in a practical storage system there are many drive pulse lines which all contribute to this phenomenon. It has also been found that not only does the persistent reverse baseplate current increase the demands on the current driver and make it difficult to produce disturbance-insensitive elements, but it also creates considerable noise in the sensing lines.

As mentioned above, it has been found that the reverse current builds up or creates a flux which is opposite to the flux generated by a following data signal. As a result of this discovery, it has been determined that if a bipolar drive signal is used, where a signal of opposite polarity either precedes or follows the desired data signal, the reverse current is swept out, and the data signal is subjected to little or no attenuation . This change can best be understood by referring to fig. 3> where current waveforms for storage operation in accordance with this invention are shown. As mentioned earlier, element 10 can be made to acquire one or the other of its light remanent states by simultaneously applying pulses to both word lines and drive pulse lines. These energizations are shown by waveforms 62 and 64, respectively. With positive currents 62 and 64 applied to drive pulse line 20 and word line 18, respectively, element 10 is caused to orient in the direction shown by arrow 14. If it were a normal storage drive arrangement, the termination of the energizing ring 62 of the drive pulse line 20, creating a reverse current j£>

(fig. 1) in the base plate 28. This earth current would last until the next element pulse was applied to the drive pulse line 20. In this case

however, the drive member 24 immediately applies a pulse with the opposite polarity 66 to the drive pulse line 20, which causes the reverse current to be swept out of the base plate 28 over the drive pulse line 20 and into the drive member 24. When pulse 66 ends, a significant part of the reverse current has been swept out of the base plate 28, and the element position is prepared for the next read-write cyclec In normal storage operation, the next thing that occurs will be a read pulse, in which the word line lo is energized and causes the magnetic orientation of the element 10 to be rotated to the direction indicated by arrow 16. This rotation

creates a changed flux which is sensed by the sense line 26 (waveform 69) and fed to a sense amplifier (not shown) which provides a signal indicative of the stored data element. The next write cycle then occurs with either a positive or negative energization being applied to the drive pulse line 20 in accordance with the information that is desired to be inserted into the element 10. In this case, the waveform 70 indicates that a positive potential has again been applied to the drive pulse line 20 and causes the element 10 is oriented in the direction 14. As stated previously, the immediately following signal of opposite polarity 72 causes the reverse current to be swept out of the base plate.

It must be emphasized here that, if desired, the waveform 72 can precede the drive pulse 70 and an essentially identical operation will occur. Furthermore, if a negative energization is applied to the drive pulse line 20 (as indicated by the dotted waveform 74) > then it can also either be preceded or followed by a positive signal 76. The same working technique is also advantageous if it is applied to word lines. However, the lower duty cycle of the dictionary in most storage devices will make this necessary. In each case, the more equal the energies of the two successive oppositely polarized pulses are, the more the sustained opposite current is reduced to zero0

Reference is now made to fig. 4, a circuit diagram is shown with which the aforementioned bipolar drive pulses can be obtained. The drive member 24 comprises a pulse generator 80, which can produce either a positive or negative pulse. Such signal generators are common to the storage device technique and will not be described in more detail. The output from the pulse generator 80 is applied in parallel across the delay network 82 and the resistor 84. The output signal that occurs across the resistor 84 is fed directly to the drive pulse line 20 and then to the base plate 28. The delay network 82 is slightly longer than the duration of the pulse output from the pulse generator 80, so that the signal that comes from there is delayed by a pulse time from the signal that occurs across resistance 84. The output of the delay device 82 is pressed across the clamp 91 on the primary winding 86 of transformer 88. Transformer 88 can be of the well-known bifilar type where the primary conductor 86 and the secondary conductor 90 is wound around a magnetic core, the signal connections to it being such that a signal inversion is produced between the input terminal 91 °S the output terminal 92. The delayed and inverted pulse signal is then applied through resistor 94, the wire 20 and base plate 28. The time sequence for the aforementioned respective pulses are shown at 96. If pulse generator 88 iste in order to produce a positive pulse produces a negative output pulse, the negative signal is immediately sent through resistor 84 to the drive pulse line 20. The negative signals are also delayed in the delay device 82 and inverted in transformer 88 and then impressed as a positive pulse on the drive pulse line 20.

Above, reference is essentially made to storage devices with flat films and the problems that occur and are caused by induced reversed currents in the base plate. However, it will also be understood that similar phenomena occur in any circuit in which a circuit element with a long time constant can occur in any circuit which is exposed to unipolar pulses with a high repetition frequency. Such phenomena have been observed in common drive devices that use transformer outputs. When it is operated at a high repetition rate, continuous current with a long time constant will be induced in the secondary winding with a consequent destruction of the output. This problem can be addressed by using the ideas of this invention.

1. Circuit for storing and transmitting drive current pulses with a high repetition frequency for recording information in or reproducing information from a magnetic thin film storage device, which comprises a conductive base plate serving as a common return conductor for the drive pulses, on which a thin film storage element is directly placed, and which has a large time constant in relation to the time interval between two consecutive drive pulses, as well as at least one drive pulse line which is magnetically connected to the thin film elements and connected to the base plate at one end, characterized by a drive element (24) connected to the other end of the drive pulse line (20) , which comprises a drive pulse generator (80) which partly emits the normal drive pulses directly to the drive pulse line (20) and partly via a device connected between the output of the drive pulse generator (80) and the drive pulse line (20), which comprises a

delay circuit (82), and a phase inverter circuit (88) connected in series with this emits a pulse of the opposite polarity to the drive pulse to the drive pulse line (20) after the occurrence of a normal drive pulse, as these pulses of opposite polarity serve to eliminate residual current originating from the normal drive pulses in the base plate (28). 2. Circuit according to claim 1, characterized in that the phase inverter circuit (88) is a transformer, whose primary winding (86) is connected to the output of the delay circuit (82), and whose secondary winding (90) is connected to the drive pulse line (20), the transformer windings being connected so that the secondary voltage has the opposite polarity to the primary voltage. 3. Circuit according to claim 1 or 2, characterized in that the delay circuit (82) is designed to cause a pulse delay which is somewhat greater than the length of a normal drive pulse.

Claims (3)

1. Corrosion-preventing solvent-based paint containing - 10 - 30% by weight of a resin binder, - 2 - 25% by weight optional pigments including extenders, fillers and corrosion inhibitors, - possibly up to 1.5% by weight pigment suspending agent and - 30 - 90% by weight solvent, characterized whereby 20 - 35% by weight of a color pigment consisting of finely divided manganese-manganese oxide smoke particles with a) a chemical composition comprising at least 96% by weight of manganese-manganese oxide is added to the paint, the rest comprising a mixture of calcium oxide, magnesium oxide, potassium oxide and silicon dioxide with less than 1% by weight free manganese metal, and b) a particle size of which 98% is less than 10 µm. 2. Paint as specified in claim 1, characterized in that the manganese manganese oxide pigment comprises spherical smoke particles of which 99% pass through a 325 mesh Tyler sieve and which smoke particles contain 96 - 98% by weight Mn,0.. 3 4 3. Paint as stated in claim 1, characterized in that a Mn^O^ smoke dust is used as pigment which is precipitated from the exhaust gases from metallurgical smelting furnaces that produce ferromanganese.