DE3111342A1 - Electrical current generating element - Google Patents

Abstract

The basis is an effective unit consisting of the interacting properties of magnetic-electrical induction and of thermodynamics, and the associated wire loops. The Möbius strip is used as a matrix for the method of operation. In this case, the wire loops run like a mesh in the same way as the transverse thread and the magnetic field migrations - the switched rotator mechanism in a ring-like track - in the same way as a longitudinal thread. In the thermodynamics method of operation, in contrast, the magnetic field migration and the wire loop have the same axis direction, in order to convert electrical energy into heat. In this case, it is not only the case of storing the extracted electrical energy, but of simultaneously also dissipating the same heat for thermodynamic interaction in the system of magnetic-electrical induction. The structure of the Möbius strip actually facilitates this interaction. The circumferential tracks of the lines of the bisections and trisections allow temporarily rising interactions to come into play. The economy is achieved because suitably reconfigured superconducting switches are used for the switching and magnetic elements. Families of magnetic field migrations can then be assembled by means of integrated circuits to achieve a programmed efficiency. <IMAGE>

Description

The invention of an electrical power generation element consists in the fact that several, simultaneously-taking place, different and / or different magnetic field migrations, which are carried out by electronically controlled and / or switched magnetic field elements on a ring-shaped and semi-twisted wire winding band, with the help of a design a rhythmic sequence of movements with low operating current requirements in order to cut through the wire winding for the purpose of generating electrical power with magnetic fields that run in a rhythmic sequence.

The cutting through in a uniform rotation, which is used as an example in the principle of the dynamo machine, is known.

Compared to the prior art, the object of the invention is that a rhythmic cutting technique is represented by a rhythmic sequence of movements of several, simultaneously occurring, different and / or different magnetic field migrations.

According to the invention, this is achieved by choosing a rigid arrangement principle here, which is characterized by a special path-geometric mode of action. Furthermore, by classifying special single switching systems, the representation "magnetic field" and the representation "switching process" should take place in one and the same sphere of activity. This is a process that can only be switched and therefore requires the use of operating current. However, due to particularly efficient interrelationships, the use of operating current is kept so low that the energy threshold can be overcome as soon as possible.

The three-part Möbius strip can be assumed to be known. For example, the Möbius strip, which is cut open along a third of its width with scissors, has the following effect: "The scissors probably cut twice completely around the strip, but they only make one continuous cut!" If you first imagine the wire winding in the arrangement as a zigzag band, then you also imagine that its two ends are connected to each other after half a turn, you get a closed ring in this way, which is the essence of Möbius Band. If you divide the cross-section of this band into three parts, you get the trace of two routes on this band. If you continue to look at this route like a line made up of points, you can reach z. B. each at one point the attachment point of a single, but consisting of two parts, and thus also attached to both sides of the tape magnetic field element.

Such a two-part magnetic field element can, for example, under appropriate conditions, cut through the wire winding strip, i.e. the wire winding. The continuous sequence of such locations would correspond to the above-mentioned connection of the points, and thus to the representation of the route. The switching and / or the control of such a relationship leads to a continuous magnetic field migration, according to the example of the scissors cut mentioned above.

In order to overcome the energy threshold as efficiently as possible, single switching systems of data processing systems are used to represent the magnetic field elements, which actuate the ON / OFF switching process by means of a magnetic field excited by a small current pulse. Likewise, with these single switching systems, for example, the area of the magnetic field effect still has to be broken down into two effective sections. The purpose of this decomposition is not only to expose this magnetic field, but it is also intended to provide the opportunity to form a gap.

A gap, as it were, as a gap that should be filled with the wire winding!

That such single switching systems can be interconnected as a series connection to form a continuous series results from the nature of the matter. But if you combine such a series to form a ring, you achieve an all-round hike. An all-round hike that has to be fed by a low operating current. Such all-round hikes could, under appropriate conditions, be characterized, for example, by the time differences between the switching operations, i.e. by the different speeds. But also from the different magnetic field strengths, and also from the different directions. Such properties are made to understand an all-round hike as a whole, a whole, which can thus be classified with a corresponding value.

If you put such all-round hikes on the track of the route of the Möbius tape, here more correctly said the wire-winding tape, you have reached the level of efficiency that is characterized by the rhythmic cutting technique. The rhythmic sequence of movements results from the opposing positions, which can be established through the geometrical way of working.

Since special electrical magnetic field elements are not used here, nor with special switching and / or control circuits, the energy consumption of the operating current remains extremely low. Especially since the different and / or different magnetic field migrations taking place at the same time, which can be detected by respective place values, can be combined into a composition.

This unequal, more rational structure of effects can produce the representation of a rhythmic sequence of movements by simply coordinating them.

In an example of the known type of single switching systems in data processing systems, the so-called "layer kyrotron", the function for the utilization as a rational magnetic field element can easily be explained.

(The function for utilization as a rational magnetic field element can easily be explained in a layered kyrotron).

In a layered kyrotron there is an insulating layer on a superconducting base plate, over which there is a wide strip conductor made of tin - or another soft material - which switches back to normal conduction even at relatively low magnetic field strengths. This is followed by a second insulating layer and then a narrow lead tape in a crossed position to the first tape. If the control circuit in which the lead tape is located receives a current pulse, the resulting magnetic field switches the part of the tin tape underneath to normal conduction, while the superconducting state is maintained in the lead itself. If you go here, for example, you pack the layers, the superconducting base plate, the insulating layer and the strip conductor made of tin or another soft material above it to form a so-called "reflex-related active section". If you go further and pack the layers, again the second insulating layer and then a narrow lead tape in a crossed position to the first band as well as a so-called "projecting effective section" you have broken down the single switching system into a relationship system of two effective sections .

With this breakdown, the interrelationship between the magnetic field and the element has been structured in such a way that an intermediate space can be arranged between the two active sections. This gap is then the place that is filled by the wire winding. Thus, this place corresponds to the place on the route where, as is known, the magnetic field element cuts through the wire winding. The continuous sequence of such places is given by the course of the route.

Since the mode of action here is characterized by several simultaneous magnetic field migrations, a multi-part structure has to be achieved on site. There are several possibilities for that. For example, through the symmetrical arrangement on circular points of an imaginary circular disk, several magnetic field elements can be brought into effect radially. This radial function cannot give rise to any mutual interference.

This gives you the opportunity to create compositions with several magnetic field hikes. One can for example Conceive a composition of intermittent intersection points for the rhythmic movement sequences. Such a composition, which is characterized by the sequence of points of intersection, can organize a new sequence of movements with a higher overall efficiency, which is indicated by the summation of the magnetic field strengths that come together. This interference mode of action would then be suitable for overcoming the energy threshold. Such vibrations, which are excited on a small scale and which are then transferred to a larger scale, can do a tremendous amount of work by simply coordinating them.

Furthermore, it would also be conceivable, for example, to classify corresponding microprocessors in accordance with the compositional conceptions in order to be able to assemble a special connection from intermittent route sections, if necessary.

Another application example would be the additional classification of a wire loop running in the axial direction. Since this electrical conductor has to heat up under the action of the magnetic fields, such temperature effects could possibly also be used. For example, such a temperature gradient in the wire winding could be of particular importance!

The relationships are explained in more detail using the drawings. Show it

Figure 1 The entirety of the electrical power generation element as a scheme.

Figure 2 section and view of the wire winding tape

Figure 3 point design for the arrangement of several magnetic field elements.

In Figure 1, the shape of the wire winding tape (1), which is characterized by the structural feature of the Möbius tape, is striking. Two lines (2) run on this belt, which, as a line made up of points, can also convey the locations for the magnetic field elements (3). The routes (2) run twice completely around the strip (1) and divide the tape into three sections. The two wire ends (6, 7) appear at one point on the tape, where the current can then be tapped. The unit (8), which inputs the operating current into the magnetic field migration as an electrical impulse for the function of the single switching system, is located outside.

In FIG. 2, in the section of the wire winding strip (1), not only can the location for the course of the route (2) be made out, one can also see the location for the attachment of the magnetic field elements (3). Not only can a magnetic field element (3) be broken down into two corresponding effective sections, but also the resulting space between the two corresponding effective sections, and thus also the wire winding strip (1) running through here.

When looking at the wire winding tape (1), two examples can be seen as differences. In the example case (9), the wire winding is represented by a crossing zigzag pattern. In contrast, in the example case (10) the wire winding appears as a zigzag pattern running next to one another.

In Figure 3, the multiple structure of the point design is explained. One can see the imaginary circular disk, on whose circular points the individual two-part magnetic field elements (3) are attached in such a way that they correspond in radial section with their opposite effective section. It can be seen the space that is filled by the course of the wire winding tape (1). Likewise, at the intersection of these radially acting magnetic fields, one can see the location of the arrangement of an additional axial wire loop (5), which could optionally be introduced.

Claims (14)

1.) Electric power generation element characterized in that several, simultaneously-taking place, different and / or different magnetic field migrations, which are carried out by electronically controlled and / or switched magnetic field elements on an annular, half-twisted wire winding tape, using a design a rhythmic sequence of movements with low operating current requirements in order to cut through the wire winding for the purpose of generating electrical power with magnetic fields running in rhythmic sequences. The generated electrical current can then be picked up at the wire ends. 2.) Electric power generation element according to claim 1, characterized in that the wire winding tape takes over the structure of the Möbius tape as a structural feature. 3.) Electric power generation element according to claim 1 and 2, characterized in that the wire course in this wire winding band is formed by a crossing zigzag pattern. 4.) Electric power generation element according to claim 1, 2 and 3, characterized in that the wire course in this wire winding band is formed by a perpendicular zig-zag pattern. 5.) Electric power generation element according to claim 1, 2, 3 and 4, characterized in that a three-fold subdivision is effective in the cross section of the wire winding strip. 6.) Electric power generation element according to claim 1, 2, 3, 4 and 5, characterized in that simple switching systems of the data processing systems are used, which actuate the switching ON / OFF by means of a magnetic field excited by a current pulse. 7.) Electric power generation element according to claim 1, 2, 3, 4, 5 and 6, characterized in that simple switching systems are broken down into two corresponding action sections. 8.) Electric power generation element according to claim 1, 2, 3, 4, 5, 6 and 7, characterized in that by breaking it down into two corresponding effective sections, a gap is created which is filled by the wire winding. 9.) Electric power generation element according to claim 1, 2, 3, 4, 5, 6, 7 and 8, characterized in that several magnetic field elements can be arranged in one place through the multiple links at the location. 10.) Electric power generation element according to claim 1, 2, 3, 4, 5, 6, 7, 8 and 9, characterized in that different magnetic field migrations can be represented in different time differences. 11.) Electric power generation element according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9 and 10, characterized in that different magnetic field migrations can be represented in different magnetic field strengths. 12.) Electric power generation element according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 and 11, characterized in that different magnetic field migrations can be shown in different directions. 13.) Electric power generation element according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 and 12, characterized in that an additional classification of microprocessors can be provided. 14.) Electric power generation element according to claim 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 and 13, characterized in that the classification of an additional wire loop can be provided in the axial direction of the route .