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Chapter 4: The momentum order at the electromagnetic engine(OLD VERSION) The presupposition: The ripple current
and the alternate current The alternate current to think of here is so-called " the single-phase alternate current " of the sine wave. Its waveform becomes like the following figure. It has both positive and negative ingredients and the direction in which the electric current flows turns. Figure 13: Alternate current waveform
The ripple current passed through the electromagnetic engine is a direct current to have removed only either of the ingredients of the alternate current in the above figure by rectifying. The waveform becomes like the following figure. It is the electric current to have only either positive or negative ingredient and to flow only through one-way. As for the half time when it flows, the strength of the electric current is zero. But, it is the one which is made very low voltage. Figure 14: Ripple current waveform
It is to think of the size of the electromagnetic force which this ripple current gives each electron pair. The strength of the magnetic field made by the ripple current is in proportion to the strength of the ripple current. Because of "F=BIL", the electromagnetic force which acts on the eternal current is in proportion to the strength of the magnetic field. The strength of the electromagnetic force which acts on the eternal current is in proportion to the strength of the ripple current. Also, because of "F=BIL", the strength of the electromagnetic force which acts on the ripple current is in proportion to the strength of the ripple current. Then, the strength of the electromagnetic force which acts on the eternal current as the reaction is in proportion to the strength of the ripple current. Therefore, according to the strength of the ripple current, the electromagnetic force acts on the superconductive magnet. The electromagnetic force of different strength acts on each electron pair in proportion to the strength of the ripple current, the height of the mountain of the ripple current. Figure 15: The size of the electromagnetic force by the ripple current
An impulse of different strength in each moment is given to each electron pair. Then, the moving velocity of the waveform of an alternate current is supposed to be near the velocity of light. Because of this, it takes the form that the waveform of ripple current foreruns electron pairs. Then, like figure 6, the impulse of different size is given to each electron pair which composes an eternal current in the constant time. Then, I think the condition that at least one electron pair given only the impulse which doesn't fill the constant value in the constant time exists like figure 10 becomes an ordinary condition because the half of the waveform is zero electric current. Therefore, it becomes the condition of figure 12, the impulse of the electromagnetic force to act on electron pairs which compose the eternal current is canceled and the repulsion or the attraction to act on the superconductive magnet is canceled. Because of this, only the repulsion or the attraction to act on the normal-conductive magnet remains and can be used as a driving force. However, even if supposing that the momentum of same size in the direction of electromagnetic force remains in each electron pair like figure 9 and that the repulsion or the attraction occurred in the superconductive magnet, I think that it becomes sufficiently smaller than the repulsion or the attraction which occurred to the normal-conductive magnet. Figure 16: If the electromagnetic force occurs to the superconductive magnet
f1 becomes sufficiently bigger than f2. As a result, it is possible to use "F=f1-f2" as a driving force. |
