Alexander A.Shpilman (
alexandrshpilman78@gmail.com )The optical generator of "Axion (Spin) Field" with cross by EM-fields
The generator with optical excitation of "axion field" designs N4/99 demonstrates new idea, but structurally described generator less perfecting of a design N2/99.
In figures 1 and 2 the generator of the advanced design is shown.
Fig.1 |
Fig.2 |
Where 1 - constant magnet, 2 - external copper cone (shield), 3 - internal copper cone (negatively charged electrode), 4 - optical fibre, 5 - aluminium disk (partition), 6 - electric insulate ring, 7 - offshoot of an aluminium disk (dovetail) covered by an alloy to a Rose, 8 and 9 - light sources.
The constant magnets 1 are directed so, that in an interval between them the radial magnetic field is created. On internal copper cones 3 the high negative voltage concerning all design of the generator moves. They fasten to an aluminium disk 5 through of a dielectric ring 6. In an interval between cones 3 and disk 5 the coils from optical fiber 4 are stacked.
In this design, with left and from the right party of a disk 5, a Poyting vector has an opposite orientation. The light flow from sources 8 and 9 moves on a direction a Poyting vector, i.e. in opposite directions in left and right optical fibre of the coil 4.
What reason of such complication of a design?
The reason in that, CHAIN of positive pseudo-charges, moving in direction of a proton, does not get in it at once, and is gone in a magnetic field on a converging spiral 10 (see Fig.3). If moves on electrodes 3 (internal cones) the negative voltage concerning an electrode 5 (aluminium disk) that a spiral 10 (see Fig.4 ) is extended along strings optical fiber 4. In result, the time (length) of passing interaction of a CHAIN of positive pseudo-charges with a flow of light in optical fiber is increased (8 and 9 - direction of a light flow). And on the large distances from a proton, the CHAIN of positive pseudo-charges drifts in the crossed EM-fields on a direction of a vector Poyting.
Fig.3 |
Fig.4 |
This design has one more advantage: the non-uniform magnetic field well keeps a "axion field" in space between magnets 1 (see Fig.1), supporting large density of "axion field" in to a "working zone" - in optical fiber 4.
"Axion field" seep away through a magnetic field along offshoot 7 aluminium disks 5, forms a beam of a "axion field" departing upwards (for figures 1 and 2).
The author expresses the gratitude to Alexander Sboev from Tomsk city for his technical assistance!