Biotron is the key to human health. The use of concentrated radiation of young organisms for health improvement and prolongation of active life

If it had been a parabola, that would have been the end of it. All these 250 thousand rays would be honestly focused at one point. Radiation from other directions will dissipate. But that’s NOT how the sphere works AT ALL!

Now consider Fig. 11. It is clear that from the center of the sphere to its surface, you can draw as many completely equivalent optical axes as you like. For example, the OR2 and OR3 axes. Then all 250 thousand plants from the stand will radiate together and parallel to these axes and will also form two focal lines on the optical axes OR2 and OR3 with a length of 16 cm. At the same time, a part of the sphere P2 will also work on the formation of the focal line on the OR2 axis with a size of 3000x2200 (projection on the sphere of the stand with plants in the direction of the OR2 axis). And for the formation of the focal line on the OR3 axis, a part of the P3 sphere with a size of 3000x2200 mm will work by analogy.

Also, from the center of the sphere O, you can draw many other axes (to the left, to the right, above, below). And, since 250 thousand plants will radiate parallel to these new axes, a focal line of 16 cm long will also be formed on all these new axes with the help of a part of a sphere measuring 3000x2200 mm! And these are thousands of optical axes within the angular aperture of the reflector in the form of a segment of a spherical surface. After all, an axis half a degree apart from the other will already form its own, completely independent focal line from the radiation of all 250 thousand plants from another direction, and another completely independent part of the sphere with a size of 3000x2200 mm will work on the formation of this focal line. Thus, more than 60,000 m2 of the reflector surface will be used to form a joint focal zone of the EKOM Biotron. For example, the angular aperture of the EKOM Biotron reflector is 40x600. If the optical axes are in half a degree, then 80x120 = 9600 optical axes will work on the reflector. If a completely independent part of the 3000x2200 mm reflector works on each such axis, then the total area will be more than 60,000 m2 (3 m x 2.2 m x 9600 = 63360 m). Only half of the reflector area will work on the edges of the reflector. Then the total effective area of one reflector will be more than 30,000 m2. And two reflectors are more than 60,000 m2.

Thus, a spherical volumetric focal zone with a thickness of 16 cm, marked in red, will be formed. And a very high concentration. In such a situation, a parabola will honestly concentrate radiation parallel to its main optical axis from 250 thousand plants to a point and THAT’s IT. The radiation from the blades of grass from other directions of the parabola will not concentrate. For example, if a TV parabolic antenna tuned to a satellite is rotated at least a couple of degrees, then the signal from the satellite will disappear. Therefore, if we imagine the technical possibility to install thousands of parabolas with a size of 3000x2200 mm each with thousands of optical axes that will all be directed to one focal zone, then it would probably be possible to get about the same effect. Using only one parabola for Biotron technology is thousands of times less effective than using only one sphere.