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On Thu, May 31, 2018 at 4:34 PM, Axil Axil <janap...@gmail.com> wrote: > http://www.trinitas.ru/rus/doc/0231/004a/02311041.htm > > 1. Analysis of microscopic traces of MHER from bodies of revolution. > > Experiments with bodies of revolution were carried out on a special > installation. The installation consisted of a collectorless high-speed > motor (up to 50,000 revolutions per minute) mounted on the table top, > engine power supply unit and remote control engine. On the axis of the > engine were mounted bodies of rotation of various materials, made in the > form of cones with a diameter of 20 mm and a height of 20 mm (photo 4). > > A photo 4. *Rotational bodies of various materials* . > > To ensure the safety of work around the engines with the bodies of > rotation, a protective casing is mounted, inside which, along the wall of > the casing (perpendicular to the bases of the cones) and above it > (perpendicular to the axis of rotation), photodetectors packed in opaque > bags were placed. > > A series of experiments was carried out for the exposure of photodetectors > with the following rotation bodies: graphite, aluminum, titanium, copper, > bismuth, zirconium, iron, cadmium, lead. At the same time, light > materials (graphite, aluminum, titanium) rotated at speeds of about 40,000 > rpm, heavy ones - at least 15,000 rpm. > > Exposure time for all bodies of rotation was 360 +/- 20 seconds. Temperature > at measurement: 25 0 С +/- 5 0 С. Comparative analysis was performed by > comparing microdamages at different areas of photodetectors: > > - in the plane of the base of the rotating cones (about 35 mm from the > bottom of the photodetector); > > - at different heights from the plane of the base of the cones; > > - on the upper photodetector located perpendicular to the axis of rotation > of the cones. > > > Spiral traces. > > On all photodetectors located perpendicular to the base of cones of bodies > of rotation, there are macroobjects in the form of rings, semirings and > spirals (hyperbolic and logarithmic spirals), which are located on the > entire surface of the negatives. The greatest concentration of objects is > observed in the central (vertically) parts of the negatives - about 2.5 - > 7.5 cm from the bottom. On photodetectors located perpendicular to the > axis of rotation, there were no special differences from the control > samples. In Fig. 5, for example, the spirals selected by the operator, > recorded by a photo detector near the body of rotation from the iron, are > shown. > > > Photo 5. *Spiral-shaped* *objects on the photodetector, exposed near the > body of rotation of iron (about 7 cm from the bottom, an increase of 64x)* > > A clear pattern of the distribution of spiraling objects, applicable to > all bodies of rotation, was not revealed, because the distribution of > objects over the surface of negatives is not uniform, and on films with a > low emulsion concentration (light films), it is practically impossible to > consider objects (for example, films with a copper rotation body - Cu). > > To make the quantitative analysis of spiral traces it was not possible for > the following reasons: > > - high labor intensity and subjective dependence of the identification > of spiraling traces on the quality of training and health of the operator; > - the nature and mechanisms of the appearance of spiral trails are > unknown, so we can not yet determine the parameters by which the analysis > should be performed; > - the quality of photographs strongly depends on the quality of the > developer, the film and the modes of manifestation, and therefore varies > from batch to batch. > > Table 1 describes the qualitative characteristics of the detected objects > on photodetectors located near different rotation bodies: > > > See more in the referenced document... > > > On Thu, May 31, 2018 at 4:23 PM, Chris Zell <chrisz...@wetmtv.com> wrote: > >> Build it. Simulations aren't enough. >> >> I do think there might be a way to use centrifugal force that hasn't been >> exploited yet, as with the Linevich patent. >> >> >
