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Gravity-Centrifugal-Power-Motor Objectives At chapter Swing-Circuit-Motor (SCM) above, a design was worked out corresponding to build-up of a loop-swing. There, two axis were demanded (system- and exeter-axis) and two 'wheels' did turn within each other. So this will be a rather difficult technical construction. By this chapter now shall be examined, how effect of building-up mechanical oscillations could be realized easier. So only one axis should be neccessary, nevertheless masses should move like at uneven 'movement of pendulum', above this phase shifting by intermediate storage of forces must be guaranteed.
Pendulum with radial suspension At previous chapter Mechanical Oscillating Circuit Harald Camera did mention example of a pendulum with radially working spring, like schematically shown once more at picture EV SKM 31 upside. Around system axis (SA) a pendulum, here called rotor arm (RT, German Rotortr " ager), can swing. At the rotor arm effective mass (MP) can glide inside and outside. That radial movements are limited resp.
controlled by a spring element (FE, German Feder element). Potential energy of level is transformed into kinetic energy at downward-phase, opposite energy of movement is re-transformed into energy of high level at upward-phase. In addition, power is stored into spring intermediately, so some later power is restored into pendulums oscillation. Mass will move at an U-shaped track. Mass will show maximum speed at its lowest point of track (A) and there will press down spring at its maximum. Following relaxation of spring will show analog relations of forces, based at symmetry, so this mechanical oscillation will be stable (no friction assumed).
Effect of building-up oscillations can only be achieved, if symmetry is broken. This could be done e. g. as shown at picture EV SKM 31 downside. Asymmetric track Tension of spring downside should have to be stored for a short time, e. g.
any mechanism could allow relaxation of spring some later (B). Counter stored energy then would exist less forces (resulting force of gravity power and centrifugal power), showing upward more and more. Power of spring afterward could move mass easier and faster towards upward-inside (C). Angles speed thus will be accelerated and mass will be brought to higher level (D) than starting level. This mechanical oscillating circuit thus will be build-up without input of energy from outside. Progressive suspension By this concept an asymmetric track is achieved.
However, this pendulum swinging resp. effect of build-up oscillations is technically usable only if a momentum is achieved at a constant turning shaft. That's why at picture EV SKM 32 again is shown a round turning (counter clockwise) loop-swing. Schematically there are drawn multistage spring elements, by which demanded delay of spring's relaxation can be achieved. Around system axis (SA) is constantly turning the rotor arm (RT), here for example represented by twelve spokes. On these rotor arms effective masses (MP) can glide inwards and outwards.
Inside and outside spring elements (FE) are installed, working in radial directions. These springs are doubled, each element existing of a long spring arranged within a shorter spring. Distances of movements of springs are marked by dotted resp. red circles. At 12 -o'clock-position speed is low, so practically only gravity weights onto inner both springs, pressing these downward.
At 11 o'clock reduced resulting force (of gravity power and centrifugal power) does allow some relaxation, nearby 10 o'clock inner-short spring will be relaxed. Until 9 o'clock inner-long spring will have moved mass to larger lever arm. There, mass will fall downward nearby vertically. Falling-curve however will be bended to right side by outer-long spring nearby 7 o'clock. Nearby 6 o'clock that outer-long spring will dip into outer-short spring, so now resulting force will weight on both springs. Finally at 5 o'clock a fix support will be reached resp.
here resulting forces will show less amount (and showing more and more upwards), so springs can sling mass inside-upward. Nearby 4 o'clock outer-short spring, nearby 3 o'clock outer-long spring will be relaxed again. Via 2 - and 1 -o'clock-position gravity will increasingly with at inner springs, pressing together first that inner-long spring, lastly also inner-short spring (as mentioned above as starting point). So as a whole, well known track of previous chapters will be achieved. Optimum By this principle of radially working springs is documented, building-up of mechanical oscillation can be done also at a constantly turning wheel. This principle here is shown only schematically, track of mass drawn here won't be optimum at all.
Properties of springs, distances and radius naturally must be optimized, so demanded tracks are achieved (analog free swinging pendulum inclusive phase shifting). Even rotor arms show constant angles speed, masses at different sections must show different speeds. Elasticity and lengths of inner and outer springs will have to be rather different (opposite to sketch shown here). By simulation program must be calculated degree by degree, by well known formulas, when which spring suitably will take resp. give which about of power. Naturally instead of springs marked here, elastic elements of diverse kind can be used.
Above this, it would also be possible e. g. , mass won't glide on rotor arms but each mass to keep within a net of several springs. Essential fact will be, outer-short spring element will start to work finally at 6 -o'clock-position and by its reaction demanded delay of phase-shifting will be achieved. If this can't be achieved by this concept of double-stage springs, again a second axis will be neccessary, based at following considerations.
Diagonal U-shaped track At picture EV SKM 34 upside (A) U-shaped track above is shown once more. This track will exist, if a mass (MP) can move at a rotor arm (RT), can swing free around a system axis (SA) and thereby will be guided by a radially working spring element (FE). Here, that spring element is marked only one time, rotor arms and mass is shown several times in diverse positions, green curve shows track of mass. Phase shifting would exist, if the U-shaped track would be inclined a little bit, e. g.
like this picture shows at the middle (B). In that case however, track left side would be pressed down some more (based on gravity) and also right side. Instead of symmetric U-shape, now an uneven track will result, e. g. like shown at this picture downside (C). Ideal Looping In order to get a technically usable solution, instead of ahead and back swinging pendulum a 'looping swing's hold be used.
Thus at picture EV SKM 35 track above is completed upside by an almost circled section of track. At a whole thus will result an egg-shaped track with longitudinal axis inclined. However, track won't be symmetric to this longitudinal axis, cause gravity will deform that diagonal track downwards. At picture above were shown positions of mass after each same section of angles.
Here now positions are marked, mass will take after each same time unit. Distances between two mass positions thus will show speed of mass within that section. At upside positions mass will move slowly, then will be accelerated increasingly into falling curve. Maximum speed however will be achieved finally after 6 -o'clock-position.
Afterwards mass will be singer inward-upward back again towards upside. This process of movements were described by viewers of Remote Viewing sessions, demand of phase shifting is covered, intermediately stored energies will bring momentum wanted. So a track similar to this one will be ideal track for building-up of a mechanical oscillating circuit. Bended spokes At Remote Viewing sessions also was noticed, some parts of Bessler-Wheel 'had to be in water before'. Why this - for bending wooden spokes? Cause ideal process of movements above will demand a wheel with bended spokes, as schematically shown at picture EV SKM 36.
A wheel has to turn around system axis (SA). Essential parts of that wheel are spokes, which outside must be bended ahead (in turning sense). At these rotor arms (RT) effective mass (MP) will glide inward-outward. Movements are controlled by a spring element (FE), which will be anchored at the one side at the mass, at the other side around exeter axis (EA). Here, spring element and mass is drawn only one time, spokes are drawn at diverse positions while turning constantly. Track of mass is marked by green curve, corresponding to...
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Research essay sample on Gravity Centrifugal Power Motor
