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  • evert aether-physics and -philosophy
    the storage surfaces Both are ordered motion pattern so the charge is translocated into the interim storage by most few power Opposite the rear face of that piston should be dielectric material thus the Free Aether can affect most strong pressure onto that face of disorderly motions like explained at previous chapter Ring Shaped Picture 09 14 04 shows why that conception is named ring generator four charge storages C1 to C4 are arranged ring shaped see cross sectional view upside left Each storage is build by a curved pipe The sections are connected by a ring RI grey of non conductive material NL Each storage has two conductive connections towards outside each one for the inlet and one for the outlet IN und OUT The housing GE grey builds an area for the charge LA light green around the storage see longitudinal cross sectional view upside right At this picture below right side that area of charge is filled up by the dielectricum DI violet completely So at this position charge momentary is pushed off the storages C1 and C3 The storages are about 45 degrees long The dielectricum is some longer e g about 55 degree because the front face is funnel shaped Both dielectricum pistons are connected by a cross beam see below left and that beam is fix installed at the shaft dark grey Based on the turning of that rotor here all times left turning charge is pushed off the storages all around and previous discussed processes continuously are repeated Expecially advantageous is the fact all charges and flows are running only within the stator so the rotor is a relativ simple constructional element Phases Picture 09 14 05 shows the rotor RO violet at three positions during its left turning Upside at the picture the rotor momentary is positioned between charge storages C1 and C4 The dielectricum DI violet will push off charge from C4 by further turning That charge flows off the outlet connection OUT green and through the diode D4 into the interim storage Z4 Momentary the conductive connection is ending at switch S4 see green conductive way After that first phase of charge displacement follows the second phase of charge balancing like shown at the middle of this picture When the rotor completely covers the storage C4 exists only the remaining rest of charge at C4 and same time the interim storage Z4 is charged at its maximum A minimum charge also shows the storage C1 white which was swept clean at an earlier phase Thus a charge potential respective a voltage difference exists between Z4 and C1 If now the switches S4 and S1 offer a free conductive connection suddenly occurs a balancing flow see red conductive way up to inlet IN of storgage C1 That impulsive movement flows through the transformer T4 The generated secondary current is available for external usage here not drawn That second phase ends when the rotor did turn further 35 degree at this example

    Original URL path: http://www.evert.de/ap0914e.htm (2016-02-09)
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  • evert aether-physics and -philosophy
    thick The isolating walls of the housing must also be only some millimeter thick Thus within a round cylinder of about 25 cm length e g seven modules could be installed one besides the next at the system shaft Upside the rotor was drawn as a four arm star So all times four sections are covered by the dielectricum and at four sections the charge can reach into the room aside of the storage disc The sections numbers 1 to 8 at first row of picture 09 15 05 must show each smaller surface If the width of each section decreases by 1 10 e g from 100 to 90 and 81 etc finally to 48 see second row of the picture at the very end the width of the band respective the face will be half When the dielectricum glides here from left to right over that storage band CB light green of decreasing size the charge becomes compressed and at the outlet will exist double voltage In order to avoid fading backward wandering charge the storage band CB light green should be divided into sections e g by bottle necks build by slots like sketched at A That constructional characteristic is adopted from the Testatika where such slots are arranged within the storage faces and the inventor Baumann underlined that would be most important The sections could also be build by a row of holes like sketched at B also by several rows and some shifted like sketched at C These holes could be 1 to 2 mm wide with rounded edges and separated one from the next by about 3 to 5 mm distance however the optimum must be found by experiments The importance of that perforation is explained by lower part of that picture Perforation There is drawn a cross section through the storage disc CS here marked red At its side surfaces exists charge LA light green If these surfaces momentary are not covered by the dielectricum at D the swinging motions of the charge reach out into the space aside The housing respective the stator ST grey of non conductive material NL builds the borders for that room Normally the general pressure of Free Aether presses down all charges to likely level at a surface here marked by dark green lines see e g at D Left side at this picture is drawn a part of the rotor respective the dielectricum RO and DI violet moving to right side see arrow It s frontside should be plough shaped and build by metal blue like discussed at previous chapter this constructional element rotates within an area filled up by charge and it s gliding along charged storage faces all times Soon it will become charged by itself the metallic frontside and whole dielectric part as well e g like a PCV ruler This constructional element by its materia and in addition by its own charge affects pressure onto the storage surface see diagonal arrows The charge at the storage surface is piled up at E and transported forward At F is a hole within the storage sheet However there won t be a gap within the charge Opposite contrary swinging charge motions meet at the inner sides of the hole so aether stress comes up at the border line between dark green lines The hole practically builds a Faraday cup so at its border the charge is compressed and accumulated dark green areas Already a depression within the storage surface at G causes the building up of a hill within the charge layer Stronger Thrust The displacement of charge by a dielectricum is depending essentially on the distance of the gap to the conductive surface That rotor here is a rather simple construction at previous example with length and diameter of only about 25 cm Nevertheless that rotating part will show swinging motions so the gap between dielectricum and storage disc could be 0 5 mm at its best However just near to the surface exists the main and most intensive part of charge swinging movements If now the dielectricum arrives at a hole or depression the previous piled up charge marked by arrow at F is pushed into that deepening A reflection occurs and that whirl up again increases the charge hill Thus the dielectricum can sweep away a most greater part of the charge At the other hand that impulsive crash of aether motions into the gaps of holes or depressions affects a shock on the atoms of the conductor At its outer regions thus comes up a material motion i e not only the charge displacement but also current are achieved like discussed at following chapters That perforation of the conductive surface enforces extremely the effect of charge shifting and thus of generating electric current So this technology should also be used at the Electric Ring Generator of previous chapter The possible result is shown at following picture 09 15 06 Charge Accumulation At row A again the sections of the storage disc are listed by 1 to 8 All sections at row D at first are charged by a strength corresponding to 24 V against the earth It s assumed only 1 10 of charge is transported forward when the dielectricum glides over the storage disc so here from left to right From these 24 charge units of section 1 thus 2 4 units are moved to section 2 see row B violet There exists 1 10 less surface for that volume so the charge of section 2 again is increased by 0 2 units row C light green The charge of section 2 thus now shows 24 0 2 4 0 2 26 6 units Analogue from each following section 1 10 of its charge is shifted forward and there that part of charge is compressed by 1 10 After short time the sections from left to right will show increasing charge units At this soft inclination no fading respective back flow occurs if e g 3 0 units of section 3 are pushed forward by the dielectricum it leaves behind an empty section 3 of 29 6 3 0 26 6 units This corresponds exact to the charge splash which is pushed forward by the next dielectricum from section 2 into section 3 So the charge transports from one section to the next are done by minimum resistance Finally at section 8 a charge volume is accumulated corresponding to 49 9 Volt against the earth As here is assumed only the small part of one tenth of each charge is pushed forward and that part is compressed into a face only 1 10 smaller after eight steps the double voltage is achieved If really only the half 1 20 could be achieved the factor would by 1 5 thus increasing 24 V up to 36 V If however 15 of the charge could be involved factor 3 would result transferring 24 V up to 72 V Multistage Compression Upside was mentioned the volt booster could be build by seven modules one aside the next at one shaft These modules are numbered 1 to 7 at row E Row G represents the inlet of the modules and row F represents their outlet All modules are constructed likely Modules 1 and 2 are fed with charge corresponding to 24 V marked light green Based on previous procedure at the eighth section respective at the outlets the voltage rises up to 48 V Both charge volumes are guided into the inlet of section 3 Its first section can take that charge without problems because its surface has double size of section 8 at first level At that second stage the charge is transferred from 48 V to 96 V at the outlet Analogue process occurs right side at the modules 7 6 and 5 see red arrows At third stage the charges from modules 3 and 5 once more are combined into the inlet of module 4 At its outlet finally all charges are available with the voltage of 192 V see green arrow Only real experiments can show which voltage of charges are achieved in reality If that shifting takes these 10 percent that three stage pump results eight fold performance 24 48 96 192 If only five percent could be involved about three fold voltage would be achieved 24 36 54 81 If however 15 percent of the charges could be seized factor 3 would result with much higher values 24 72 216 648 Performance Surplus One can produce an amperage of 24 V with a normal generator or 48 V or 96 V However one needs double or four fold input because the mechanic energy is transferred only 1 1 into electric energy One can transform the voltage of 24 V to 48 V or 96 V with a normal transformer however the amperage will decrease correspondingly The electric performance P U I keeps constant That volt booster however produces an increased voltage by unchanged amperage If previous multistage pump compresses the input voltage of 24 V up to output voltage of 192 V results an eight fold performance As an example the dielectricum pushes forward 1 10 of the 24 charge units of section 1 thus moving off 2 4 units Section 1 remains empty resp now has only the charge corresponding to 21 6 units So these 2 4 units must be reloaded four times into previous modules 1 and 2 also into modules 6 and 7 at same time by 24 V voltage The amperage fed into the input is transported through the whole system and the same amount of amperage leaves the system via the outlet of module 4 at same time sequence however by 192 V output voltage So the decisive performance surplus in comparison with a normal transformer comes up because the same amperage is available however with stronger voltage The decisive difference in comparison with a normal generator comes up that volt booster needs much less power for the mechanical drive Charge must be shifted within this system however moving forward the dielectricum along a conductive surface is nearby force neutral as explained at previous chapter Capacitor Mystery When current is flowing through that storage disc also electro magnetic forces come up all times forward left turning Here however no contrary forces exist There is only charge respective current running well protected by the non conductive isolating housing all times forward into same direction The essential part of the performance is done by the Free Aether as it pushes the compressed charge to the consumer by increased force Tilley stated one third of the energy is necessary for keeping the system running so two third of the energy are available for driving a car or electric tools or lightning That third is also mentioned at other comparable systems e g also at heat pumps which draw additional energy from the environment General Design At picture 09 15 07 upside is sketched how Tilley might have used his spinner SP green for charging batteries BA blue The spinner draws electrons from the plus pole transforms them to stronger voltage and pushes them back into the minus pole Here are drawn three batteries one for the motor MO blue for driving the spinner and control units for internal processes two for external usage e g for driving vehicles or tools or for lightning etc Probably he also used batteries parallel for stronger voltage Depending on energy demand the batteries are reloaded even alternating However this simple conception won t work The electrons won t leave the plus pole voluntary e g for starting the procedure The current from a battery must flow within a closed loop all times normally from minus to plus pole However also when charging batteries the internal chemical processes need a constant relation between surplus and lack of electrons That s why that system needs additional elements especially for starting the system e g some capacitors or intermediate storages These problems are avoided if generally the input and the output of the volt booster comes from runs into an intermediate storage This principle design is shown below at this picture Into the volt booster VB green flows charge from an intermediate storage CN of low voltage and pressed the charge into an intermediate storage CH of high voltage The voltage difference between both storages can be used as a current flow via conductive connections A battery BA blue can be charged by a battery charger unit LG blue At least one accumulator must be available for the motor MO blue and internal control units A transformer TR blue can build demanded shape of current for consumers V blue With these intermediate storages one is no longer bound to the obligatory closed circuit when using batteries Changing demands for current are better to manage when using wide intermediate storages Recharging the storage of high voltage CH must not run totally synchronous to demanded current but can be done some time shifted Depending on demand the volt booster can work with varying speed and or different input voltage Opposite one can stock up the storage of high voltage in advance The wider the intermediate storages are the more stabile and flexible the system can be controlled Large Intermediate Storage Picture 09 15 08 upside right shows the round cylinder of a volt booster VB with seven modules At previous example its length and diameter would be some 25 cm to 30 cm An intermediate storage ZS upside left could also be a round cylinder of comparable size A longitudinal cross sectional view schematic is drawn below left side and its cross section below right side The storage faces are build by bare round copper or aluminium pipes with radius of 4 5 6 and 7 cm see green rings There is enough air space for the charge at both sides of each pipe The Free Aether needs that room for working effective In order to differ the charges between the hollow copper cylinders should be installed thin isolating pipes here not drawn By the length of about 25 cm a surface of about 0 7 m 2 is available for the storage of low voltage CN green Within same housing could be installed the storage for high voltage CH red by pipes with diameter of 9 10 11 and 12 cm Both sides of these pipes build a surface of about 1 3 m 2 At both storage areas CN and CH here are drawn an inlet and an outlet IN and OUT All pipes of an area are conductive connected So this storage has an area of low and an area of high voltage however this might not be mixed up with a common capacitor Also the Testatika used big Leidener Bottles with internal connected faces That s rather difficult to understand for experts because it makes no sense based on the idea of positive negative charges However these pipes are advantageous round storage faces for exclusive existing negative charges How much Coulomb by which voltage one finally can store at these free storage faces no expert dared to tell me because here the common capacitor formula are not valid Running Mode At picture 09 15 09 previous principle design is added by some functional elements Generally for starting the system all storages and accumulators must be charged At running mode the volt booster VB green pushes charge into the storage of high voltage CH192 dark green A diode D1 blue must avoid back flowing from CH192 to VB e g if the volt booster is not working momentary Based on the high potential gradient to the storage of low voltage from CH192 to CN24 current will flow as soon as a conductive connection is available Opposite between the storage of low voltage and the inlet of the volt booster between CN24 an VB exists only a small gradient The average level of section 1 is about 24 0 V against the earth One tenth is transferred into section 2 The dielectricum leaves behind an empty section 1 with 24 0 2 4 21 6 V So the difference to the storage of low voltage are only these 2 4 V Probably no sufficient balancing flow will come up because the charge should run by itself from CN24 into section 1 of the volt booster within relative short time This charge process could be ensured by an transformer T1 blue below left It should press the secondary current from storage CN24 with few increased voltage into section 1 at the very moment when the inlet is opened This transformer T1 is supplied by an accumulator A1 blue below left which also supplies the mechanical drive MO blue of the volt booster Performance Input and Output The volt booster of previous example takes charge into four modules 1 and 2 plus 6 and 7 e g of one ampere with a voltage of about 24 V every second The performance is P U I so here the input is 4 1 24 96 W The volt booster at the outlet of module 4 delivers these 4 ampere also each second now however with the voltage of 192 V so here the output is 4 192 768 W For continuous running mode the performance taken from the storage of low voltage must be reloaded No matter which way thus 4 ampere with 24 V corresponding to 96 W must be fed into the storage of low voltage Also the consumption from accumulator A1 must be replaced same time e g by recharging a second accumulator by an other transformer T2 and A2 blue at the middle of the picture where A2 could also be identical with A1 So keeping up the running mode demands about one third of the cross performance see Tilley Remaining are about 500 W for external usage These could

    Original URL path: http://www.evert.de/ap0915e.htm (2016-02-09)
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