25
Claims:
1. Method to create – in a controlled environmental (embodiment, cavity, ) - in the first stage atomic and moleculair elements of the periodic table and their isotops, by means of interaction of radioactive source(s) and chemical or biological materials or both without need for any heat or pressure at ambiant conditions (as triggering factors for creation of atomic or moleculair element or use of any external intervention), where is achieved by means of the use of gasses or mixture of gasses, liquids or mixture of liquids or mixture of liquid gasses and/or solid materials, that can lead to creation of the plasma and release of electrons (for example: creation of atomic or moleculair hydrogen by use of a chemical or biological matter and interaction with radioactive material), where not only the material mentioned above is the source of the atomic or moleculair element, the created element is automatically ionized by the the same radiation source leading to the creation of plasma and the creation of electrons, which these new atoms or molecules or ionized elements of them can be used in the following claims and in the claims of the previous patent applications;
2. Method to create – in a controlled environmental - in the first stage atomic and moleculair elements of the periodic table and their isotops, by means of interaction of radioactive source(s) and chemical or biological materials or both without need for any heat or pressure at ambiant conditions (as triggering factors for creation of atomic or moleculair element or use of any external intervention), where is achieved by means of the use of gasses or mixture of gasses, liquids or mixture of liquids or mixture of liquid gasses and/or solid materials, that can lead to creation of the plasma and release of electrons (for example: creation of atomic or moleculair hydrogen by use of a chemical or biological matter and interaction with radioactive material), where not only the material mentioned above is the source of the atomic or moleculair element, the created element is automatically ionized by the the same radiation source leading to the creation of plasma and the creation of electrons, which these new atoms or molecules or ionized elements can recombine by the energy supplied by the radioactive source to attain extra electrons for them to return and recombine to return to their original state or atomic or moleculair composition; (example where the free electrons can be attained from the metal and hydrogen plasma can return to hydrogen atom and recombin with available oxigen atoms to create water, and for the hydrogen atom to go througght the same ionazion process again by the radioactive material source;
3.
4. of them can be used in the following claims and in the claims of the previous patent applications;
5.
6. Plasma reactor (10A) – located in an embodiment (10B) - in which a rotative plasmatic state (11) is initiated by a scintillation process of one or more gasses (i.e. hydrogen 17) or other matter states in such a way that at least three physical phenomena are provoked inside at least one core (fig.1:B) of the reactor, namely: compression, heat and one magnetic field (22A, 22B) - leading in first instance to the production of energy -, and the reactor is equipped with at least:
a. one separation wall (12A) which can be composed by any state of matter – i.e. a layer formed by liquid plasma, metallic material vapour (i.e. K, Na, Ca, Mg), liquid metallic element layer gas, molecular matter, solid matter and/or by electromagnetic fields - in the reactor cavity, and
b. at least one transportation means (i.e. channels 13A, 74) doors 72A, ports 13B, mouths, valves 13C, slides 13E, pumps, open/closing system, gates, etc.) that can be located everywhere in the reactor (i.e. in a central column 14, in a separation wall 13D and 25, or in the reactor embodiment 10B) and/or connected with the reactor,
i. to transport relevant elements (i.e. hydrogen gas 17 to core B in fig. 1 and fig 2) from outside to the inside of the appropriate core(s) of the reactor;
ii. to transport plasma (11), atomic and/or molecular elements from one inside cavity (20) or core to one or more other inside cavities (21, 19A and 19B) or cores for the purpose to change compositional properties of such elements (26) by the environmental conditions (i.e. gravitational, magnetic, electromagnetic, temperature, contact with other inserted or present atomic or molecular elements, …),
iii. to transport elements to specific areas (19C) – i.e. having another temperature degree - inside one core (fig.1: core E),
iv. to transport recombined elements outside (23) the reactor, i.e. to a decompression and/or a separation unit 24, a storage means 15,
v. to transport plasma or recombined elements to one or more other plasma reactors with similar or different properties, and/or to a twin/multi-reactor (fig.7),
and in which, by repositioning atomic and/or molecular elements in and between reactor cores or reactors (fig. 7), several transformation processes of the elements are possible, such as:
c. the decomposition of existing molecular elements (i.e. CO2) to atomic elements,
d. the combination of atomic and/or molecular elements to new differently composed molecular elements, either in zero-gravitational conditions or in specific controlled gravitational conditions within the core(s),
e. creation of the condition for atomic welding between the elements inside of at least two cores,
f. creation of the Dark Matter which can be withdrawn from the combination of the two matters from at least two cores, which can be collected in gravitational reactors (in 3 x 120° combination gravitational reactors) for space travel and motion,
and from which the reactor cores (fig.1: A, B, C1, C2, D, E) can have each – internally and between them - other conditions and/or dimensions, size and structure – such as:
g. different local temperature,
h. different local compression,
i. different positioning in one or more magnetic fields,
j. different positioning in a gravitational magnetic field,
k. different composition of the wall
l. different thickness (50) of the wall(s),
m. different regularity of the wall shape(s) (i.e. asymmetrical volume 51),
n. different surface dimensions of the wall,
o. separated chambers in a core (fig.1: C1 and C2),
p. non-spherical cores (fig1: E),
so that each core or its sub-chamber(s) can hold the exact conditional parameters to realize the specific phases of decomposition, composition and/or recomposition for some or for all elements involved, which can lead to the synthesis of the desired atomic elements and molecular products of high purity or specific impurity, such as H2O, conductive amino acids, etc., thus the fashionable controlled creation of specific state and composition of atomic elements, molecular elements and molecules for various use, which can lead to the production of rare basic matter, the production of products with high demand, new type of materials, new markets and new business model(s);
7. Plasma reactor (fig.3, fig.4), as described in claim 1, that can alter or rearrange the state, the entanglement and/or composition of introduced atomic elements;
8. Plasma reactor, as described in claim 1, that can alter or rearrange the state, entanglement and/or composition of introduced molecular elements;
9. Plasma reactor, as described in claim 1, that provokes - due to processing steps inside the cores involved - the repositioning of parts of the initial elements to one or more new preferred inter-positioning(s), thus creating at least one preferred atomic and/or molecular element (i.e. H2O), different from the original(s) matter(s) or any state of matter which was initially introduced;
10. Method by which a plasma reactor is used as a separation and synthesis system to provokes - due to siphoning and processing steps inside the cores involved - the repositioning of parts of the introduced initial elements to new preferred inter-position(s) or rearrangement(s), thus creating at least one preferred atomic and/or molecular element, different from the original(s) matter(s) or any state of matter which was initially introduced;
11. Plasma reactor, as described in claim 1, in which a central core (fig.1:A, 27) or chamber is positioned in the central area of the reactor - encircled by at least one core (fig.2:B) that holds the plasma (11) - that is used to generate atomic elements, molecular elements and/or molecules (i.e. diamonds 30, conductive amino acids, etc.) in zero-gravity or low-gravity (31) or any magnetic condition in that core or chamber;
12. Method in which a plasma reactor has a central core (fig.1:A, 27) or chamber, that is encircled by at least one core (fig.2:B) that holds the plasma (11) and is positioned in the central area of the reactor, which is used to generate atomic elements, molecular elements and/or molecules (i.e. diamonds 30, conductive amino acids, etc.) in zero-gravity, low-gravity (31) or any magnetic condition in that core or chamber;
13. Plasma reactor, as described in claim 1, which has at least one regular or irregular torus-type (non-spherical, ring shaped, fig.1:E)(19D) core which can encircle or be encircled by a spherical core or by torus-core which one or the other is in positional of a gravitational field force or a magnetic field force;
14. Plasma reactor, as described in claim 1, which has at least one irregular core (i.e. non-spherical, ring shaped, fig.1:E, asymmetrical 52)(19C and 19D, 62, 63) with other dimensional properties (16) with the purpose to create in the same core different environmental conditions (i.e. inner zones with varying temperature), for example to generate or collect specific molecular elements;
15. Plasma reactor, as described in claim 1, where a cavity(is) positioned mount could be placed - by means of attachment or a specific bracketing position without connection to the central column - for the creation of elements could be created within the core where the created material could be feed to outside of the core on a continuous (i.e. nano technology wire, creation of H2O) or single use production of the material (i.e. single diamond crystal);
16. Plasma reactor, as described in claim 1, of which at least one core (fig.1:C) has at least two separate inner-core chambers (fig1: C1 and C2) , i.e. to create identical gravitational and thermal conditions for different atomic and/or molecular elements;
17. Method by which in the same plasma reactor two or more separate inner-core chambers (fig1: C1 and C2) can be accommodated to create identical conditions like gravitational and thermal conditions for different atomic and/or molecular elements, processed at the same time or in sequence from one inner-core chamber to (13F) another or to other core(s);
18. Plasma reactor, as described in claim 1, which has at least one spiral-shaped core (51, 80) – fixed or rotative within any cavity of the reactor - which makes it possible to create an internal pressure progress and/or temperature difference inside such specific core (fig.8: core B) leading to the creation of a variable gravitational field (i.e. for plasma gravitational distillation) or variable magnetic field(s)(85A, 85B, 85C) within the core(s) or at the boundaries of the core(s) (i.e. for alternating current or power supply due to effect like a wave magnetic field necessary for power generation in turbine);
19. Method where in a plasma reactor, which has at least one spiral-shaped core (51, 80) – fixed or rotative within any cavity of the reactor - which makes it possible to create an internal pressure progress and/or temperature difference inside such specific core (fig.8: core B) leading to the creation of a variable gravitational field (i.e. for plasma gravitational distillation) or variable magnetic field(s)(85A, 85B, 85C) within the core(s) or at the boundaries of the core(s) (i.e. for alternating current or power supply due to effect like a wave magnetic field necessary for power generation in turbine);
20. Plasma reactor, as described in claim 1, being an energy and/or gravity producing and separation/synthesis system, method, concept and technology whereby in a reactor a chain of energetic events is created via a rotative magnetic initiation of a basic ionization of a gas (i.e. hydrogen) or other matters, which then triggers a controllable chain of energy transfers (so called scintillation) to the next following layer(s) of introduced gasses (i.e. He, Ne, Ar, Kr, Xe) and all other introduced elements of the periodic table (i.e. Li, Be, K, Ca, Ti, …Pt, etc.) and/or their introduced molecule combinations (i.e. vapor), with the possibility to injection such materials inside the reactor chamber(s) or core(s) (18), i.e. liquid metallic elements, and which internal effects (such as heat, compression, electromagnetic fields, magnetic gravitational fields, temperature differences, etc.) will be different in the cores and make it possible to rearrange the atomic and/or molecular compositions of the elements by transportation from one core to one of more other core(s);
21. Plasma reactor, as described in claim 1, called the twin-reactor or multi-reactor possessing their own magnetic and gravitational field (fig. 6 and 7) at the same time as overcoming weightlessness in the craft, which has at least two plasma areas, and/or at least two separate or interconnected columns rotating – partly (i.e. only the head rotates 78) or as a whole - individually or simultaneously within at least one static or centrifuged core(s), feed or interconnected - preferable separated by a separation wall (72B) with at least one accessible port (72A) - from at least one core of one side to another, for the use of and the production of new elements and materials;
22. Plasma reactor, as described in claim 1 and 16, which has at the outside of the reactor at least one layer and/or zone of one or more material(s) that will provoke or create charged particles which the interaction of the particles with the magnetic field created in the core of the reactor can create lighting in any frequencies, or microwave production or heating in the surrounding area or vicinity of the system needed for fusion or atomic welding of two or more similar or different elements of the periodic table, for example where one reactor (70A) provides the plasma and another reactor (70B) provides the energy necessary for atomic and/or molecular fusing or welding;
23. A method to create in the same plasma reactor (multi-reactor) at least two plasma areas (70A and 70B), each having their own magnetic (76) and gravitational field (fig. 6 and 7) at the same time as overcoming weightlessness in the craft, and/or at least two separate or interconnected columns (79A, 79B) rotating – partly (i.e. only the head 78) or as a whole (60) - individually or simultaneously within at least one static or centrifuged (73) core(s), feed or interconnected - preferable separated by a separation wall (72B) with at least one accessible port (72A) from at least one core (71A) of one side to another (71B) - for the use of and the production of new elements and materials, and where each of the incorporated plasma areas can have their own function, such as one plasma can have an outer core with at least one layer and/or zone of one or more material(s) that will provoke or create charged particles which the interaction of the particles with the magnetic field created in the core of the reactor can create lighting in any frequencies, or microwave production or heating in the surrounding area or vicinity of the system needed for fusion or atomic welding of two or more similar or different elements of the periodic table, for example where one reactor provides the plasma and another reactor provides the energy necessary for atomic and/or molecular fusing or welding;
24. Plasma reactor, as described in claim 1, called the twin-reactor or multi-reactor (fig. 6 and 7) where the central columns can be either separate (like the single column in fig.1) or joined, either parts (arms 79A and 79B connected to 14) of the same basic column, and of which for mentioned arms and their sub-parts may have different dimensions (i.e. length, height, diameter, speed of the rotation of the head, number of channels, content of channels, etc.);
25. Plasma reactor, as described in claim 1, having in or connected to the embodiment a mechanical (cfr. Watch system, fly-wheel type) and/or electro-magnetic rotational mechanism (i.e. at 250 rpm) which is connected with or making a whole with at least one central column (14) in which at least one container is located that can release precise quantities of the contained matter (i.e. radio-active material or liquid Helium) into the reactor chamber;
26. Plasma reactor, as described in claim 1, to create via a multi magnetic field system which can lead to a magnetic funneling to suppress and strip nucleus protons and neutrons to a single line particles which these type of sequencing can be used in example as proton as one, and neutron as zero for production of any nano-technology component or wire as in binary systems in communication and computers;
27. Method to create magnetic funneling which will suppress and strip nucleus protons and neutrons to a single line particles, which these type of sequencing can be used in example as proton as a One, and neutron as a Zero for the production of any nano-technology component or wire as in binary systems in communication and computers, which is done via a multi magnetic field system that is a set-up of at least two multi-reactors parallel, inline or opposite to each other to create the funneling effect to varying strength in the magnet strength of a core in interaction with its opposite core, to achieve this to varying size of the core or varying the magnetic strength;
28. Plasma reactor, as described in claim 1, which has an inside-chamber size of 1,000,000 cm3 maximum to nano dimensions (i.e. 25 picometer radius), where for a plasma reactor in nano-dimensions the core of the caroline core is realized by at least one magnetic and/or electromagnetic field which hold the protons and neutrons (stripped from electrons);
29. Plasma reactor, as described in claim 1, for the creation of synthesis processes, in example for the recycling of CO2 into oxygen, water, carbon (as described in figure 3) or recombination with any other matter for production of new desired organic, biologic (i.e. amino acids as described in figure 4) and mineral materials, in example the method described in claim 25;
30. Method of a synthesis process for the creation of various materials, by following next steps from which some can be simultaneous:
a. Activation of the plasma reactor: A plasma reactor – which has at least one core – preferably three cores – is started with creating a plasma matter (11), inside a basic centrally positioned core (fig.3: core b.), where the plasma provokes at least one gravitational magnetic field that has gravitational effects on at least the next encircling core (fig. 3: core C),
b. Feed of material(s): At least one atomic or molecular material – called ‘old material’ - to be disintegrated, decontaminate, cleaned, filtered or …, i.e. blood, exhaust gas, … is introduced (feed) in at least one of the outer – lower temperature - cores of the plasma reactor (61), like in figure 3. CO2 gas (28) is feed into core d.,
c. Plasma transport: A part of the plasma is feed to at least one of the outer cores – having the correct gravitational and temperature conditions - to create atomic (H) and molecular hydrogen (H2), and the atomic hydrogen (H) can possible wise be re-feed to the plasma area as re-fuel matter,
d. H2 transport to an outer core: The H2 is feed to a core that contains at least old material which atomic and/or molecular elements are combined with at least H or H2, (i.e. recycling of CO2 where H2 can interact with CO2 leading to separation and creation of H2O (normal, light or heavy) and C (Carbon) and O (Oxygen) in atomic or molecular state,
e. Transport of new materials. The new materials – like H2O – then can be siphoned outside the reactor and/or are further treated inside other cores or special cavities for production of other matters; (see fig. 3 for these steps),
f. Additional process for using new materials: New materials can be feed to other additional cores or sectors (19A and 19B) of the same core which their interaction or recombination with for example atomic C, atomic H and atomic O in combination with the feed of appropriate molecular or atomic Nitrogen (40) can lead to production of amino acids (protein), (see fig. 4 for these additional steps),
g. Further processes: Like the addition of atomic Sodium (Na) which could be obtained by the interaction of Sodium with Hydrogen plasma could be feed to the same chamber as the amino acid leading to production of a new conductive amino acid or protein which can be used for repair or coating of damaged nerves in living bodies;
h. Alternative process: As the total system is always under a magnetic and continuous gravitational force a core of the system can be used for feed of fresh blood where the magnetic field of the system can match the undesired elements within the blood for them to be absorbed or to be attracted to the boundaries or separated from the main stream of the blood before the blood is being refeed into the body (a new magnetic dialysis machine where a miniaturized version of this system could be implanted within the body of the patient where the system will have its own power supply and can last for many years), or to add desired elements into the blood,
method that can be applied to recycle existing waste or exhaust materials such as CO2, lead (i.e. collected in 24), to clean blood from CO2, viruses (like HIV), sugar, PCP’s, for decontamination spaces from hazardous elements (i.e. viruses), creation of H20, oxygen and hydrogen, dissemination process, air filtration, etc.;
31. Method to use basic matters of planets, moons, asteroids and/or comets, or extra-terrestrial and inter-stellar dust to create - due to the recombination process(es) in at least one plasma reactor as described in claim 1, 24 and 25 – new elements and various materials, i.e. fuel for plasma reactors, composing building materials for housing, machinery, electronics and man-made fabrics, nutrition for humans, animals and plants, oxygen, water, etc.;
32. Embodiment (10B), as described in claim 1, that can be solid in full (fig.1), or can contain at least one hollow space (75B) – different from the total reactor cavity (10A) itself – which can be used i.e. as a container (75A) for gas or liquid matter, and/or at least one tube, borehole or pipe (77) to transport elements for a shorter time through one or more specific gravitational and/or magnetic fields or zones of specific temperature created by the reactor;
33. Plasma reactor (fig.8), as described in claim 1, which can create alternating current (83) and direct current at the same time where the alternating current can be created by variation(s) in the thickness (84A, 84B and 84C) of the boundary of one or more core(s) by addition or variation of the same material or any other material in the core or on the core surface – internal (84B) or external (84A) - or on at least one blade (84C), which could be placed at any specific position and any size, such as on a blade (80) or on the reactor core(s) embodiments to create a dip (85A, 85B, 85C) or other variations in the magnetic or gravitational field – different from constant and normal operation production of the magnetic field and/or gravitational field created by the core (85D) - of at least one core that by the interaction of the magnetic field of at least one core and the electrical plates (81A, 81B) placed at the boundary of the core will lead to the creation of alternating current (83) in the combination of setting of the zones and the plates or electrodes;
34. Method where in a plasma reactor (fig.8) alternating current (83) and direct current can be created at the same time where the alternating current can be created
a. by variation(s) in the thickness (84A, 84B and 84C) of the boundary of one or more core(s)
b. by addition or variation of the same material or any other material in the core or on the core surface – internal (84B) or external (84A) - or on at least one blade (84C), which could be placed at any specific position and any size, such as on a blade (80) or on the reactor core(s) embodiments,
to create a dip (85A, 85B, 85C) or other variations (82A, 82B) in the magnetic or gravitat...
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