KR20020087817A - KNY Chaos nuclear reactor - Google Patents

Abstract

PURPOSE: A mid/low temperature hydrogen nuclear fusion method and semi-fusion reactor is provided to achieve improved economic advantage by permitting a nuclear fusion reaction to be occurred at a mid/low temperature. CONSTITUTION: A mid/low temperature hydrogen nuclear fusion method comprises a step of inducing a first combustion by adjusting hydrogen and oxygen such that surplus hydrogen is generate, and allowing the hydrogen and oxygen to react to a catalyzer; a step of accelerating plasma by providing deuterium and tritium, while accelerating plasma by an electromagnetic field of coil and electromagnetic wave of magnetron; and a step of inducing fusion reaction at a relatively mid/low temperature, by adjusting chaos of surplus hydrogen to reach a maximum degree through a corona discharge, interference of laser beam and resonance. A semi-fusion reactor comprises a closed cylinder type bearing wall(3) integrated with a solenoid coil; a heat exchange unit for circulation of water coolant; a tube type air chamber surrounding an incinerator and heat exchange unit; an automatic control unit; an electrolytic analysis unit(26) for analyzing water into hydrogen and oxygen; a multi-stage nozzle unit for supplying hydrogen and oxygen to a combustion chamber; a first combustion unit(33) for first ignition; a second combustion unit(39) for supplying deuterium and tritium; a third combustion unit(43) for supplying active oxygen; a solenoid electromagnetic field induction unit; a magnetron electromagnetic wave oscillation unit; a high pressure induction unit(17); a corona discharge unit; and a laser beam radiation and laser resonance induction unit.

Description

Medium and low temperature hydrogen fusion method and semi fusion reactor {KNY Chaos nuclear reactor}

The present invention relates to a low-temperature hydrogen fusion method and a semi-nuclear fusion furnace using water and heavy water.

When the deuterium nucleus fuses with the tritium nucleus, helium nuclei and neutrons, also called alpha particles, are produced. In this process, the small mass loss caused by the rearrangement of the inner structure of the nucleus is released as the kinetic energy of the particles produced after the reaction. At this time, the amount of energy released per reaction is 17.6 MeV.

It is capable of producing 10E8 kWh of energy, which is 1 kg of fuel, meeting the requirements of current 1 GW-class power plants.

In general, fusion requires more than 100 million degrees of high temperature and many advanced equipment to maintain and control its state. The main devices of the current development status are under study as large superconducting magnets, large ultra high vacuum vessels, cryostat cryogenic vessels, ultra high temperature special materials, ultra high temperature plasma counters, vacuum exhaust machines, power supplies and diagnostic devices.

These advanced technologies cost enormous development costs, and if development through international cooperation proceeds smoothly, it is expected to be put into practical use until 2040 after the engineering development phase is completed by 2025.

In addition, using a brown gas obtained by electrolysis of water (water gas kept in a mixed state without separating hydrogen and oxygen), it was burned together with a catalyst such as hexane to develop a heat generating device using the heat of reaction. Not so high.

The object of the present invention is a low-temperature hydrogen fusion method and a semi-fusion reactor to solve the above problems and to implement a simple fusion reactor using water and heavy water, which can be more economically and practically used in a short time.

We need to find a way to make nuclear fusion without the use of complex and difficult advanced devices, and it is best to use water that is always with us as the main material. The reason why expensive fusion equipment is needed in the existing fusion method is that it needs to maintain and control the high temperature of 100 million degrees or more in the hydrogen fusion reaction.

The present invention relates to a low-temperature hydrogen fusion method and a semi-fusion reactor, and provides a low-temperature semi-hydrogen fusion device that induces a chaotic [CHAOS] state so that a partial fusion reaction occurs even at a relatively low temperature [2000 ℃ ~ 20000 ℃] I will.

1 is a diagram showing a process for inducing nuclear fusion using active oxygen in a chaotic state by the low-temperature hydrogen fusion method according to the present invention.

2 shows nuclear fusion of deuterium and tritium.

3 shows the conceptual appearance of a semi-fusion reactor

4 is a cross-sectional structure diagram of a low-temperature hydrogen fusion process and a semi-fusion reactor

Figure 5 shows the details of Figure 4

6 is a front view of FIG. 5

7 is a conceptual diagram of a low-temperature hydrogen fusion method and a semi-fusion reactor

8 is a comparison of the semi-fusion reactor and other heat engines

*** Description of each code

1. Heat Exchanger Carousel Wall

2. Pressurized water

3. Inside wall of combustion chamber [with solenoid coil formed inside]

4. Coolant

5. 3rd combustion flame [nuclear fusion]

6. Check valve [internal pressure control and exhaust gas control]

7. Free radical plasma

8. oxygen nozzle

9. Magnetron

10. Combustion chamber inner wall with coil

11. Second combustion flame

12. Deuterium and Tritium Plasma

13. laser beam

14. Primary combustion flame

15. Laser Gun

16. Laser Oscillation Tube

17. Ultra High Pressure Induction Device

18. Secondary Catalyst Rod

19. Oxygen Supply Nozzle

20. Primary catalyst rod

21.Battery

22. Hydrogen Supply Nozzle

23. Hydrogen and Oxygen Separator

24. Central control unit

25. Oxygen Distribution Pipe

26. Electrolysis device

27. Oxygen Waiting Room

28. Water

29. Vent

30. Water supply pipe

31. Oxygen Supply Pipeline

32. Solenoid Coil

33. Primary catalyst rod automatic entry device

34. Deuterium and tritium waiting rooms

35. Second catalyst rod automatic entry device

36. Cooling water intake

37. Deuterium and Tritium Nozzles

38. Discharge electrode

39. Secondary combustion discharge tube

40. Ultra high pressure induction device for discharge

41. Tubular multipurpose air chamber [internal pressure control and heat exchange function]

42. Semi-nuclear combustion chamber

43. 3rd combustion discharge tube

44. Combustion gas exhaust pipe

45. Cooling water [vapor] exhaust

46. Insulation shielding outer wall

47. Reflection of laser beam and interference of light [resonance]

In order to achieve this purpose,

The present invention relates to a low-temperature hydrogen nuclear fusion method and a sebi fusion reactor, which naturally accelerates deuterium and tritium, and adds electromagnetic fields, electromagnetic waves, discharges, laser beams, active oxygen, etc. to cause chaos and resonance. It is a method and apparatus for partially implementing nuclear fusion by momentarily incapacitating the repulsive force between hydrogen protons or inducing a high energy state beyond the repulsive force.

Let's take a look at the operation principle and structure of the low-temperature hydrogen fusion method and the semi-fusion reactor

First, the method relates to the low-temperature hydrogen fusion method of inducing chaotic state [see FIG. 1],

Initially, the amount of hydrogen supplied is greater than that of oxygen to cause hydrogen and oxygen to react in a constant ratio of imbalance. In principle, the volume of oxygen in the air is included in the ratio. When the exothermic reaction occurs and the temperature is overheated, the excess hydrogen molecules that wander around unbonded become increasingly overheated. Hydrogen and oxygen are additionally supplied through each nozzle to increase the exothermic reaction and continue to raise the temperature. At the same time, a reaction catalyst (hydrocarbon, silicon compound, iron, metal, nickel, tungsten, aluminum alloy rod) is introduced to induce a rapid rise in reaction temperature.

Among the natural hydrogens, 0.015% contains deuterium, a mixture of these and excited hydrogen molecules and atoms that accelerate and rebound. Little by little, hydrogen, oxygen and a catalyst are added to the hydrogen to combine with oxygen to induce even more superheat.

The heated gas forms a cylinder, and a cylindrical coil is wrapped around the rising pillar, which emits electromagnetic fields.

The excess hydrogen, which escapes from the lack of oxygen, is activated in an excited state and begins to ionize by the electromagnetic field.

The temperature continues to rise and some of the excited hydrogen molecules and atoms are accelerated to an ionized plasma state.

Oxygen molecules are also momentarily activated during this process, and a unique phenomenon occurs when a large number of excited hydrogen is combined with active oxygen in the plasma state. That is, in the process of bringing together several excited hydrogens at the same time to combine with one active oxygen, the hydrogens that are not bound collide with each other. In this process, the hydrogen molecules are split and are separated into hydrogen atoms. In some cases, oxygen and a catalyst are combined. At this time, it emits a lot of energy, and the light and heat increase the temperature inside the furnace and accelerate the hydrogen atoms and ions.

This completes the primary combustion. [4000 degrees]

The heated gas forms a long cylinder, and a cylindrical coil is wrapped around the rising pillar, sending out electromagnetic fields, and at the same time the magnetron starts to emit electromagnetic waves.

Hydrogen and oxygen are gradually supplied from the nozzles formed on the inner wall of the cylindrical furnace, which continues to expand, inducing hydrogen to combine with oxygen even more. The additional oxygen is immediately activated and excited into ozone or atomic ions, and at the same time hydrogens stick together and react in an instant. The temperature inside the furnace rises again and hydrogen is accelerated further in the plasma state.

The hydrogen atoms and molecular ions in the partial plasma state are activated and accelerated in the excited state, and the coronal discharge of high pressure is applied to the wider cylindrical space by pulses from all four electrodes.

Lightning sparks occur and sparks flash.

Deuterium and tritium are supplied to them along with lightning discharges, which are immediately heated to a plasma state, irradiated with laser light, and brought into an excited chaotic state.

This completes the secondary combustion. [7000 degrees]

The heated gas forms a long cylinder, and a cylindrical coil is wrapped around the inner wall of the furnace to let the electromagnetic field flow out, and the magnetron emits electromagnetic waves. And sparks are generated by the corona discharge and sparks are sparkling.

The deuterium and tritium supplied in the two-stage combustion are disordered together in an accelerated space with only excess hydrogen with little oxygen.

Occasionally, the oxygen that appears in the hydrogen quickly flocks to become a mess. Surplus hydrogen, deuterium, and tritium rebound from each other in search of oxygen like crazy

Again, a more powerful corona discharge is applied, gradually supplying free radicals accelerated in the plasma state.

Pulses from laser guns and reflectors in all four sides of the cylindrical space interfere with each other by pulses, causing resonance and plasma turbulence. Rush For oxygen, which is still scarce in number, a large number of hydrogens fight fiercely to combine with each other. The exothermic reaction proceeds and the furnace temperature is overheated, leading to chaos.

Finally, the interference of laser beams causes resonance and neutralizes the repulsion between deuterium and tritium to combine with oxygen, and the corona discharge causes the depletion of high energy deuterium and tritium in the chaotic situation. At the moment when deuterium and tritium are close to each other in order to combine with each other, they cause an order-like resonance in the disorder and momentarily hydrogens lose their polarity and collide with each other in the chaos [see Fig. 1].

The collision began to produce hydrogen fusion, helium and neutrons, and massive energy releases.

The inside of the furnace quickly heats up.

This completes the tertiary combustion. [10000 degrees]

Only a small fraction of the supplied hydrogen is fused, but its divergence energy is so great that the inside of the furnace quickly heats up and heat exchanges in the coolant surrounding the inner wall of the furnace, which is then circulated and transferred to the outside.

Summarizing the three-step process, the ratio of hydrogen and oxygen is initially adjusted to generate excess hydrogen, reacted with the catalyst to induce primary combustion, and the deuterium is accelerated by the electromagnetic field of the coil and the electromagnetic wave of the magnetron. Induces secondary combustion process by accelerating and supplying tritium and tritium, and controls the chaos of surplus hydrogen with the appearance of the last active oxygen by induction of interference and resonance such as corona discharge and laser beam. Thus, the fusion reaction is induced at relatively low and low temperatures.

The fusion is extremely partial, but the emission is enormous, and the temperature in the semi-fusion furnace can be increased by increasing the supply of hydrogen and oxygen, but the control system is operated so that it does not suddenly amplify, and the control technology allows. The reaction temperature is controlled.

The following is a low-temperature semi-nuclear fusion furnace that induces a chaotic [CHAOS] state to perform a fusion reaction by performing a three-stage combustion process [see Fig. 5],

It is centered on a cylindrical combustion furnace shaped like an inverted baseball bat which is widened to naturally induce the processes of primary combustion, secondary combustion and tertiary combustion as the reactor body is heated and ascended.

Triple-walled inner wall [1 + 2 + 3] with a built-in solenoid coil and a baseball bat containing pressurized water,

Heat-exchange system unit that wraps around and circulates coolant

Tubular multi-purpose air chamber that surrounds the inside of the combustion furnace and the outside of the heat exchanger and passes in all directions;

Automatic control system

Electrolysis unit unit obtained by separating the hydrogen and oxygen by electrolysis of water,

A multi-stage nozzle unit for separating hydrogen and oxygen and supplying them to the combustion chamber step by step,

Primary combustion unit to automatically enter the initial ember ignition and catalyst rod,

Discharge tube and secondary combustion unit for supplying deuterium and tritium,

Discharge tube and tertiary combustion unit for supplying active oxygen,

Solenoid magnetic field induction part,

Magnetron electromagnetic wave generator,

Ultra high pressure induction

Corona Discharge Part,

Laser beam irradiation unit,

It consists of a laser resonance induction part.

Nuclear fusion requires more than 100 million degrees of high temperature and a variety of advanced equipment to maintain and control its condition. The main devices of the current development status are under study as large superconducting magnets, large ultra high vacuum containers, cryostat cryogenic containers, ultra high temperature special materials, ultra high temperature plasma counters, vacuum exhaust machines, power supplies and diagnostic devices.

At temperatures as high as 10,000 degrees, control is possible simply by applying the current technology without the use of complex and difficult advanced technologies and equipment as possible in the decades to come.

Of course, the efficiency of semi-nuclear fusion reactors is less than that of the existing [future-completed] nuclear reactors, which are developed and developed by multi-billion dollar research funds.

The temperature of the low-temperature semi-nuclear fusion furnace is only about one millionth of 100 million degrees of existing fusion reactor, and its efficiency is analyzed to be about one thousandth. However, the efficiency is equivalent to 1,000 times higher than that of fossil fuels, and water and heavy water can be obtained as much as it is.The economic efficiency is higher than that of conventional fusion reactors, and 100 times higher than that of fossil fuels. It was shown that the utility value is obtained.

In addition, the low-temperature hydrogen fusion method and the semi-fusion reactor using water and heavy water serve to advance the practical use of nuclear fusion technology, and are suitable as alternative energy to solve the energy depletion problem of the global village. It is expected that it will be a new light for humankind with pollution-free clean energy that frees us from energy.

Claims (2)

Hydrogen fusion reaction requires a high temperature of more than 100 million degrees and a high-tech device, and relates to a low-temperature hydrogen fusion method that induces a chaotic state to partially fusion reaction even at relatively low temperature [2000 ℃ ~ 20000 ℃] [Fig. 1], Initially, the ratio of hydrogen and oxygen is adjusted to generate excess hydrogen, reacted with the catalyst to induce primary combustion, and accelerated by supplying deuterium and tritium while accelerating the plasma with the electromagnetic field of the coil and the electromagnetic waves of the magnetron. Induced secondary combustion process, and by controlling the chaos state of surplus hydrogens with the appearance of the last active oxygen through the induction of resonance and resonance of corona discharge and laser beam, nuclear fusion at relatively low temperature It has a tertiary combustion process that induces a reaction. Thus, the low-temperature hydrogen fusion method characterized in that the three-step combustion process. It relates to a low-temperature semi-nuclear fusion furnace to induce a chaos (CHAOS) state to perform a fusion reaction by performing the three-stage combustion process of claim 1, see FIG. It is centered on a cylindrical combustion furnace shaped like an inverted baseball bat which is widened to naturally induce the processes of primary combustion, secondary combustion and tertiary combustion as the reactor body is heated and ascended. A triple cylinder load capacity [1 + 2 + 3] with a built-in solenoid coil and a baseball bat containing pressurized water, Heat-exchange system unit that wraps around and circulates coolant Tubular multi-purpose air chamber that surrounds the inside of the combustion furnace and the outside of the heat exchanger and passes in all directions; Automatic control system Electrolysis unit unit obtained by separating the hydrogen and oxygen by electrolysis of water, A multi-stage nozzle unit for separating hydrogen and oxygen and supplying them to the combustion chamber step by step, Primary combustion unit to automatically enter the initial ember ignition and catalyst rod, Discharge tube and secondary combustion unit for supplying deuterium and tritium, Discharge tube and tertiary combustion unit for supplying active oxygen, Solenoid magnetic field induction part, Magnetron electromagnetic wave generator, Ultra high pressure induction Corona Discharge Part, A low-temperature semi-fusion reactor comprising a laser beam irradiation unit and a laser resonance induction unit.