JP2013227894A - Various energy conservation cycle union engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve a problem of existing steam turbine power generation in which a steam speed is reduced to 1/10 by damming up the steam speed by having stator blades with totally no power factor by a half, a maximum speed part is 43,000 times volume of water, and a power generation output is almost zero.SOLUTION: A power generation quantity of 1/10 or smaller is improved by damming up a lightweight steam speed+lightweight object power generation by including stator blades with totally no power factor by a half to provide an electricity+liquid air+superheated steam hot heat supply facility 3D for the heat manufacture of sunlight heater of inexpensive electric driving such as a power generation cost of 1/100 such as a fuel cost 0 by aiming at 1355 times the existing power generation quantity with 0 bearing load on a one unit power generation quantity of superposing 100 sets of mercury injection turbines by aiming at Mach 30 as mercury gravity acceleration power generation, for example, in a 30 mmHg vacuum for doubly reversing the whole moving blades by a horizontal shaft 1h gear, a vehicle, a ship, and an aircraft are set in a volume compression power of 21/60,000 of air compression as liquid oxygen compression driving and set in a 1/10 fuel cost and a 10-time speed, the aircraft is aimed at a 1/500,000 space arrival cost so as to enable a day' trip anywhere on the earth, and thus an operational profit for operating the whole manufacturing object becomes preeminently and permanently best in the world.

Description

The present invention is a gravity-type gravity turbine with a significant ratio of vertical rotor blades, which is fitted with six types of annular turbine blade groups on both the inner and outer cylindrical shaft devices that drive Mach 30 mercury with liquid jet velocity + gravitational acceleration in vacuum and ultra high speed circumferential speed. 8Q power generation is reversible permanent magnet 9B + attracting permanent magnet 9C to make bearing load close to 0 + super-high speed peripheral speed, and reverse inversion one after the other by the double reversal magnetic device 85 + horizontal axis 1h magnetized on the outer periphery of the gear, and the vibration reduction head 100 sets of turbines are generated in 828m, the largest unutilized renewable energy of the earth is added to the existing pumped-storage power generation, gravity acceleration during vacuum increase + Mach 3 or higher high speed injection added + turbine number unlimited head drop unlimited limit, for example Mach 28 Mercury injection vacuum acceleration in vacuum, aiming for a power generation of 10,000 times the existing pumped-storage power generation of 100 sets of turbines with a drop of 500 to 828 m, various fuel costs of boilers and nuclear reactors abolished As necessary power generation, gravity turbine 8N power generation electric drive 1 to multistage heat pump 1G and solar heater 21 are used, and solar heating air is compressed to high temperature, and heat recovery is divided and stored in 1 to multistage compression heat recovery unit 2C. 24 to 200MPa superheated steam 50 warm heat + liquid air 28a cold heat, divided into electricity + liquid air cold heat + superheated steam heat supply equipment 3D endless application, for example, ships, vehicles and airplanes are liquid oxygen The compression volume work rate is 21/60000 volume work rate of air compression, the compression pressure of liquid oxygen or water is 20 times easier, the simple gas engine 88a rotational drive, the simple injection engine 88b and the simple Water injection engine 88c combined injection propulsion, ship combined injection promotion speeding natural phenomena 2a Supply nitrogen, oxygen and CO2 to seawater Increase microorganisms and seaweed, Greatly increase human foods such as airplanes and automobiles, aiming to reach space with 1 / 10th CO2 exhaust, 1 / 10th fuel cost and 1 / 500,000 cost, airplanes and ships aiming for 10x speed, combining various energy conservation cycles The present invention relates to a technique of an engine and various energy storage and combination methods.

The most existing car-driven reciprocating engine in the world consumes enormous amount of fuel due to air compression, and the vertical type moving blade ratio critical material gravity turbine 8Q vacuum critical material gravity acceleration power generation of electricity + liquid air cold heat + superheat Supply as steam heat supply equipment 3D, for example, superheated steam is injected into methane hydrate under permafrost land or under the sea, methane and water are divided into methane and liquid nitrogen cooled liquid methane is recovered and liquid oxygen chamber 5K receives liquid oxygen 5K Then, compression of liquid oxygen 5K, compression volume work rate of 21/60000 volume work of air compression, 24-200MPa ultra-high pressure compression injection, liquid oxygen 5K + liquid fuel 1b + high temperature water 52a compression theory to ultra high pressure Fuel is injected and burned in the process of heating at the inner circumference of the combustion chamber 4Q, etc., and injecting each into the theoretical combustion chamber 4Q by heating to an ultra-high temperature or optimum temperature, ultra-high pressure oxygen + ultra-high pressure Super high pressure high temperature high temperature superheated steam 50 is heated by high temperature combustion, and super high pressure oxygen super high pressure fuel flame 3000 ° C or more is intended for pyrolysis and electrolysis of superheated steam. The combustion gas 49 + superheated steam 50 in the chamber 4Q is injected from the high pressure / high temperature combustion gas control valve 5a or the combustion gas injection nozzle 6Y, and the simple gas engine 88a is driven to drive various vehicles such as automobiles and tillers. Drive propeller 7A, rotor blade 7B and screw 7C, drive various vehicles, propeller airplanes and screw ships, and aim for fuel cost 1/10 or 10 times speed by using liquid oxygen 5K for electricity generation electricity generation The present invention relates to the technology of various energy conservation cycle coalescence engines and coalescence methods aiming at the world's best operating profit rate.

  Since existing jets are also blocked by stationary blades, they consume huge amounts of fuel through air compression, so that rotational output and jet propulsion output are reduced, and space flight such as 16 laps of the earth on air resistance 01 is impossible with air compression. As an aim of propulsion of liquid compression simple injection engine 88b combined with space rocket and jet, vertical type moving blade ratio critical material gravity turbine 8Q power generation electric drive many 1 to multi-stage theoretical gas compressor 3T isothermal pump 1G + sun By the light heater 21 heat production, 24 to 200 MPa high-temperature water to superheated steam temperature 50 + liquid air cold heat 28a are divided and stored. As electricity + liquid air cold heat + superheated steam heat supply equipment 3D, the jet propulsion of the plane is liquid oxygen 5K + Received by liquid fuel 1c + high pressure high temperature water 52a, compressed volumetric power is compressed by liquid oxygen compression and compressed by ultra high pressure at 21/60000 volumetric power of air compression, respectively. The fuel heating pipe 1L, water heating pipe 5H, oxygen heating pipe 5F, and the like are not shown in the inner peripheral view of the simple injection engine 88b theoretical combustion chamber 4Q, and the optimum heating temperature is set by the fuel heating valve 25b + oxygen control valve 24D + superheated steam control valve 25. Is opened, and each is injected and burned into a theoretical combustion chamber 4Q aiming at one or more stoichiometric air-fuel ratio ultra high pressure combustion, and oxygen heating nozzle 6L fuel injection nozzle 6X multiple central combustion at 3300 ° C or higher as a target for pyrolysis electrolysis, superheated steam With 50 heat recovery aiming to increase oxygen-hydrogen combustion + rocket combustion combustion gas injection nozzle 6Y injection, aiming to combine the forward air with suction injection, etc., adding 1 to several points suction air flow jet combustion, theoretical combustion chamber 4Q superheated steam Injecting nozzle 6A superheated steam 50 with 200MPa target injection and suction injection of combustion gas 49. With rocket combustion, aiming for space arrival cost of 1 / 500,000. It is possible to make day trips anywhere on the earth, such as making 16 orbits of the earth in a space flight close to zero fuel cost, and aiming at the world's best profit rate with various space return planes. Regarding technology.

  The existing ship consumes a large amount of fuel by air compression, reduces the rotational output and injection propulsion output, and consumes a large amount of fuel for low-speed movement. / 60000 volume work rate is included, the air compressor for liquid air production is also added to the theoretical best gas compressor 3T, and the vertical all-blade ratio critical material gravity turbine 8Q power generation electric drive 1 to multistage theoretical gas As a heat pump 1G compression of the compressor 3T, etc., the solar heater 21 solar heating air is compressed to high temperature, heat production is divided and stored in the 1-multistage compression heat recovery unit 2C, and 24 to 200 MPa high-temperature water 52a to 50 heated superheated steam + liquid air 28a cold and stored as electricity + liquid air cold + superheated steam temperature supply equipment 3D, in the process of receiving liquid oxygen 5K + liquid fuel 1c + hot water 52a Aiming at compression of 200 MPa, the liquid oxygen control valve 5T + liquid fuel control valve 1K + water control valve 5Q (not shown) are opened and heated to the optimum temperature on the inner periphery of the simple water injection engine 88c theoretical combustion chamber 4Q, respectively. 88c and the simple gas engine 88a are respectively driven by water suction injection and rotationally driven to make the water suction injection propulsion of the simple water injection engine 88c and the screw 7C rotational propulsion of the simple gas engine 88a. 1/10 Fuel Cost Aiming for the screw propulsion simple gas engine 88a, the bottom of the ship is exhaust injection propulsion, the natural phenomenon is accelerated in the process of friction reduction injection propulsion, and oxygen, nitrogen, CO2 etc. are supplied into the sea , Phytoplankton, seaweeds, corals, fish, etc. It related to the technology.

  Considering elementary school science without brainwashing, the existing best steam turbine power generation at atmospheric pressure and speed and volumetric capacity kg weight m / second is 1/2 of the gravity gravity turbine 8N power of the vertical type moving blade ratio critical material. In addition, the steam speed is dammed and the stationary vanes with no work are half-damped with the moving blades, the steam speed is approaching 1/100, and the seawater temperature is 7 As the temperature rises, the entire surface of the sea rises, making it impossible for natural phenomena to occur, increasing abnormal weather without an upper limit, and increasing the danger of human beings approaching extinction due to heavy rains of seawater around 50 to 100 years. The green earth is a miracle product and there is a great risk of approaching other stars. According to the explanation of the power station, if the rise in seawater temperature is 7 degrees or less, there is no influence on the environment, but for example, 7 degrees in the sea area where the seawater temperature is 30 degrees If the rise continues, the typhoon wind speed will be 300m / sec, etc., and there will be danger of human beings extinction due to the covering of concentrated rainwater salt in seawater, etc., and the temperature of the whole sea surface will rise and nutrients such as nitrogen, oxygen, CO2 etc The natural phenomenon that has supplied water is made impossible, the number of marine microorganisms, phytoplankton and seagrass is drastically reduced. The number of marine foods such as fish is drastically reduced. If China continues to grow 10%, the rise in seawater temperature will be 10%. The current rate is twice as high as the current rate in 20 years, and the speed of typhoons, seasonal winds and ocean tornadoes is 100m / sec. And forestry and residential areas Such as close to 0, for Japan residents it is difficult before and after 50 years, there is a background necessary technical development that corresponds to the existing technologies worst part before it's too late.

When the atmospheric pressure, the same speed, and the same volumetric power, kg weight m / second, are converted into a mercury-accelerated power generation in a vacuum by using 23,000 times more important material than the existing steam turbine power generation. Power generation is 230 times higher than that of the existing steam turbine power generation, but a huge power generation amount of 23,000 times power generation is expected in 100 pairs at a height of 500m or more, and further mercury gravity acceleration Mach 30 in vacuum is necessary for further experiments Infinite power generation with zero fuel cost generation, vertical type full blade ratio material mercury gravity turbine 8N power generation cylinder inner rotor blade group 60C cylindrical outer rotor blade group 60D, fully automatic machining including cylinder assembly fixed rotor blade group, respectively Easy and easy assembly, 1/10 number of parts, etc., 1/10 parts fully automatic machining 100 sets assembly, aiming for 23000 times power generation, mercury gravitational energy in the earth's largest gravity acceleration acceleration in Mach 30 Driven to the expansion of low-cost electricity applications with zero fuel cost power generation by a large amount of mercury resources, solar heating the air with the solar heater 21, mercury gravity turbine 8N fuel cost zero power generation electric drive 1 Multiple-stage theoretical gas compressor 3T, etc. Compressed multiple times with heat pump 1G, recovered heat multiple times, divided and stored in 24-200MPa high temperature water 52a-superheated steam temperature 50 + liquid air cold 28a, electricity + liquid air cold + superheated steam It is supplied from the hot heat supply facility 3D and received by the liquid oxygen chamber 5K, the storage battery, etc., and the liquid-air combined driving car, airplane or ship is set to 1/10 fuel cost driving or 10 times speed driving for a short time. There are backgrounds such as air-floating ships, storage battery drive and electric drive for extremely inexpensive power generation, and prevention of global warming with little CO2 exhaust.

  In high school and university, the existing engine is described as the best engine, and when we return to elementary school science without brainwashing and think about the best engine, the unit of work is kg weight m / sec. The engine is the best engine in terms of generating rotational output at a high speed, but there is no trace of thought. Therefore, for example, when the vertical turbine-type critical material gravity turbine 8Q power generation is used, there is a background of low fuel cost power generation, and the case of heating a huge methane hydrate sleeping in the sea near Japan or permafrost is considered in elementary school science. And fuel cost 0 heating is the best. Therefore, the fuel cost 0 power generation electric drive solar heater 21 is used, and the heat pump 1G such as the 1-multistage theoretical gas compressor 3T or the 1-multiple stage compression of the air 28a heated by sunlight with the fuel cost 0 power generation electric drive. In the heat recovery unit 2C, the heat is recovered multiple times and heat is recovered multiple times, divided into 5K cold liquid oxygen and 5L liquid nitrogen + hot high temperature water 52a to superheated steam 50, and in the process of infinite use of heat, for example permafrost Injecting superheated steam 50 into underground methane hydrate, splitting it into methane and water, recovering methane with liquid nitrogen cooled liquid methane and continuing the superheated steam injection forever, the methane recovery enclosure has a suitable temperature and lots of water droplets Land grazing, increasing the use of food by humans, and infinite use of heat, aiming to reach 1 / 500,000 in space-driven costs for liquid air-powered cars, ships and spacecrafts, and speeding natural phenomena in the process of ship driving 2a , Fine And the seaweed and coral, etc. to increase the food of fish such as the human race in the growth the food chain, etc., to prevent the heavy rain of sea water there is a background that can put off the human race extinct. Revolution of employment growth that will increase the employment by making the manufacturing operation monopolized 100% worldwide, with the operating profit rate becoming 10 times larger than the existing operational profit ratio, as the ship revolution and airplane revolution aiming at 10 times speed with low fuel cost There is a background that can be.

Japanese Patent No. 1607151, Patent No. 1609617, Patent No. 1645350, Patent No. 1924889, Patent No. 1912522, Patent No. 1959305, Patent No. 1986119, Patent No. 2646636, 1992 U.S. Pat. No. 5,133,305, 1993 U.S. Pat. US Pat. No. 5,429,078, 1997 US Pat. No. 5,701,864, PCT International Application No. PCT / JP97 / 01814, US Pat. No. 6,119,650, Chinese Patent No. 8818, EU British Patent No. 902175, PCT International Application No. PCT / JP97 / 02250 No. 6,263,664.

PCT International Application Publication No. WO 2010/101017 PCT / JP2010 / 052171 etc. have 326 applications from the date of filing of Japanese Patent Application No. 2009-048869 on March 3, 2009 to the date of filing of Japanese Patent Application No. 2010-007805 on January 18, 2010 Since then, there have been 26 applications including PCT until March 16, 2012, the filing date of Japanese Patent Application No. 2012-059542.

  In the existing thermal power plants in the world, the total heat generation is 7 degrees Celsius, and the seawater temperature rise is 1000 times in 100 years, and the downdrafts and updrafts are increased as much as possible. As the number of storms, torrential rains, heat waves, cold waves, etc. increases without limit, typhoons, seasonal winds, tornadoes, etc., around 100 years in the sea near Japan, salt water on the land due to concentrated heavy rains, etc. Covering increases the danger of human land food loss, making it impossible for the natural phenomenon of supplying nutrients to the sea-cooled seabed in winter, dramatically reducing microorganisms, phytoplankton, seaweeds, corals, etc., fish through food chains, etc. The number of human underwater foods has been reduced as much as 1/100, and droughts, torrential rains, typhoons and seasonal winds have increased 10 times in 100 years. For example, typhoons and seasonal winds have an upper limit such as 300m / sec. weather Giant seafloor rock expansion earthquake and tsunami There is a challenge to postpone human extinction. A recent issue is the rapid increase in countries with deficits. The biggest cause is the epidemic that easily makes profits with low labor cost countries as the world's factories, and all the developing countries that can easily make profits compete for the best in imitation improvement like Japan in the past, so cheap and excellent products There is a risk of the destruction of manufacturing facilities in the developed countries and the deficit of jobs in the developed countries, and the destruction of employment.There is an urgent need to increase profit margins in developed countries because the current economic crisis is in the early stages. However, as a top-secret manufacturing operation of the invention that keeps 100% monopoly on the world scale forever, there is a challenge to make the world's most eternal financial surplus with outstanding profitability forever.

Vertically moving blade ratio critical material gravity turbine 8Q fuel cost 0 power generation cheap electric drive all, heat production by solar heater 21 + 1-multistage theoretical gas compressor 3T etc. heat pump 1G + 1-multistage compression heat recovery unit 2C Then, as electricity + liquid air cold heat + high temperature water to superheated steam temperature heat supply facility 3D, the received liquid oxygen 5K is compressed to 21/60000 volumetric compression work rate of air compression, and super high pressure combustion and super high temperature combustion are easy As the theoretical combustion chamber 4Q, the superheated steam 50 is heated so that the stoichiometric air-fuel ratio combustion is possible, and as a rocket combustion, combined with the existing technical improvement invention, a simple gas engine 88a or a simple water injection engine 88c driven by the theoretical combustion chamber 4Q. And simple injection engine 88b, and vehicles such as automobiles, ships and airplanes are driven by rotational force and propulsion driving. Advances and speeds up natural phenomena 2a, supplies oxygen, nitrogen, CO2, etc. into the sea, increases microorganisms, phytoplankton, seaweeds, corals, fish, etc. As a result of making 16 rounds of the earth on a full day of flight, etc., a day trip anywhere on the earth and the aim of CO2 exhausting in the atmosphere are limited, and power generation, ships, airplanes, automobiles, etc. that are 100% globally monopolized and operated in secret As the best in the world for profit margins and the best for new jobs, preventing droughts, torrential rains, typhoons, seasonal winds, heavy rains on seawater, and earthquakes and tsunamis to prevent global warming and postpone human extinction .

Specific gravity material gravity turbine 8N Fuel cost 0 Low cost power generation, the effect of transmitting the horizontal axis 1h double reversal to 100 sets, etc. is very large, all the 100 sets of theoretical best turbine blades 8c of the cylindrical blade group 60C60D The 100-manufacturing effect of automatic production is very large, and the effect of simplifying the structure without the need of a boiler or nuclear reactor is very large. When the turbine 8N power generation is compared with the maximum speed final blade group by the same vacuum water drive, water vapor of 1,700 times volume of water at an atmospheric pressure of 100 ° C. and 760 mmHg is obtained according to Boyle's law at an exhaust temperature of 29 ° C. and a vacuum degree of 30 mmHg. 760mmHg × 1700 = 30mmHg × V2 volume water vapor, V2 = 760/30 × 1700 = water 43,000 times water vapor, 1/100 volume water power generation It will be 430 times the amount of power generation. In other words, vertical all-blade water gravity turbine 8P power generation, which is a group of existing steam turbine maximum speed power blades, is much more advantageous at the power generation stage, and 430 times power generation at 1/100 volume water speed of superheated steam. In addition to increasing the amount, the degree of vacuum increase is far superior, and the use of gravitational acceleration in the vacuum is further increased to 43,000 times the power generation amount calculated by one set of 100 pairs, water injection speed Mach 3 × in vacuum Gravity acceleration = Mach 30 aiming for 30 times power generation target, and mercury injection aiming for 406 times power generation target, but experiments are necessary, but the power generation cost will be greatly reduced to 1/10 etc. to increase the employment of electrical products infinitely effective.

The green earth is a miracle product and has a high risk of approaching other stars. For example, if China continues to grow 10% for 100 years, the temperature rise in the sea near China will exceed 1000 times due to thermal power generation and nuclear power generation. There is a strong possibility that the extinction of mankind will rapidly approach within 100 years, such as the increase in guerrilla heavy rain in Japan is 1000 times the heavy rain in seawater, the current drastic decrease in fish is close to 0, etc. Electric power drive is required. Therefore, the fuel cost is 0. Electricity generated by power generation + liquid air cold heat + high temperature water to superheated steam temperature heat supply equipment 3D receives liquid oxygen 5K, etc., and the compression work rate of combustion oxygen is 21/60000 volumetric compression work of air compression The theoretical combustion chamber 4Q can drive the simple gas engine 88a, the simple water injection engine 88c, and the simple injection engine 88b most efficiently as the increase in the super high pressure superheated steam 50 in the vicinity of the center of the theoretical combustion chamber 4Q. In addition to the effect that the fuel cost can be aimed at 1/10 or 10 times the speed of automobiles, ships, and airplanes, the space arrival cost can be aimed at 1 / 500,000 of existing space rockets, wheels and screws 7C, propeller 7A and rotor blade 7B are driven by a simple gas engine 88a, and a ship, an airplane, an automobile, etc. are driven by a rotational force. The effect of increasing the digestive capacity of medium microorganisms such as CO2 to tens of thousands of times of the forest is great, and phytoplankton, seaweeds, corals, etc. are proliferated, and fish food such as fish is greatly increased in the food chain etc. It prevents desertification, droughts, torrential rains, typhoons, seasonal winds, and earthquake tsunamis, delays the most important human race extinction, and aims to achieve the world's best profit rate.

Airplane drive is a theoretical combustion chamber that receives liquid oxygen + high temperature water from electricity + liquid air cold heat + high temperature water to superheated steam temperature heat supply equipment, which is driven by electric power driven by gravity turbine 8Q power generation with a fuel cost of 0mm type all blades Optimum heating with a high-temperature water heating pipe 5H etc. on the inner periphery of 4Q, the fuel injection nozzle 6X + oxygen injection nozzle 6L is opened, oxygen gas + fuel gas is mixed and ignited near the center, and the inner periphery of the theoretical combustion chamber 4Q The theoretical combustion chamber 4Q that optimally heats the fuel + oxygen + high-temperature water heating pipe 5H and superheats to the super-high-pressure high-temperature superheated steam 50, etc. The simple injection engine 88b is driven and the space arrival cost is aimed at 1 / 500,000 of the existing space rocket, and the effect of aiming at the prime use of space with the same fuel cost 10 times the injection propulsion output. 100 times pressure 10 times calorie injection short time 1000 times injection propulsion output aim, propeller flight, rotor blade flight and injection propulsion aim at low fuel cost in the atmosphere, superheated steam injection speed and combustion gas injection speed Because it is the largest in vacuum, the mass injection of the existing space rocket ground is considered the worst. It has the effect of aiming for a prime use of space where you can make a day trip anywhere on the earth, such as going around the earth 16 times.

Explanatory drawing of 4C4D of horizontal type moving blade ratio critical material gravity turbine 8U (Example 1) Explanatory drawing of 8A9C9B of horizontal type moving blade ratio critical material gravity turbine 8U (Example 2) Explanatory drawing of the solar heater 21 of electricity + liquid cold / heat supply equipment 3D (Example 3) Explanatory drawing of 9B9C9D9E6F6G6H of theoretical gas compressor 3T (Example 4) Explanatory drawing of the simple gas engine 88a (Example 5) Explanatory drawing of the simple water injection engine 88c (Example 6) Explanatory drawing of the simple injection engine 88b (Example 7) Explanatory drawing of simple gas locomotive 7D (Example 8) Explanatory drawing of simple gas engine ship 7E (Example 9) Explanatory drawing of simple gas engine airplane 7F (Example 10) Explanatory drawing of the simple water injection engine ship 7G (Example 11) Explanatory drawing of simple injection engine airplane 7H (Example 12)

  The use of gravity acceleration in vacuum for a long period of time is prevented by brainwashing such as existing steam turbine power generation, and one unit of 100 sets prevents the aim of generating power 43,000 times that of one existing steam turbine power generation, for example, the existing best steam turbine power generation Steam pressure is reduced by reducing the atmospheric pressure, the same speed, and the same volumetric power, kg weight m / second, to 1/1700 of the water power, and by installing the stationary blades alternately with the moving blades and blocking the rotation output to zero. The seawater temperature rises by 7 degrees with all of the driving heat of the sea, the fishes are drastically reduced, the bottom bedrock is expanded into earthquakes and tsunamis, and the typhoon, seasonal winds and sea tornadoes in the sea near Japan are increased to about 100 m / sec. There is a danger that food extinctions and humankind extinction will be approaching rapidly by providing salt coating on the land in around 50 to 100 years, such as heavy rain of suction seawater is expected over the sea. That is, since the invention becomes too large due to many fatal defects of the existing technology, the description of the invention is described in the description of the reference, and the part which has been repeatedly described in the previous application is omitted, and the horizontal axis 1h counter-rotating vertical type whole moving blade Except for the specific material gravity turbine 8Q, we will explain in substitution for three examples, and try to materialize the invention without common sense.

Fig. 1 Gravity acceleration in vacuum + mercury injection speed, Mach 30 drive, etc., aiming to the limit, vertical type moving blade ratio critical material gravity turbine 8Q power generation is proportional to kg weight m / sec. Each shaft device 60B is provided with a repulsive permanent magnet 9B attracting permanent magnet 9C, each bearing is made close to the bearing load by the repulsive force or attracting force, and there are a plurality of ring-type double-sided two-pole magnetisms, so Aiming at an infinite increase in diameter, the specific critical material 2E3E is raised by 500 to 828 m, etc. by the specific critical material raising device 2F, and the specific critical material accelerator 6W is driven by mercury 3E and 2E mixed injection vacuum gravity acceleration acceleration Mach 30 target driving The cylinder inner rotor blade group 60C and the cylinder outer rotor blade group 60D are super-high speed turbine peripheral speed record renewal target, and the vertical type whole blade ratio critical material gravity turret driven 100 pairs etc. one after the other with the horizontal axis 1h gear. 8Q power generation, the inner shaft device 60A and the outer shaft device 60B are each provided with a cylindrical portion to facilitate full automatic processing and assembly, and the moving blade group is fitted to the cylindrical annular assembly 9A. In the manufacturing process, the cylinder inner rotor blade group 60C and the cylinder outer rotor blade group 60D are each made up of six components as shown in FIG. Are fixed to the inlet fixed outer blade 60E + the inlet fixed inner blade 60F + the outer annular blade 60G + the inner annular blade 60H + the outlet fixed outer blade 60J + the outlet fixed inner blade 60K. The six parts are fully automatic casting, fully automatic processing, cemented carbide surface treatment, etc. Gravity acceleration for vacuum acceleration of water as a thrust bearing 80a and bearing 80 including permanent magnets and electromagnets that support weight, making mass production inexpensive and easy to manufacture, such as cylindrical annular assembly 9A, etc. 1g, and the gravity acceleration part 1g joint has a horizontal shaft 1h through hole for driving the generator 1, and the generator 1 is driven plurally outside the turbine outer box 77a, so that the multistage saddle type all blade specific gravity Large material gravity turbine 8Q Rotation direction alternate drive, the next turbine 8N is driven one after another by acceleration of gravity acceleration part 1g, and the horizontal axis 1h is alternately driven to make the electric product infinity and electric drive infinity with simple structure, The world's best energy conservation cycle combined engine power generation and combined method power generation with outstanding profitability.

The vertical type moving blade ratio critical material gravity turbine 8Q power generation consists of 6 parts in one set with two kinds of cylindrical annular assemblies 9A, and 100 to 200 sets such as 100 to 200 sets in the existing highest building 828m in the turbine outer box 77a. The thrust bearings 80a of the inner shaft device 60A and the outer shaft device 60B are provided with bearings 80 to form a counter rotating magnetic device 85 with a horizontal shaft 1h gear, and a cylindrical inner rotor blade group. The 60C cylindrical outer rotor blade group 60D is driven by a double reversal drive that rotates alternately for each turbine, and the vibration and noise are minimized by the turbine drive that cancels the resonance. As a target jet speed, for example, platinum ball 2E mixed injection is performed with mercury 3E pressure, and as the acceleration effect of gravitational acceleration in vacuum is the highest, the cylinder inner rotor blade group 60C is injected into the cylinder outer rotor blade group 60D, respectively. The horizontal axis 1h counter-rotating drive power generation to maintain the target speed of Mach 30 and drive the next turbine to make a vertical full blade ratio critical material gravity turbine 8Q power generation that effectively uses the head, and frictional heat cooling In the air extractor 51, the existing power generation maximum vacuum degree, such as 30 mmHg, is easily used, and 100 to 200 sets are used for a head of 828 m. In comparison with one turbine 8Q Mach 1 power generation in which 100 sets are stacked, 1/1000 volume of mercury is 43 × 100 × 13, 55 = 58265 times the amount of mercury power generation by Mach 1 speed injection, and 91891 for platinum balls Energy saving cycle coalescence engine fuel cost becomes extremely low 0 To power.

  2 of FIG. 2 The most important configuration of the cylindrical inner blade group 60C of the cylindrical inner blade group 60D in the cylindrical annular assembly 9A is that the lowest friction loss is the most important. The inner shaft device 60A and the outer shaft device 60B in FIG. 1 are each provided with a cylindrical annular assembly 9A, and the outer shaft device 60B and the cylindrical annular assembly 9A are fixed to the inlet fixed outer blade 60E in an annular fitting assembly. The inlet rotor blade group of the cylindrical outer rotor blade group 60D is constituted, and the inner shaft device 60A and the cylindrical annular assembly 9A are fixed to the inlet fixed inner blade 60F, and the inlet rotor blade group of the cylindrical inner rotor blade group 60C is fixed. The outer shaft device 60B and the cylindrical annular assembly 9A are configured by an outer annular blade 60G annular fitting assembly to form an intermediate blade group of the cylindrical outer blade group 60D, and the inner shaft device 60A and the cylindrical annular assembly 9A are disposed on the inner side. With annular wing 60H annular fitting assembly, The intermediate rotor blade group of the cylinder inner rotor blade group 60C is constituted, and the outer shaft device 60B and the cylindrical annular assembly 9A are annularly fitted to the outer annular blade 60G, and the second intermediate rotor blade group of the cylindrical outer rotor blade group 60D. The inner shaft device 60A and the cylindrical annular assembly 9A are configured by fixing the outlet fixed inner blade 60K in an annular fitting assembly to form the outlet blade group of the cylindrical inner blade group 60C, and the outer shaft device 60B and the cylindrical annular assembly 9A. Outlet fixed outer blade 60J annularly assembled and fixed to form the outer rotor blade group of the cylindrical outer blade group 60D, and each of the six types of cylindrical rotor blade groups 60 is manufactured by fully automatic processing, etc. As a result, the manufacturing cost is extremely low due to the simplicity of the structure, no boilers, no reactors, etc., making it the world's best operating profit rate with no comparison of fuel costs, etc. To cheap power generation.

Heat production of the solar heater 21 in FIG. 3 is a vertical all-blade ratio critical material gravity turbine 8Q fuel cost 0 power generation Extremely inexpensive electric drive, inexpensive electricity + liquid air cold heat + superheated steam temperature supply equipment 3D The solar heater 21 has a buoyancy on the surface of the water or a circular railroad on a flat surface, and the solar heater 21 is used as a surface device or a land device for rotating and controlling sunlight at right angles from east to west. Is provided with a rotation support part 4f and provided with a gear unit 4d and a roller 4e, and as a cylindrical rotation part 77G, the vertical rotation maintaining rotation is controlled at right angles in the vertical direction, and the east-west vertical rotation control is performed by using buoyancy and circular railway. The solar light is controlled to maintain the right angle in two directions and the air temperature in the heat absorption tube 4H is maximized, and the solar light with the maximum amount of the earth is collected in a straight line by the rectangular long lens 2d, and is near the focal length. Heat absorption tube 4H The internal air passage 28A air 28a temperature is maximized, the external air passage 28A air 28a temperature is also increased, and the existing lens cross section is linearly extended as a rectangular long lens 2d. A heat insulating material 2c such as a cylinder is surrounded by a cylindrical rotating portion 77G or the like to form a long cylinder such as a cylinder, a long long lens 2d is a joint 80A + fastener 80B, and a sealed upper portion is a 4H external air passage 28A. Intake and compression as 1 to multiple stage heat pump 1G for suction, theoretical gas compressor 3T and the like as heat pump 1G are set to 800 to 1200 ° C multiple times, and heat recovery is repeatedly performed at 1 to multiple stage compression heat recovery unit 2C. Then, the liquid air 28a cold heat is stored in the liquid oxygen chamber 5K + liquid nitrogen chamber 5L, and the 24-heat of about 200-400 MPa superheated steam is divided and stored in the high-pressure high-temperature steam chamber 5N. Electrical + liquid air cold + using various applications in the superheated steam heat supply facilities 3D, the electric drive flourish and battery driven prime, to various thermal utilization prime and various cold use PRIME electrical product.

The theoretical gas compressor 3T of FIG. 4 is equipped with a repulsive permanent magnet 9B attracting permanent magnet 9C compressed air part 9D vacuum part 9E water injection part 6F aiming at super-large size, ultra-high speed rotation, and compression ratio greatly increased, and uses magnetic force + air pressure. With a bearing load approaching zero or using heat of vaporization, the compression ratio of one unit is greatly increased, and Boyle's law gas volume is inversely proportional to the pressure. The best aim is to compress the suction from the large circumferential blade to the central short blade. As a result, the maximum intake air amount is aimed at, and the intake air velocity is aimed at the maximum at the upper compression blade group 8g and the lower compression blade group 8h of all the rotor blades, and the assembly compression blade group 8j facilitates assembly and suction. Mouth area maximum ease and compression efficiency best aiming, vertical type moving blade ratio critical material gravity turbine 8Q fuel cost 0 power generation extremely cheap electric drive, double reversal magnetic (gear) device 85 (85Y) of horizontal axis 1h gear The upper compression blade group 8g The side compression blade group 8h is rotated in the opposite direction to rotate in the opposite direction, the relative peripheral speed is 3 to 10 times that of the existing axial flow compressor, the theoretical gas compressor 3T is the best theoretical gas compressor 3T, and the final compression blade 6 stationary blade 6G The heat production is to press fit into the compressed air heat exchanger 2Y, and the heating air of the solar heater 2 is mainly compressed with a heat pump 1G such as the theoretical gas compressor 3T, and 1 to a plurality of stages of compression heat for each compression high temperature. Heat is recovered by the recovery unit 2C, divided and stored as liquid air cold heat + superheated steam temperature heat, and used as a supply facility 3D for electricity + liquid air cold heat + hot water to superheated steam temperature heat. For use in infinite heating applications such as greenhouse cultivation, inexpensive liquid oxygen is used for driving automobiles, ships and airplanes with a compression work rate of 21/60000 of air compression, and inexpensive liquid nitrogen is used for infinite use for cooling such as ice production, Various uses You use.

The simple gas engine 88a in FIG. 5 is a combination of the drive of the improved invention engine of the existing gas turbine and the drive with no fuel cost power generation electric product drive. Low-priced electrical manufacturing, electricity + liquid air cooling + high-temperature water to superheated steam temperature supply facility 3D receives the liquid oxygen + electricity + high-temperature water from the 3D theoretical combustion chamber 4Q driven by low-cost electrical products, compresses liquid oxygen By doing so, the compression volume work rate is set to 21/60000 volume compression work rate of air compression, liquid oxygen + liquid fuel + high temperature water is compressed and heated to an ultrahigh pressure such as 24 to 200 MPa, and the multiple inlet on-off valve 1Q is closed. Two types of rocket combustion in the theoretical combustion chamber 4Q, oxygen + fuel injection combustion heated to the optimum temperature from the oxygen injection nozzle 6L + fuel injection nozzle 6X, fuel + oxygen + superheated steam 50 on the inner wall of the theoretical combustion chamber 4Q Heating to the appropriate temperature Theoretical air-fuel ratio combustion, aiming at 10 times the pressure 10 times the combustion amount of the existing technology improved theoretical combustion chamber 4Q high pressure high temperature combustion gas 5M, the existing technology improved theory combustion chamber 4Q is the theory of 4 times the fuel of the existing technology As the air-fuel ratio combustion amount, the superheated steam 50 of 200 MPa or the like with an increased heat amount is injected from the production superheated steam injection nozzle 6A, and the high-pressure high-temperature combustion gas 5M of four times the combustion amount is sucked and injected by rocket injection, approaching the existing gas turbine The simple gas engine 88a is a simple gas engine 88a that uses a combination of a plurality of liquid oxygen drive theoretical combustion chambers 4Q having a compression work rate of 21/60000 volumetric compression work of air compression and uses even zero liquid oxygen.

The simple water injection engine 88c in FIG. 6 combines the drive of the improved invention engine of the existing jet engine and the drive with no fuel cost power generation electric product, and the vertical all blade ratio material gravity turbine 8Q fuel cost 0 power generation extreme Low-cost electric manufacturing, from the electric + liquid air cold heat + high temperature water to superheated steam temperature supply equipment 3D, the liquid combustion oxygen + electricity + high temperature water is supplied to the theoretical combustion chamber 4Q, etc. driven by low-cost electric products, and liquid oxygen is supplied By compressing, the compression volume work rate is set to 21/60000 volume compression work rate of air compression, and liquid oxygen + liquid fuel + high temperature water is compressed and heated to an ultrahigh pressure such as 24 to 200 MPa, and the multiple inlet / outlet on-off valve 1Q In the rocket combustion theoretical combustion chamber 4Q with two types closed, oxygen + fuel injection combustion heated to the optimum temperature from the oxygen injection nozzle 6L + fuel injection nozzle 6X, fuel + oxygen + superheat on the inner wall of the theoretical combustion chamber 4Q The air 50 is heated to the optimum temperature and the theoretical air-fuel ratio combustion is performed, and the existing technology improved theoretical combustion chamber 4Q high-pressure high-temperature combustion gas 5M is aimed at 10 times the pressure 10 times the combustion amount, and the superheated steam injection of the theoretical combustion chamber 4Q peripheral air 28a suction flow From the nozzle 6A + combustion gas injection nozzle 6Y, superheated steam 50 and high-pressure high-temperature combustion gas 5M approaching 200 MPa are injected, air 28a is sucked and injected, and water is sucked and injected. As a theoretical air-fuel ratio combustion amount of four times the fuel, the superheated steam 50 is aimed at 200 MPa with an increased amount of heat. The high-pressure high-temperature combustion gas 5M produces rotational output, and the superheated steam 50 is injected from the superheated steam injection nozzle 6A with the suction flow of the outer air 28a. As a simple water injection engine 88c close to the existing jet engine, the front air 28a is sucked and injected to suck water 52a. The rate of addition 21/60000 volume compression work rate of the air compressor, the liquid oxygen driving theory combustion chamber 4Q plurality of coalesced, and simple water injection engine 88c used any liquid oxygen 0.

The simple injection engine 88b shown in FIG. 7 combines the drive of the improved invention engine of the existing jet engine and the drive of the electric product with zero fuel cost. Low-priced electrical manufacturing, electricity + liquid air cooling + high-temperature water to superheated steam temperature supply facility 3D receives the liquid oxygen + electricity + high-temperature water from the 3D theoretical combustion chamber 4Q driven by low-cost electrical products, compresses liquid oxygen As a result, the compression volume work rate is set to 21/60000 volume compression work rate of air compression, liquid oxygen + liquid fuel + high temperature water is compressed and heated to an ultrahigh pressure such as 24 to 200 MPa, and the on-off valve 1Q at the plurality of inlets and outlets is set. Two types of closed rocket combustion theoretical combustion chamber 4Q, oxygen + fuel injection combustion heated to optimal temperature from oxygen injection nozzle 6L + fuel injection nozzle 6X, fuel + oxygen + superheated steam on the inner wall of theoretical combustion chamber 4Q 50 is heated to the optimum temperature and the theoretical air-fuel ratio combustion is performed, and the existing technology improved theoretical combustion chamber 4Q high pressure high temperature combustion gas 5M is aimed at 10 times the pressure 10 times combustion amount, superheated steam injection nozzle 6A + combustion gas injection around the theoretical combustion chamber 4Q From the nozzle 6Y, superheated steam 50 and high-pressure high-temperature combustion gas 5M approaching 200 MPa are injected, and when the on-off valve 1Q is closed, the high-power rocket combustion space utilization is primed. The theoretical combustion chamber 4Q is a liquid oxygen-driven rocket combustion chamber and jet combustion chamber, and the existing technology improved theoretical combustion chamber 4Q is a superheated steam aimed at 200MPa with an increased heat amount as the theoretical air-fuel ratio combustion amount of four times the fuel of the existing technology. 50 is produced with a high-pressure high-temperature combustion gas 5M, and the superheated steam 50 is injected from the superheated steam injection nozzle 6A of the suction flow of the peripheral air 28a. Of the air 28a sucks injection, as a simple injection engine 88b that close the existing jet engines, and liquid oxygen driving theory combustion chamber 4Q plurality of coalesced, and easy injection engine 88b used any liquid oxygen 0.

The simple gas engine vehicle 7D in FIG. 8 is a combination of the drive of the improved invention engine of the existing micro gas turbine vehicle and the drive of the electric power generation with zero fuel cost. Power generation from electricity + liquid air cold heat + high temperature water to superheated steam temperature heat supply equipment 3D, which is extremely low power generation, receives liquid oxygen + electricity + high temperature water to the theoretical combustion chamber 4Q, etc. driven by low cost electric products, and liquid By compressing oxygen, the compression volume work rate is set to 21/60000 volume compression work rate of air compression, and liquid oxygen + liquid fuel + high temperature water is compressed and heated to ultrahigh pressure such as 24 to 200 MPa, and a multiple inlet on-off valve 1Q closed rocket combustion theoretical combustion chamber 4Q, oxygen + fuel injection combustion heated to the optimal temperature from oxygen injection nozzle 6L + fuel injection nozzle 6X, fuel + oxygen + superheat on the inner wall of theoretical combustion chamber 4Q The air 50 is heated to the optimum temperature and the air / fuel ratio is combusted at the optimum temperature, aiming at 10 times the combustion amount of the high-pressure high-temperature combustion gas 4M of the existing technological improvement 4Q, and 4 times higher than that of the existing technology. As the theoretical air-fuel ratio combustion amount of fuel, superheated steam 50 with an increased heat quantity of 200 MPa or the like is injected from the manufactured superheated steam injection nozzle 6A, and suction injection of high pressure and high temperature combustion gas 5M aimed at 4 times combustion amount or 40 times combustion by rocket injection. As a simple gas engine 88a close to an existing micro gas turbine, the generator 1 is driven and the storage battery 1A is driven by the storage battery drive wheel 4J. The liquid oxygen drive theoretical combustion chamber 4Q is combined into a plurality of units and used even with liquid oxygen 0. The simple gas locomotive car 7D.

The simple gas engine ship 7E in FIG. 9 combines the drive of the improved invention engine of the existing gas turbine ship and the drive with no fuel cost power generation electric product drive. Liquid oxygen + electricity + high temperature water is supplied to the theoretical combustion chamber 4Q, etc. driven by an inexpensive electric product from the electricity + liquid air cold heat + hot water to superheated steam temperature heat supply facility 3D, which is extremely inexpensive electric manufacture, and liquid oxygen Is compressed to 21/60000 volumetric compression work rate of air compression, liquid oxygen + liquid fuel + high temperature water is compressed and heated to ultrahigh pressure such as 24 to 200 MPa, and a multiple inlet on-off valve 1Q In the rocket combustion theoretical combustion chamber 4Q closed with oxygen + fuel injection combustion heated to an optimal temperature from the oxygen injection nozzle 6L + fuel injection nozzle 6X, and the fuel + oxygen + superheated steam 50 is made the most on the inner wall of the theoretical combustion chamber 4Q. The temperature is heated to the theoretical air-fuel ratio combustion, aiming at a 10-fold pressure 10-fold combustion amount of the existing technology improved theoretical combustion chamber 4Q high-pressure high-temperature combustion gas 5M, the existing technology improved theoretical combustion chamber 4Q in the theoretical sky of 4 times the fuel of the existing technology As the fuel ratio, the superheated steam 50 with an increased heat quantity of 200 MPa or the like is injected from the production superheated steam injection nozzle 6A, and the high-pressure and high-temperature combustion gas 5M aimed at the 4-times combustion amount or 40-times combustion is sucked and injected by the rocket injection. As a simple gas engine ship 7E close to a turbine ship, the screw 7C drive exhaust is injected to the bottom of the head with the rotation output of the simple gas engine 88a, so that the frictional loss can be reduced to 10 times as fast as the lowest friction loss. Liquid oxygen driven theoretical combustion chamber 4Q combined with a plurality of liquid oxygen driven theoretical combustion chambers to save fuel oxygen by reducing friction loss extremely and using even liquid oxygen 0 And simple gas engine ship 7E that.

The simple gas engine airplane 7F in FIG. 10 combines the drive of the improved invention engine of the existing jet and the fuel cost 0 power generation electric product drive. Low-priced electrical manufacturing, electricity + liquid air cooling + high-temperature water to superheated steam temperature supply facility 3D receives the liquid oxygen + electricity + high-temperature water from the 3D theoretical combustion chamber 4Q driven by low-cost electrical products, compresses liquid oxygen By doing so, the compression volume work rate is set to 21/60000 volume compression work rate of air compression, liquid oxygen + liquid fuel + high temperature water is compressed and heated to an ultrahigh pressure such as 24 to 200 MPa, and the multiple inlet on-off valve 1Q is closed. In the rocket combustion theoretical combustion chamber 4Q, oxygen + fuel injection combustion heated to the optimum temperature from the oxygen injection nozzle 6L + fuel injection nozzle 6X, and optimal fuel + oxygen + superheated steam 50 on the inner wall of the theoretical combustion chamber 4Q Heated theoretical air-fuel ratio combustion every time, aiming at 10 times pressure 10 times combustion amount of 5M high pressure high temperature combustion gas 4Q in existing technology improved theoretical combustion chamber 4Q in the existing technology improved theoretical combustion chamber 4Q As the fuel ratio, the superheated steam 50 having an increased heat quantity of 200 MPa or the like is injected from the production superheated steam injection nozzle 6A, and the high-pressure and high-temperature combustion gas 5M is sucked and injected by the exhaust injection or the rocket injection for the purpose of 4 times combustion amount or 40 times combustion. As a simple gas engine airplane 7F approaching an existing jet aircraft, the propeller 7A drive exhaust is injected backward with the rotational output of the simple gas engine 88a, and the rocket combustion + jet combustion capable of 10 times output etc. is made into the liquid oxygen drive theory As a combination of the combustion chambers 4Q, a simple gas engine airplane 7F that flies even with a space flight aim and liquid oxygen 0 is used.

The simple injection engine ship 7G in FIG. 11 combines the drive of an improved invention engine of an existing gas turbine ship and the drive of a fuel cost zero power generation electric product. Liquid oxygen + electricity + high temperature water is supplied to the theoretical combustion chamber 4Q, etc. driven by an inexpensive electric product from the electricity + liquid air cold heat + hot water to superheated steam temperature heat supply facility 3D, which is extremely inexpensive electric manufacture, and liquid oxygen The compression volume work rate is made to be 21/60000 volume compression work rate of air compression, and liquid oxygen + liquid fuel + high temperature water is compressed and heated to an ultrahigh pressure such as 24 to 200 MPa to open / close valves with multiple inlets and outlets 1Q is closed in the rocket combustion theoretical combustion chamber 4Q, oxygen + fuel injection heated to the optimum temperature from the oxygen injection nozzle 6L + fuel injection nozzle 6X, and fuel + oxygen + superheated steam 5 on the inner wall of the theoretical combustion chamber 4Q Is heated to the optimum temperature, and the air-fuel ratio is heated to the optimum temperature, and the existing technology is improved. The combustion chamber 4Q is high in the high temperature and high temperature combustion gas 5M. From 6Y, superheated steam 50 and high-pressure, high-temperature combustion gas 5M approaching 200 MPa are injected, and when the on-off valve 1Q is closed, high-power rocket combustion is performed. 4Q multiple rocket combustion chambers and jet combustion chambers driven by liquid oxygen, and the existing technology improved theoretical combustion chamber 4Q produces superheated steam 50 aiming at 200MPa with increased heat quantity as the theoretical air-fuel ratio combustion quantity of 4 times fuel of existing technology Rotational output is generated by the combustion gas 5M, superheated steam 50 is injected from the superheated steam injection nozzle 6A of the suction flow of the peripheral air 28a, and the front air 28a is absorbed. As a simple water injection engine 88c driven near the existing jet engine by jetting and sucking water, the liquid oxygen drive theoretical combustion chamber 4Q is combined with a plurality of planes, and a simple water injection engine that moves at ultra high speed even with zero liquid oxygen It is assumed to be a ship 7G.

The simple injection engine airplane 7H of FIG. 12 combines the drive of the improved invention engine of the existing jet and the fuel cost 0 power generation electric product drive. Low-priced electrical manufacturing, electricity + liquid air cooling + high-temperature water to superheated steam temperature supply facility 3D receives the liquid oxygen + electricity + high-temperature water from the 3D theoretical combustion chamber 4Q driven by low-cost electrical products, compresses liquid oxygen As a result, the compression volume work rate is set to 21/60000 volume compression work rate of air compression, liquid oxygen + liquid fuel + high temperature water is compressed and heated to an ultrahigh pressure such as 24 to 200 MPa, and the on-off valve 1Q at the plurality of inlets and outlets is set. In the closed rocket combustion theoretical combustion chamber 4Q, oxygen + fuel injection heated to an optimum temperature from the oxygen injection nozzle 6L + fuel injection nozzle 6X is combusted, and fuel + oxygen + superheated steam 50 is supplied to the inner wall of the theoretical combustion chamber 4Q. The combustion temperature is set to an appropriate temperature, and the combustion is aimed at the combustion temperature of the theoretical combustion chamber 4Q and the combustion gas injection nozzle 6Y on the outer periphery of the theoretical combustion chamber 4Q. More than 200 MPa, superheated steam 50 and high-pressure high-temperature combustion gas 5M are injected, and when the on-off valve 1Q is closed, the high-power rocket combustion space utilization is primed, and when the on-off valve 1Q is opened, the front air 28a is sucked and injected, The plurality of theoretical combustion chambers 4Q are liquid oxygen-driven rocket combustion chambers and jet combustion chambers. In the existing technology improved theoretical combustion chamber 4Q, as the theoretical air-fuel ratio combustion amount of four times the fuel of the existing technology, the superheated steam 50 is aimed at 200 MPa with an increased heat amount. Production high-pressure high-temperature combustion gas 5M generates rotational output, and the superheated steam 50 is injected from the superheated steam injection nozzle 6A with the suction flow of the peripheral air 28a, and the front air As a simple injection engine 88b drive that sucks and injects 8a and approaches the existing jet engine, the liquid oxygen drive theoretical combustion chamber 4Q is combined with a plurality of 4Q to reach the space cost 1/5 million of the existing technology, and liquid oxygen is 0 in the atmosphere A simple injection engine airplane 7H that drives the propeller 7A by extending the inner shaft device 60A depending on the application is used.

Compared to the existing pumped-storage power generation, the gravity-type gravity turbine 8Q power generation of vertical type moving blades, aiming at a resource price of 0 fuel cost of 0 power generation less than 1/2 of nuclear power generation, water jet processing Since the gravity acceleration in the vacuum is added to the water injection speed Mach 3 or more of the machine, and the work rate is proportional to the speed + proportional to the height, the mercury injection speed Mach 3 or more + gravity acceleration in the vacuum = Mach 30 ultimate speed 100x speed 1/100 mass vertical mercury drive + all-blade horizontal axis 1h counter-rotating drive to maximize the power of gravity acceleration of 9.8m / second in the world, to the world's highest building height of 828m There is a possibility of extremely low-priced power generation with a vertical all-blade specific material gravity turbine 8Q power generation with 200 sets of vertical equipment, one power generation, and the same amount of mercury generated 2710 times that of the existing pumped-storage power generation.

Aiming to reduce the cost of resources, zero fuel costs, and zero power generation to less than half of nuclear power generation, the gravity-type full-blade ratio material gravity turbine 8Q power generation is compared with existing thermal power nuclear steam turbine power generation in the process of comparison with Boyle's law. Assuming that the steam velocity of 1700 times water at 100 ° C. and 760 mmHg becomes 43,000 times water vapor at an exhaust temperature of 29 ° C. and a vacuum pressure of 30 mmHg, and that the steam velocity of the final moving blade group of existing steam turbines is sonic, Since the blade group vapor velocity is 1 / 100th the speed of sound or less and the work rate is the lowest, the comparison will be made with the last blade group having the highest work rate. When the water drive volume is 1/43000 volume 29 ° C water drive of the steam 29 ° C volume, the same power generation amount is obtained by driving the 6-stage front and rear blade groups that are double-reversed for 1 h for all the rotor blades. With 200 units of power generation 200 units connected, the power generation amount is 40,000 times, and mercury-driven power generation amount is 542,000 times. If calculated by elementary school science, there is a possibility of making cheap power generation extremely large astronomical power generation. .

Vertical type moving blade ratio critical material gravity turbine 8Q power generation Extremely inexpensive power generation as an electric product prime, electricity + liquid air cold heat + superheated steam temperature supply facility 3D receives superheated steam, methane under the seabed and permafrost land Injecting enclosures in hydrates to recover methane, converting pasture grazing in permafrost areas, injecting superheated steam in oil sands, oil shales, and old oil collecting areas, and installing them in vaporized recovery liquefaction storage A company may receive superheated steam at low cost for mass production of low-priced foods, etc., and use it for agriculture, industrial use, industrial use, mining, etc.

Vertical type moving blade ratio critical material gravity turbine 8Q power generation Extremely inexpensive power generation, electric product prime as electricity + liquid air cold heat + superheated steam temperature supply equipment 3D receives liquid oxygen 5K, liquid oxygen drive and normal drive The vehicle is a combined vehicle, ship, airplane, etc., and the liquid oxygen 5K is liquid-compressed to make the air volume compression work rate 21/60000 volume compression work rate, and the simple gas engine 88a, simple water injection engine 88c and simple injection Driving the engine 88b, there is a possibility that CO2 emissions and fuel costs will approach 1/10 in an automobile, ships may approach 10 times the speed with the same fuel cost, and an airplane will reduce the space arrival cost to 1 / 500,000. As such, there is a possibility of making a major revolution in the use of cold energy, such as making day trips anywhere on earth as the prime use of space.

0: Various energy storage cycle coalesced engine (various heat energy is compressed and recovered by heat pump as air temperature, divided into liquid air cold heat + superheated steam heat, and gravitational energy is increased storage spray accelerated by acceleration of gravity in vacuum Various energy coalescence engine coalescence means used for conversion to generated power) 0: Various energy storage cycle coalescence engine and coalescence method (various thermal energy is heated by solar heat or geothermal heat, etc., compressed air is recovered by a heat pump as air temperature, liquid air cooling + Divided and stored in superheated steam temperature ・ Used with a heat retaining device when using liquid metal below 500 ℃ ・ Shock energy is set to turbine blades and small-diameter metal balls, and silicon resin coating or fluororesin coating is provided to extend the working time Use / gravity energy is ascended by the ascending device, stored and sprayed, accelerated by gravitational acceleration in vacuum, and converted into energy using generated power Combined engine and various energy combining means) 1: generator, 1A: storage battery, 1B: pressure engine (oxygen pressure gear engine, oxygen pressure reciprocating engine, water pressure gear engine, water pressure reciprocating engine, etc.) 1C: alcohol, 1D: fuel injection pump, 1F: condensate pump, 1G: 1 to multistage heat pump (heat pump with heat energy as air temperature (various air 1K: Liquid fuel control valve, 1L: Fuel heating pipe, 1Q: On-off valve, 1Y: Multistage combustion chamber (Liquid oxygen) And liquid nitrogen are separately compressed 24 to 200 MPa, combustion gas and nitrogen gas are manufactured separately, and 1Y is injected or exhausted by performing steam heating inside and outside the combustion gas injection fuel injection combustion several times) b: Fuel (liquid fuel + liquefiable gas fuel) 1b: Fuel pipe (provided so that the fuel injection temperature becomes the optimum temperature) 1c: Liquid fuel, 1d: Mercury, 1g: Gravity acceleration part, 1h: Horizontal axis ( 2) Sunlight heater (collects sunlight in a straight line with a long lens and heats the hot part forming intake air) 2a: Speeds up the natural phenomenon (in the air) In the case of leftover foods with almost zero change moving to a nearby river, a huge amount of microorganisms that approaches zero overnight will be used to increase food for humans. 2a: Speeding up natural phenomena (In power generation, mixing cold 28a with seawater will speed up natural phenomena) Supplied seawater to the seabed Supplying nutrients such as nitrogen, oxygen and CO2 Increases microorganisms and increases foods such as fish and kombu 2a: Speeding up natural phenomena (in ships, nutrients such as nitrogen, oxygen and CO2 are put into the sea Forests the digestive capacity of the supplied microorganisms Phytoplankton, seaweed, etc. aiming tens of thousands of times increase food for fish such as fish and kombu by increasing food chain, etc. 2b: Water resistance is low (water resistance is high by jetting air + combustion gas + superheated steam to the bottom of the ship) 2c: heat insulating material, 2d: long lens (convex lens cross-section extended into a straight line, aiming at the maximum focal length by using multiple lenses) 2e: water surface, 2g: specific material acceleration direction, 2A: heat resistance Material, 2B: heat absorbing material, 2C: 1 to multiple stage compression heat recovery device (heat energy is air temperature, compression is performed multiple times with heat pump, 2X2Y2Z of 2C, etc. heat recovery is used multiple times in various heat exchangers and the rest is heated 2E: Specific critical substances (including alloys, platinum balls, gold balls, tungsten alloy powder sintered balls, silver balls, copper balls, tin balls, lead balls, zinc balls, aluminum balls, indium, cadmium, etc.) Substances with large specific gravity, such as gallium, thallium, bismuth, etc.) 2E: Specific critical substances (Manufacturing method reduces the impact energy as the diameter decreases. For example, molten steel is injected into the air to produce high-impact pulverization air cooling water cooling, etc. 2E: Specific critical substances (silicon resin coating or silicon resin coating, coated platinum alloy balls, coated gold alloy balls, coated tungsten alloy powder sintered balls, coated silver alloy balls, coated bismuth alloy balls, coated copper alloy balls, coated tin Alloy balls, coated lead alloy balls, coated zinc alloy balls, coated aluminum alloy balls) 2F: Specific critical substance elevating device (Gravity energy is increased and stored) 2H: Chilled seawater mixer (Process of speeding up natural phenomena by mixing cold heat into seawater) 2X: Air heat exchanger (the air is compressed with a heat pump at a high temperature, aiming at an infinite increase in the mass of recovered air and an infinite increase in pressure) 2Y: Compression Air heat exchanger (produces air cold heat + superheated steam heat with high temperature air or combustion gas) 2Z: Specific material heat exchanger (used for temperature control of liquid metal below 500 degrees) 3a: Water repellent plating, 3A: Repellent Water coating, 3D: Electricity + liquid air cooling + superheated steam heating equipment (cooling + heating manufacturing with gravity power generation, supplying liquid oxygen and liquid nitrogen Driving car, ship and airplane or supplying with superheated steam to methane hydrate 3E: Specific critical substances (specific critical substances that are liquid at room temperature, such as mercury and water) 3E: Specific critical substances (low melting temperatures of less than 500 ° C of liquid, stable high temperature) Liquid alloy) 3F: Oxygen pressure reciprocating engine (liquid oxygen, liquid nitrogen, and fuel are used as combustion for injecting combustion of 24-200 MPa, and fuel injection multistage combustion is performed during expansion to drive the multistage oxygen pressure reciprocating engine) G: Theoretical combustion gear engine (liquid oxygen + liquid fuel + water is compressed and heated for injection combustion) 3H: Reciprocating piston, 3J: Theoretical combustion reciprocating engine (liquid oxygen + liquid fuel + water is compressed and heated for injection combustion) 3K: External gear 3L: Multistage combustion chamber, 3M: Steam pressure reciprocating engine (multistage oxygen pressure reciprocating engine drives water and steam in multiple stages to drive the multistage steam pressure reciprocating engine) 3N: Steam pressure gear engine (multistage 3P: Theoretical expansion engine (the gas volume is inversely proportional to the pressure, aiming for the best engine + oxygen-hydrogen hydrogen combustion) 3Q: Theory 3R: Theoretical gas turbine (Theoretical best gas turbine whose gas volume is inversely proportional to the pressure) 3S: Theoretical steam tank -Bin (Theoretical best steam turbine with gas volume inversely proportional to pressure) 3T: Theoretical gas compressor (Theoretical best gas compressor with gas volume inversely proportional to pressure) 3U: Theoretical turbine, 3V: Pump engine (existing various types) 3X: Compressor engine (uses various existing compressors in the engine) 3Y: Counter-rotating engine (engine whose gas volume is inversely proportional to pressure) 3Z: Oxygen pressure gear engine (liquid oxygen and liquid 3a: Water repellent plating, 3b: Water repellent coating, 4F: Combustion. Gas reciprocating engine, 4H: heat absorption tube (long-lens 2d collects sunlight in a straight line on the heat absorption tube, heats the air temperature inside the tube to the maximum, and raises the outside air temperature) 4J: Battery drive wheel, 4K: Theoretical expansion engine vehicle, 4Q: Theoretical combustion chamber (superheated steam 50 is aimed at super high pressure theoretical air-fuel ratio combustion) 4W: Theoretical compression chamber, 4Y: Theoretical combustion chamber (combusted at high temperature in water vapor) 4Z: Combustion gas gear engine, 4X: Turbine blade cross section (enlarged cross-sectional surface area) 4a: Liquid fuel pump, 4b: Liquid oxygen pump, 4c: Water Pump, 4d: Gear device, 4e: Roller, 4f: Rotation support part, 5: Air injection nozzle, 5a: High-pressure high-temperature combustion gas control valve, 5b: Compressed intake air passage, 5d: Combustion flow inner wall, 5e: Ultra-high pressure oxygen 5A: Supply valve, 5B: Cooling fin, 5C: Exhaust chamber, 5D: Exhaust valve, 5E: Supply chamber, 5F: Oxygen heating tube, 5G: Steam heating tube, 5H: High temperature water heating tube, 5K: Liquid Oxygen, 5K : Liquid oxygen chamber, 5L: liquid nitrogen, 5L: liquid nitrogen chamber, 5M: high pressure high temperature combustion gas, 5M: high pressure high temperature combustion gas chamber, 5N: high pressure high temperature steam chamber, 5N: high pressure high temperature steam, 5P: steam control valve, 5Q: Water control valve, 5R: Superheated steam control valve, 5S: Compressed air heating pipe, 5T: Liquid oxygen control valve, 6: Final compression blade, 6A: Superheated steam injection nozzle, 6B: Compressed air injection nozzle, 6C: Combustion Gas water vapor nozzle, 6E: specific material injection nozzle, 6F: water injection nozzle, 6G: stationary blade, 6H: drain pipe, 6L: oxygen injection nozzle, 6W: specific material accelerator (liquid specific material 3E pressure and specific gravity 6X: Fuel injection nozzle, 6X: After burner (combined combustion with the fuel injection cold heat 28a combustion flow 6Y into the suction air flow and the fuel combustion amount increases, and the universe 6Y: Combustion gas injection nozzle (cooling 28a combustion flow) 6Z: Steam injection nozzle, 7A: Propeller, 7B: Rotating blade, 7C: Screw, 8c: Turbine blade (inner and outer rotor blade group respectively on inner and outer shafts) 8d: Upper expansion blade group, 8e: Lower expansion blade group, 8f: Assembly turbine blade group, 8g: Upper compression blade group, 8h: Lower compression blade group, 8j: assembly compression blade group, 8H: vertical type full blade turbine (small large output stage annularly the same diameter approximately the same shape approximately the same length screw assembly 9 full rotation rotating in opposite directions as fixed rotation 8H: Vertical type moving blade turbine (selection of cemented carbide, turbine coated with silicon resin or fluorine resin) 8H: Vertical type moving blade water gravity turbine (Existing steam turbine Is a stationary blade and the damming output is close to 0, so all moving blades are essential, and the work rate is 1 / 360,000 of platinum sphere. 1 to multi-stage heat pump + compression heat recovery with compression heat recovery unit, divided and stored in warm heat + cold heat turbine drive + used for various purposes) 8H: vertical all blade hydrogravity turbine (used as hot drive + cold drive) 8K: Vertical type moving blade water gravity turbine (water gravity turbine in which the rotation direction of the outer shaft device and the inner shaft device is alternated by the horizontal shaft 1h) 8L: Vertical type Blade specific gravity material gravity turbine (Relative material gravity turbine in which the rotation direction of the outer shaft device and the inner shaft device is alternated by the horizontal axis 1h) 8M: Vertical type full blade water gravity turbine (six types of cylindrical turbine blades) Mating assembly + Magnetic bearing load 0 contact 8N: Vertical type full blade ratio material gravity turbine (6 types of cylindrical turbine blade group fitting assembly + magnetic utilization bearing load approach 0) 8R: Horizontal type full blade hydrogravity turbine (cylindrical turbine blade) Group series opposed synchronous rotation + magnetic utilization bearing load close to 0) 8S: Horizontal type full blade ratio material gravity turbine (cylindrical turbine blade group serial opposed synchronous rotation + magnetic utilization bearing load approach 0) 8P: Vertical type all Rotor water gravity turbine (6 types of cylindrical turbine blade group fitting assembly + magnetic bearing load approach 0 + super high speed peripheral speed) 8Q: vertical type full blade ratio material gravity turbine (6 types of cylindrical turbine) Rotor blade grouping assembly + Magnetic bearing load 0 approach + Super high speed peripheral speed) 8T: Horizontal full blade hydrogravity turbine (cylindrical turbine blade group series opposed synchronous rotation + magnetic bearing load 0 approach + super high speed outer periphery) Speed 8U: Horizontal all blade specific material gravity turbine (cylindrical turbine blade group serially synchronized synchronous rotation + magnetic bearing load approach 0 + super high speed outer peripheral speed) 9: Wear resistant annular assembly (specific material flow path including 8c) 9A: Cylindrical ring assembly (wear-resistant cylindrical ring assembly with 6 types of moving blade groups, simple structure, few parts, fully automatic machining, easy assembly, etc. 9A: Cylindrical annular assembly (inlet fixed outer blade 60E + outer annular blade 60G + outlet fixed outer blade 60J is fitted to form a cylindrical outer moving blade group 60D, inlet fixed inner blade 60F + inner annular blade 60H + outlet) 9B: Repulsive permanent magnet, 9C: Suction permanent magnet, 9D: Compressed air portion, 9E: Vacuum portion, 9Q: Vertical parallel plate (jet air) Save ship 10: hull, 10A: cabin, 10b: cockpit, 10c: control room, 10d: cabin, 10e: cargo compartment, 11D: gas cooling room, 16B: vertical axis, 21: Solar heater (mainly used by providing an intake air passage in the heat absorption pipe 4H) 24: Combustion gas control valve, 24A: Compressed air control valve, 24B: Liquid oxygen control valve, 24C: Liquid nitrogen control valve, 24D: Oxygen control valve, 24E: Nitrogen control valve, 25: Superheated steam control valve, 25b: Fuel control valve, 25c: Fuel pipe, 28a: Air, 28a: Cold heat (Compressed air heat by compressing air 28a with a heat pump) 28b: Compressed air heat quantity, 28A: Intake air path, 28B: Air path inlet, 38: Rotating guide, 38a: Flight Body, 38b: flying wing, 38c: flying tail, 38d: vertical wing, 38e: leading edge of the wing, 38g: surface wing, 38h: levitation boat, 38B: air suction jet ship (with 79S79T79Y79Z) 38C: water suction jet ship (Equipped with 79U79X) 38H: theoretical screw ship, 38J: theoretical injection ship, 38T: theoretical injection airplane, 38U: theoretical propeller airplane, 39A: solar thermal gravity airplane, 39B: solar thermal gravity rotating airplane, 39C: solar thermal gravity helicopter, 39D: screw Vessel, 39G: Solar gravity flying vessel, 39H: Oxygen coalescence screw vessel, 39J: Oxygen coalescence injection vessel, 39K: Oxygen coalescence screw injection vessel, 39L: Oxygen coalescence injection aircraft, 39M: Oxygen coalescence propeller aircraft, 39N: Oxygen coalescence propeller Jet plane, 39P: oxygen coalescence Roller plane, 39Q: oxygen coalescence screw ship, 39R: oxygen coalescence injection ship, 39S: oxygen coalescence screw injection ship, 39T: oxygen coalescence injection airplane, 39U: oxygen coalescence propeller airplane, 40A: rudder, 49: combustion gas, 50 : Superheated steam, 50: Superheated steam chamber, 50: Warmth (compressed air 28a is compressed with a heat pump and divided into 50-heated superheated steam + compressed air 28a cold heat) 50A: Steam, 50a: Superheated steam injection pipe 51: Air extractor 51: Combined extractor (extractor for confluence) 51A: Air extraction chamber 52a: Hot water 52a: Deep sea water 52b: Hot water 52d: Thermal (change from 50) 52e : Cold (change from 28a) 55B: Transmission, 60A: Inner shaft device (equipment with turbine blades) 60B: Outer shaft device (turbine blades) Equipment) 60C: Cylindrical inner blade group (Wear resistant cylindrical annular assembly fixed blade group including fully automatic machining easy assembly) 60D: Cylindrical outer blade group (wear resistant cylindrical annular assembly fixed blade group) 60E: Outlet fixed outer wing (inlet wing for annular assembly fixing outer rotor blade group) 60F: Entrance fixed inner wing (inlet wing for annular assembly fixing inner rotor blade group) 60G : Outer annular blade (intermediate blade for annular assembly of outer rotor blade group) 60H: Inner annular blade (intermediate blade for annular assembly of inner rotor blade group) 60J: Outlet fixed outer blade (exit for fixing outer rotor blade group in annular assembly) Blade) 60K: Outlet fixed inner wing (exit wing for annular assembly fixing inner blade group) 76: Gear device (including magnetic friction power transmission device) 77B: Semi-cylindrical outer box, 77F: Injection section outer box, 77G : Cylindrical rotating part, 77a: Turbine outer box, 80: Bearing (including magnetic bearing + air bearing) 80a: Thrust bearing (including magnetic bearing + air bearing) 80A: Joint, 80B: Fastener, 80Y: Liquid air suction water jet (High pressure high temperature combustion gas 5M High pressure high temperature steam chamber 5N Received and injected and burned multiple times at 5M and heated and injected 5N multiple times from the inner and outer peripheries, sucked and injected by air suction and injected) 80Z: Liquid air suction water jet (high pressure and high temperature) Combustion gas 5M High-pressure high-temperature steam chamber 5N is received and fuel-injected and combusted several times in 5M, and 5N is heated and injected several times from the inner and outer peripheries. 84: Counter-rotating magnetic friction device (device that rotates the inner rotor blade group and the outer rotor blade group at the same speed in the opposite direction) 84Y: Counter-rotating Gear system (existing technology 85: Double reversal magnetic device (magnet-utilized gear height is slight to non-contact and reciprocally rotates with the horizontal shaft 1h gear) 85Y: Double reversal gear device (with the existing horizontal shaft 1h gear) 88a: Simple gas engine, 88b: Simple injection engine, 88c: Simple water injection engine, 88A: Oxygen combined air injection unit (rocket injection + jet combustion + combined steam injection, etc.) 88B: Oxygen combination Air injection part (super high pressure rocket combustion + jet combustion + superheated steam injection suction) 88C: theoretical air injection part, 88M: theoretical water injection part, 88K: oxygen coalescence water injection part (rocket combustion + jet combustion + steam injection etc. 88L: Oxygen combined water injection unit (super high pressure rocket combustion + jet combustion + superheated steam injection suction) 95a: combustion gas reservoir, 95b: compressed air reservoir, 95c Superheated steam reservoir, 103: cold heat recovery unit,

Claims (377)

  6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 1-20 sets of power generation electric product drive combined various energy storage cycle combined engine and combined method.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 21 to 40 sets of various energy storage cycle coalescence engine and coalescence method.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 41-60 sets of various electric energy storage cycle coalescence engine and coalescence method for combining electric power generation product drive.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 61-80 sets of power generation electric product drive combined various energy storage cycle combined engine and combined method.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 81 to 100 sets of various energy storage cycle coalescing engines and coalescence methods for coalescence of power generation electric product drive.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 101-120 sets Combined power generation electric product drive Various energy storage cycle coalescence engine and coalescence method.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 121-140 sets of various energy storage cycle coalescence engines and coalescence methods for coalescence of power generation electric product drive.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 141-160 sets Various energy storage cycle coalescence engine and coalescence method for coalescence of power generation electric product drive.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 161-180 sets of various energy storage cycle coalescence engines and coalescence methods for coalescence of power generation electric product drive.   6 types of blades each with wear-resistant super-water-repellent plating (3a), a cylindrical ring assembly (9A), a magnetic bearing load of 0 approach + super-high-speed circumferential speed specific material Gravity turbine (8Q) 181 to 200 sets of power generation electric product drive combined various energy storage cycle combined engine and combined method.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 1-20 power generation electric product drive with high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescence engines and coalescence methods for generating power from 21 to 40 sets of vertical turbine moving blade ratio critical material gravity turbine (8Q) at a high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescing engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 41-60 power generation electric product drive with high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 61-80 power generation electric product drive with high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescing engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 81-100 set power generation electric product drive with high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 101-120 set power generation electric product drive with high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescing engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 121-140 generator electric product drive with high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 141-160 power generation electric product drive with high circumferential speed.   Magnetic wear bearing load 0 approach + super high, each of which is a wear-resistant super water-repellent plating (3a), and which is driven by a specific material (3E) Mach 1-30 with six types of moving blade groups having a cylindrical annular assembly (9A) Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 161-180 power generation electric product drive with high circumferential speed.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical material (9A) and specific material (3E) Mach 1-30, injection inlet fixed outer wing (60E) + outer Annular blade (60G) + Outlet fixed outer blade (60J) fitted to the outside of the cylinder and moving to the outside of the cylinder. Magnetic bearing load approaching 0 + Super high speed peripheral speed ratio material gravity turbine (8Q) 181 ~ Various energy storage cycle coalescing engine and coalescence method for coalescence of 200 sets of power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Combined with energy-saving cycle coalescence engine and coalescence to unite driving power generation electric product driven by the vertical type moving blade ratio critical material gravity turbine (8Q) with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Various energy storage cycle coalescence engines and coalescence methods for generating power to 21-40 sets of saddle type all-blade ratio critical material gravity turbine (8Q) with driving magnetic bearing load approaching 0 + super high speed circumferential speed.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Combined engine and combination of various energy storage cycles to combine driving of a vertical type moving blade ratio critical material gravity turbine (8Q) 41-60 power generation electric product driven with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Coupling engine and coalescence of various energy storage cycles to unite driving of electric power generation product of vertical type moving blade ratio critical material gravity turbine (8Q) 61-80 set with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Combined engine and combination of various energy storage cycles to combine the driving force of the vertical type moving blade ratio critical material gravity turbine (8Q) 81 to 100 power generation electric product drive with a magnetic bearing to drive near 0 load + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Coupling engine and coalescence of various energy storage cycles to unite driving power generation electric product combination of vertical type moving blade ratio critical material gravity turbine (8Q) 101-120 set with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Coupling engine and coalescence of various energy storage cycles to unite driving power generation electric product combination of vertical type moving blade ratio critical material gravity turbine (8Q) 121-140 set with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Coupling engine and coalescence of various energy storage cycles to unite the drive of electric power generation product of vertical type moving blade ratio critical material gravity turbine (8Q) 141-160 set with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Coupling engine and coalescence of various energy storage cycles to unite driving power generation electric product set of vertical type moving blade ratio critical material gravity turbine (8Q) 161-180 set with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Combined engine and combination of various energy storage cycles to combine driving power generation electrical product drive with vertical type moving blade ratio critical material gravity turbine (8Q) 181-200 set with driving magnetic bearing load approaching 0 + super high speed circumferential speed Method.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 1-20 sets of power generation electric product driven with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engines and coalescence methods for generating 21 to 40 sets of saddle-type full blade ratio critical material gravity turbine (8Q) with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 41-60 sets generator electric product drive with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 61-80 power generation electric product drive with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 81 to 100 power generation electric product drive with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 101-120 power generation electric product drive with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 121-140 set power generation electric product drive with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 141-160 set power generation electric product drive with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy storage cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 161-180 set power generation electric product drive with 0 approach + super high speed circumferential speed.   Magnetic bearing load that is driven by counter rotation or generator (1) by horizontal axis (1h) with 6 types of moving blades grouped as cylindrical annular assembly (9A), each of which is wear resistant super water-repellent plating (3a). Various energy conservation cycle coalescence engine and coalescence method for coalescence of vertical type moving blade ratio critical material gravity turbine (8Q) 181 to 200 sets of power generation electric product driven to 0 approach + super high speed circumferential speed.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Reversal drive and generator (1) Driven by magnetic bearing load 0 approach + super high speed peripheral speed specific material gravity turbine (8Q) 1-20 sets generator electric product drive combined Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Inverted drive and generator (1) Driven magnetic bearing load approaching 0 + super high speed circumferential speed of the blade-type all blade ratio critical material gravity turbine (8Q) 21-40 sets of various energy conservation cycle coalescence engine And coalescing method.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Inverted drive and generator (1) Driven by magnetic application bearing load 0 approach + super high speed circumferential speed specific material gravity turbine (8Q) 41-60 sets Combined with power generation electric product drive Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Reversing drive and generator (1) Driven by magnetic utilization bearing load approaching 0 + super high speed peripheral speed specific material gravity turbine (8Q) 61-80 sets combined with power generation electric product drive Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Reversal drive and generator (1) Driven by magnetic utilization bearing load approaching 0 + super high speed circumferential speed speed material ratio gravity material gravity turbine (8Q) 81-100 combination of power generation electric product drive Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Inverted drive and generator (1) Driven by magnetic use bearing load 0 approach + super high speed peripheral speed specific material gravity turbine (8Q) 101-120 sets Combined with generator electric product drive Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Inverted drive and generator (1) Driven by magnetic use bearing load 0 approach + super high speed peripheral speed specific material gravity turbine (8Q) 121-140 combination of generator electric product drive Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Reversing drive and generator (1) driven magnetic utilization bearing load close to 0 + super high speed circumferential speed with a large blade ratio critical material gravity turbine (8Q) 141-160 combination of power generation electric product drive Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Reversing drive and generator (1) driven magnetic utilization bearing load approaching 0 + super high speed circumferential speed speed material ratio gravity turbine (8Q) 161-180 combination of power generation electric product drive Various energy storage cycle coalescence engines and coalescence methods.   A horizontal axis (1h) driven by injection with specific material (3E) Mach 1 to 30 with 6 types of moving blade groups (9A) made of wear-resistant super-water-repellent plating (3a), respectively. Reversal drive and generator (1) Driven by using magnetic bearing load 0 approach + super high speed peripheral speed specific material gravity turbine (8Q) 181 to 200 sets Combined with power generation electric product drive Various energy storage cycle coalescence engines and coalescence methods.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drives and generators (1) Driven by magnetic bearing load 0 approach + super high speed circumferential speed with a large blade ratio critical material gravity turbine (8Q) 1-20 sets of generator electric product drive combined Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drive and generator (1) Driven by magnetic bearing load to drive 0 type + super-high speed circumferential speed of all blade ratio critical material gravity turbine (8Q) 21-40 sets of various energy storage cycle coalescence engine and Merge method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drive and generator (1) Driven by magnetic bearing load 0 approach + super-high speed circumferential speed with all-wheel blade ratio critical material gravity turbine (8Q) 41-60 sets to combine generator electric product drive Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drives and generators (1) Driven magnetic bearing load 0 approach + super-high speed circumferential speed with a large blade ratio critical material gravity turbine (8Q) 61-80 sets Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drives and generators (1) Driven magnetic bearings Loads approaching 0 + Super high speed circumferential speed with a large blade ratio critical material Gravity turbine (8Q) 81-100 Various combinations to combine power generation electric product drive Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drives and generators (1) Driven by magnetic use bearing load 0 approach + super-high speed circumferential speed with a large blade ratio critical material gravity turbine (8Q) 101-120 combination Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drives and generators (1) Driven magnetic bearing load 0 approach + super high speed circumferential speed with a large blade ratio critical material gravity turbine (8Q) 121-140 set Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drive and generator (1) Driven magnetic bearing load to approach 0 + super high speed circumferential speed of a blade-type all-blade ratio critical material gravity turbine (8Q) 141 to 160 sets Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drive and generator (1) Driven magnetic bearing load to approach 0 + super high speed circumferential speed with a large blade ratio critical material gravity turbine (8Q) 161-180 sets Combined power generator drive Energy conservation cycle coalescence engine and coalescence method.   Double reversal on the horizontal axis (1h) driven by Mach 30 aiming at specific material (3E) with 6 kinds of moving blade groups (9A) and wear-resistant super water-repellent plating (3a), respectively. Drives and generators (1) Driven magnetic bearing load 0 approach + super-high speed circumferential speed with a large blade ratio critical material gravity turbine (8Q) 181 to 200 sets Combined with power generation electric product drive Energy conservation cycle coalescence engine and coalescence method.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive 1 to 20 sets of vertical mass moving blade ratio critical material gravity turbine (8Q) with a magnetic reversal bearing load of 0 approaching + super high speed circumferential speed driven by counter rotating on the horizontal axis (1h) and generator (1) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 21-40 sets with a magnetic utilization bearing load 0 approaching + super high speed circumferential speed driven by counter-rotating drive and generator (1) on the horizontal axis (1h) Various energy storage cycle coalescence engines and coalescence methods for generating electricity.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive 41 to 60 sets of vertical full-blade ratio critical material gravity turbines (8Q) with a magnetic bearing load approaching 0 and ultra-high speed circumferential speed driven by counter rotating on the horizontal axis (1h) and generator (1) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 61-80 sets with a magnetic reversal bearing load 0 approach + super high speed circumferential speed driven by counter-rotating drive or generator (1) on the horizontal axis (1h) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 81 to 100 sets with a magnetic reversal bearing load 0 approach + super high speed circumferential speed driven by counter rotating drive or generator (1) on the horizontal axis (1h) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 101-120 pairs with a magnetically applied bearing load 0 approaching + super high speed circumferential speed driven by counter rotating on the horizontal axis (1h) and generator (1) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 121-140 sets with magnetically applied bearing load 0 approaching + super high speed circumferential speed driven by counter rotation on the horizontal axis (1h) and generator (1) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 141-160 sets with a magnetic utilization bearing load 0 approaching + super high speed circumferential speed driven by counter rotating on the horizontal axis (1h) and generator (1) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 161-180 sets with a magnetic reversal bearing load 0 approaching + super high speed circumferential speed driven by counter rotating on the horizontal axis (1h) and generator (1) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6-phase blade assembly (9A) made of wear-resistant super-water-repellent plating (3a), specific-critical material (3E) Mach 30 aiming injection ratio critical material (2E) mixed injection acceleration drive Vertically rotating blade ratio critical material gravity turbine (8Q) 181 to 200 sets with a magnetic reversal bearing load 0 approach + super high speed circumferential speed driven by counter-rotating drive or generator (1) on the horizontal axis (1h) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   6 types of moving blade groups each made of wear-resistant super water-repellent plating (3a), cylindrical material assembly (9A), specific material (3E) Mach 1-30, injection ratio critical material (2E) mixed injection acceleration drive 1 to 20 sets of vertical mass moving blade ratio critical material gravity turbine (8Q) with a magnetic reversal bearing load of 0 approaching + super high speed circumferential speed driven by counter rotating on the horizontal axis (1h) and generator (1) Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 21-40 with double reversal drive on the horizontal axis (1h) to be driven and magnetic bearing load to drive the generator (1) approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for combined power generation.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 41-60 with double reversal drive on the horizontal axis (1h) to drive and magnetically utilized bearing load to drive the generator (1) + close to super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically moving blade ratio critical material gravity turbine (8Q) 61-80 with double reversal drive on the horizontal axis (1h) to drive and magnetism bearing load to drive generator (1) approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 81-100 with double reversal drive on the horizontal axis (1h) to be driven and magnetic utilization bearing load to drive the generator (1) 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 101-120 with double reversal drive on the horizontal axis (1h) to be driven and magnetism bearing load to drive the generator (1) 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 121-140 with a double reversal drive on the horizontal axis (1h) to be driven and a magnetic utilization bearing load to drive the generator (1) 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 141-160 with a double reversal drive on the horizontal axis (1h) to drive and a magnetically utilized bearing load to drive the generator (1) 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 161-180 with a double reversal drive on the horizontal axis (1h) to drive and a magnetically utilized bearing load to drive the generator (1) 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Accelerated mixing injection of critical material (2E) with specific critical material (3E) Mach 1-30 with 6 kinds of moving blade groups made into cylindrical annular assembly (9A), each made of wear-resistant super water-repellent plating (3a) Vertically rotating blade ratio critical material gravity turbine (8Q) 181 to 200 with a horizontal reversal drive (1h) of double reversal drive and generator (1) drive using magnetic bearing load 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engine and coalescence method for coalescence of combined power generation electric product drive.   Inlet blade of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are wear-resistant superhydrophobic plating (3a) by fixing the inlet fixed outer blade (60E) annular fitting assembly. Combined engine of various energy conservation cycles to combine the driving force of the vertical type moving blade ratio critical material gravity turbine (8Q) 1 to 200 sets of power generation electric product with a magnetic bearing load 0 approaching + super high speed circumferential speed constituting the group And coalescing method.   Inlet blade of the cylindrical inner blade group (60C) in which the inner shaft device (60A) and the cylindrical annular assembly (9A) are wear-resistant super water-repellent plating (3a) by fixing the inlet fixed inner blade (60F) annular fitting assembly. Combined engine of various energy conservation cycles to combine the driving force of the vertical type moving blade ratio critical material gravity turbine (8Q) 1 to 200 sets of power generation electric product with a magnetic bearing load 0 approaching + super high speed circumferential speed constituting the group And coalescing method.   The outer intermediate blade group of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are made of an outer annular blade (60G) annular fitting assembly and wear-resistant super-water-repellent plating (3a). Various energy storage cycle coalescing engine that unites 1 to 200 sets of power generation electric product drive of vertical type moving blade ratio critical material gravity turbine (8Q) with magnetic bearing load 0 approaching + super high speed circumferential speed comprising Merge method.   Inner intermediate blade group of cylindrical inner blade group (60C) in which inner shaft device (60A) and cylindrical annular assembly (9A) are wear-resistant super-water-repellent plating (3a) by inner annular blade (60H) annular fitting assembly. Various energy storage cycle coalescing engine that unites 1 to 200 sets of power generation electric product drive of vertical type moving blade ratio critical material gravity turbine (8Q) with magnetic bearing load 0 approaching + super high speed circumferential speed comprising Merge method.   The outer intermediate blade group of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are made of an outer annular blade (60G) annular fitting assembly and wear-resistant super-water-repellent plating (3a). Two or more energy-utilizing cycles that combine magnetically driven bearing load 0 approach + super-high speed circumferential speed with a high-speed circumferential speed and a combination of 1 to 200 sets of power generation electric product drive Merger engine and merger method.   Inner intermediate blade group of cylindrical inner blade group (60C) in which inner shaft device (60A) and cylindrical annular assembly (9A) are wear-resistant super-water-repellent plating (3a) by inner annular blade (60H) annular fitting assembly. Two or more energy-utilizing cycles that combine magnetically driven bearing load 0 approach + super-high speed circumferential speed with a high-speed circumferential speed and a combination of 1 to 200 sets of power generation electric product drive Merger engine and merger method.   Outlet blades of the cylindrical inner blade group (60C) in which the inner shaft device (60A) and the cylindrical annular assembly (9A) are made of an abrasion-fixed superhydrophobic plating (3a) by fixing the outlet fixed inner blade (60K) annular fitting assembly. Combined engine of various energy conservation cycles to combine the driving force of the vertical type moving blade ratio critical material gravity turbine (8Q) 1 to 200 sets of power generation electric product with a magnetic bearing load 0 approaching + super high speed circumferential speed constituting the group And coalescing method.   Outlet blades of the cylindrical outer blade group (60D) in which the outer shaft device (60B) and the cylindrical annular assembly (9A) are wear-resistant super water-repellent plating (3a) by fixing the outlet fixed outer blade (60J) to the annular fitting assembly. Combined engine of various energy conservation cycles to combine the driving force of the vertical type moving blade ratio critical material gravity turbine (8Q) 1 to 200 sets of power generation electric product with a magnetic bearing load 0 approaching + super high speed circumferential speed constituting the group And coalescing method.   The next outer shaft device (60B) + the outer side of the cylinder is driven by connecting the outer shaft device (60B) + the cylindrical outer blade group (60D) made of the wear-resistant super-water-repellent plating (3a) with a horizontal shaft (1h) gear. Rotor blade group (60D) Reversing direction of rotation to minimize resonance and noise. Magnetically utilized bearing load approaching 0 + super high speed peripheral speed ratio material mass turbine (8Q) 1 to 200 sets Various energy storage cycle coalescence engines and coalescence methods for coalescence of generator-electric product drive.   The next outer shaft device (60B) + the outer side of the cylinder is driven by connecting the outer shaft device (60B) + the cylindrical outer blade group (60D) made of the wear-resistant super-water-repellent plating (3a) with a horizontal shaft (1h) gear. Rotor blade group (60D) A vertical all-blade blade with a rotation of the rotating direction opposite to that of the inner shaft device (60A) and a counter-rotating rotation of the rotating blade group (60D). Specific energy gravitational turbine (8Q) 1 to 200 sets of power generation electric product drive combined various energy storage cycle combined engine and combined method.   A vertical-type full-blade ratio critical material gravity turbine (8Q) equipped with a solar heater (21) with buoyancy on the water surface, and using solar heated air with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Compressed by suction multiple times with 1 to multi-stage heat pump (1G) of extremely inexpensive power generation electric drive, heat is recovered with 1 to multi-stage compression heat recovery unit (2C) for each compression, and electricity + liquid air cooling + High-temperature water to superheated steam temperature heat supply facility (3D) Various energy storage cycle coalescing engines and coalescence methods for combining and driving the feed.   A solar heater (21) is provided with buoyancy on the water surface, and a rotation support part (4f) for controlling rotation of the sunlight at right angles from east to west is provided, and the solar heating air is used as a magnetic bearing load. Vertically moving blade ratio critical material gravity turbine (8Q) with 0 approach + super high speed circumferential speed (8Q) Compressed by suction multiple times with 1 to multi-stage heat pump (1G) of extremely inexpensive power generation electric drive, for each compression 1-stage multi-stage compression heat recovery unit (2C) recovers heat, electricity + liquid air cold heat + hot water to superheated steam temperature supply equipment (3D) various energy storage cycle coalescence engine and coalescence drive and coalescence drive Method.   The solar heater (21) is provided with buoyancy on the water surface, and includes a rotation support part (4f) that controls rotation of the sunlight at a right angle from east to west, and includes a gear device (4d) and a roller (4e). ) Is a cylindrical rotating part (77G), which is a device that controls the rotation of sunlight at a right angle in the vertical direction, and has a vertical all-blade ratio critical material with solar heated air approaching a magnetic bearing load of 0 and an ultra-high speed circumferential speed. Gravity turbine (8Q) Extremely inexpensive electricity-driven electric drive, 1 to multi-stage heat pump (1G) compresses suction multiple times, 1 to multi-stage compression heat recovery unit (2C) recovers heat for each compression, + Liquid air cooling / heating + high temperature water to superheated steam temperature supply facility (3D) Various energy storage cycle coalescing engine and coalescence method for feeding and coalescence driving.   The solar heater (21) is provided with buoyancy on the water surface, and includes a rotation support part (4f) that controls rotation of the sunlight at a right angle from east to west, and includes a gear device (4d) and a roller (4e). ) As a cylindrical rotating part (77G), as a device for controlling rotation of the sunlight at a right angle in the vertical direction and as a device for controlling rotation at a right angle in the east-west direction by using buoyancy, the sunlight is linearly irradiated around the center of the heat absorption tube (4H). Vertically moving blade ratio critical material gravity turbine (8Q) with maximum air (28a) temperature, magnetic bearing load approaching 0 + super high speed circumferential speed 1 to multi-stage heat pump of extremely low cost electric power generation electric drive (1G) Compressed multiple times by suction, and heat is recovered by 1 to multi-stage compression heat recovery device (2C) for each compression, electricity + liquid air cold + hot water to superheated steam temperature supply equipment (3D) feed drive Various energy storage systems that are combined with Kuru union organizations and coalescence method.   The solar heater (21) is provided with buoyancy on the water surface, and includes a rotation support part (4f) that controls rotation of the sunlight at a right angle from east to west, and includes a gear device (4d) and a roller (4e). ) As a cylindrical rotating part (77G) as a device for controlling the rotation of sunlight at a right angle in the vertical direction, and as a device for controlling rotation at a right angle in the east-west direction by using buoyancy. The air (28a) temperature is maximized, and the external air (28a) is also heated. Each air passage (28A) is selected as a high temperature selective suction, and the magnetic bearing load is approached + super high speed circumferential speed ratio is significant. Mass gravity turbine (8Q) Extremely inexpensive power generation electric drive, 1 to multi-stage heat pump (1G) compressed by suction multiple times, and for each compression heat recovery by 1 to multi-stage compression heat recovery device (2C), Electricity + liquid air cooling + hot water to overheating Various energy saving cycles combined engine and coalescence process for the combined driving and temperature heat supply facilities (3D) feed drive.   A vertical all-blade ratio critical material gravity turbine (8Q) with a solar heater (21) provided with a circular railroad on a flat ground, and solar heated air with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed. ) Extremely inexpensive electricity-driven electric drive, 1 to multi-stage heat pump (1G) compresses several times with suction, heat is recovered with 1 to multi-stage compression heat recovery unit (2C) for each compression, and electricity + liquid air cooling + High temperature water to superheated steam temperature supply facility (3D) Various energy storage cycle coalescing engine and coalescence method for combining and driving the feed.   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling and rotating the sunlight at a right angle from east to west, and the solar heating air is used as a magnetic bearing. A vertical all-blade ratio critical material gravity turbine (8Q) with a load approaching 0 and an ultra-high speed circumferential speed (8Q) Compressed by suction multiple times with 1 to multi-stage heat pump (1G) of extremely inexpensive power generation electric drive, 1 to multi-stage compression heat recovery unit (2C), and various energy storage cycle coalescence engines that combine electricity + liquid air cold heat + hot water to superheated steam temperature supply equipment (3D) feed drive and coalescence drive, and Merge method.   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling rotation of the sunlight at a right angle from east to west, and a gear device (4d) and a roller ( 4e) As a cylindrical rotating part (77G), a device that controls the rotation of sunlight at a right angle in the vertical direction is used. Mass gravity turbine (8Q) Extremely inexpensive power generation electric drive, 1 to multi-stage heat pump (1G) compressed by suction multiple times, and for each compression heat recovery by 1 to multi-stage compression heat recovery device (2C), Electricity + Liquid air cooling + High temperature water to superheated steam temperature supply facility (3D) Various energy storage cycle coalescence engines and coalescence methods for driving the feed and coalescence.   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling rotation of the sunlight at a right angle from east to west, and a gear device (4d) and a roller ( 4e) is used as a cylindrical rotating part (77G) as a device for controlling and rotating sunlight at a right angle in the vertical direction, and as a device for controlling rotation at a right angle in the east and west direction by using a circular railway, sunlight is linearly centered on the heat absorption tube (4H) Vertically moving blade ratio critical material gravity turbine (8Q) with maximum irradiation internal air (28a) temperature, magnetic utilization bearing load approaching 0 + super high speed circumferential speed 1 to multiple stages of extremely inexpensive power generation electric drive Compressed multiple times with a heat pump (1G), recovered heat with 1 to multi-stage compression heat recovery unit (2C) for each compression, and supplied with electricity + liquid air cold + hot water to superheated steam temperature supply equipment (3D) Various energizers for object driving and combined driving Save cycle combined institutions and coalescence method.   The solar heater (21) is provided with a circular railroad on a flat ground, and includes a rotation support portion (4f) for controlling rotation of the sunlight at a right angle from east to west, and a gear device (4d) and a roller ( 4e) is used as a cylindrical rotating part (77G) as a device for controlling and rotating sunlight at a right angle in the vertical direction, and as a device for controlling rotation at a right angle in the east and west direction by using a circular railway, sunlight is linearly centered on the heat absorption tube (4H). A vertical all-blade with maximum temperature of the internal air (28a) irradiated and the external air (28a) heated to each air passage (28A) as a high-temperature selective suction with a magnetic bearing load approaching 0 and an ultra-high speed circumferential speed Specific gravity material gravity turbine (8Q) Extremely inexpensive power generation electric drive, 1 to multi-stage heat pump (1G) compresses suction multiple times, and each compression recovers heat with 1 to multi-stage compression heat recovery unit (2C) Electricity + liquid air cold + high temperature Various energy saving cycles combined engine and coalescence process for the combined driving and ~ superheated steam heat supply facilities (3D) feed drive.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescing engine and coalescence method for driving to receive liquid oxygen (5K) from 3D).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescing engine and coalescence method for receiving and driving liquid oxygen (5K) superheated steam (50).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods for receiving and driving liquid oxygen (5K) superheated steam (50) to a plurality of theoretical combustion chambers (4Q).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods for receiving and driving liquid oxygen (5K) superheated steam (50) in a plurality of theoretical combustion chambers (4Q).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that drive liquid oxygen (5K) superheated steam (50) to a plurality of theoretical combustion chambers (4Q) by receiving and combining rocket combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods for additionally driving the combined oxygen rocket combustion to the plurality of theoretical combustion chambers (4Q) with liquid oxygen (5K) superheated steam (50).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods for driving liquid oxygen (5K) superheated steam (50) to a plurality of theoretical combustion chambers (4Q) receiving coalescence rocket combustion + jet combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods in which liquid oxygen (5K) superheated steam (50) is rocket-fired in a plurality of theoretical combustion chambers (4Q) and the others are jet-combusted.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods in which liquid oxygen (5K) superheated steam (50) is rocket-fired into a plurality of theoretical combustion chambers (4Q) and the other theoretical combustion chambers (4Q) are jet-combusted.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods in which liquid oxygen (5K) superheated steam (50) is received in a plurality of theoretical combustion chambers (4Q) by rocket combustion and the other theoretical combustion chambers (4Q) are driven by jet combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression Two kinds of theoretical combustion chambers (4Q) Driving a simple gas engine (88a) as an ultra-high pressure fuel combustion and driving an automobile Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two kinds of theoretical combustion chambers (4Q), ultra-high pressure fuel combustion, driving a simple gas engine (88a) and driving various vehicles, and a combination of various energy storage cycle engines .   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, driving simple gas engine (88a) and driving various automobiles with energy conservation cycle And coalescing method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple gas engine (88a) driven generator (1) Various energy storage cycle coalescence engine and coalescence method for storing electric power in the drive battery (1A) and driving the battery drive wheel (4J) rotating simple gas engine vehicle (7D).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, and store it in a simple gas engine (88a) driven generator (1) driven storage battery (1A) as two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving a battery drive wheel (4J) rotating simple gas engine automobile (7D).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water and simple gas engine (88a) driven generator (1) driven storage battery (1A) as 2 types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for storing and driving a storage battery drive wheel (4J) rotating simple gas engine automobile (7D).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple gas engine (88a) driven generator (1) Various energy storage cycle coalescence engines and coalescence methods for driving a simple gas engine vehicle (7D) capable of rotating in storage battery drive wheels (4J) and normal wheels by accumulating in a drive storage battery (1A).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, and store it in a simple gas engine (88a) driven generator (1) driven storage battery (1A) as two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving a simple gas engine vehicle (7D) capable of rotating a storage battery drive wheel (4J) and rotating a normal wheel.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water and simple gas engine (88a) driven generator (1) driven storage battery (1A) as 2 types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving a simple gas engine vehicle (7D) capable of storing and rotating a storage battery drive wheel (4J) and a normal wheel.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) The simple gas engine (88a) is driven as an ultra-high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving automobile (7D).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression 2 types of theoretical combustion chamber (4Q) Ultra-high pressure fuel combustion as simple gas engine (88a) drive and screw (7C ) Various energy storage cycle coalescence engines and coalescence methods for driving a rotating ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low energy liquid oxygen (5K) + electricity, 2 types of theoretical combustion chamber (4Q), ultra high pressure fuel combustion, simple gas engine (88a) driving, screw (7C) rotating ship driving various energy storage cycles Merger engine and merger method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) driving, screw (7C) rotating ship driving various Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and set the compression volume to 21/60000 of air compression (4Q) One or more simple gas engines (88a) are driven as super high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving a screw (7C) multiple rotation ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two kinds of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation ship drive Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation Various energy storage cycle coalescence engines and coalescence methods for driving a ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and set the compression volume to 21/60000 of air compression (4Q) One or more simple gas engines (88a) are driven as super high pressure fuel combustion Various energy storage cycle coalescing engine and coalescence method for driving screw (7C) multi-turn simple gas engine ship (7E).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two kinds of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation simple gas engine Various energy storage cycle coalescence engines and coalescence methods for driving a ship (7E).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation Various energy storage cycle coalescence engine and coalescence method for driving a simple gas engine ship (7E).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) The simple gas engine (88a) is driven as an ultra-high pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods for driving a ship (7E).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression 2 types of theoretical combustion chamber (4Q) Ultra-high pressure fuel combustion as simple gas engine (88a) drive and screw (7C ) Various energy storage cycle coalescence engines and coalescence methods for driving a jet propulsion ship such as a rotary simple water injection engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, driving a simple gas engine (88a) as two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, screw (7C) rotating simple water injection engine (88c) Various energy storage cycle coalescence engine and coalescence method for driving an equal injection propulsion ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, and driving a simple gas engine (88a) as two types of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, screw (7C) rotating simple water injection engine (88c) Various energy storage cycle coalescing engines and coalescence methods for driving an injection propulsion ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and set the compression volume to 21/60000 of air compression (4Q) One or more simple gas engines (88a) are driven as super high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving a propulsion propulsion ship such as a screw (7C) multiple rotation simple water injection engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation simple water injection Various energy storage cycle coalescing engine and coalescence method for driving an injection propulsion ship such as an engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation Various energy storage cycle coalescence engine and coalescence method for driving an injection propulsion ship such as a simple water injection engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and set the compression volume to 21/60000 of air compression (4Q) One or more simple gas engines (88a) are driven as super high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method for driving a propulsion screw injection vessel such as a screw (7C) multiple rotation simple water injection engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation simple water injection Various energy storage cycle coalescence engine and coalescence method for driving an injection propulsion screw injection vessel such as an engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, screw (7C) multiple rotation Simple water injection engine (88c), etc. Injection propulsion screw injection Various energy storage cycle coalescence engine and coalescence method for driving a ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple gas engine (88a) drive as super high pressure fuel combustion and simple water injection Various energy storage cycle coalescence engine and coalescence method for driving an injection propulsion screw injection vessel such as an engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple water injection engine (88c) with multiple ultrahigh pressure fuel combustion injection propulsion Various energy storage cycle coalescence engine and coalescence method for driving an equal injection propulsion ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two types of theoretical combustion chamber (4Q) simple water injection engine (88c) with multiple ultrahigh pressure fuel combustion injection propulsion, etc. Various energy storage to drive the injection propulsion ship Cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, and driving two types of theoretical combustion chambers (4Q) simple water injection engine (88c) with multiple ultra-high pressure fuel combustion injection propulsion, driving a propulsion vessel Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and providing two kinds of theoretical combustion chambers (4Q) air suction passages with a compression volume of 21/60000 of air compression. Various energy storage cycle coalescing engine and coalescence method for driving an injection propulsion ship such as a water injection engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple water injection engine (88c) injection propulsion that receives cheaper liquid oxygen (5K) + electricity and has two kinds of theoretical combustion chambers (4Q) air suction passages and multiple ultra high pressure fuel combustion injection propulsion Various energy storage cycle coalescence engines and coalescence methods for driving a ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple water injection engine (88c) which receives cheaper liquid oxygen (5K) + electricity + hot water and has two kinds of theoretical combustion chambers (4Q) air suction passages and multiple ultrahigh pressure fuel combustion injection propulsion Various energy storage cycle coalescence engine and coalescence method for driving an equal injection propulsion ship.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and providing two kinds of theoretical combustion chambers (4Q) air suction passages with a compression volume of 21/60000 of air compression. Various energy storage cycle coalescing engine and coalescing method for driving a water jet engine (88c) or other injection propelling simple water jet engine ship (7G).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple water injection engine (88c) injection propulsion that receives cheaper liquid oxygen (5K) + electricity and has two kinds of theoretical combustion chambers (4Q) air suction passages and multiple ultra high pressure fuel combustion injection propulsion Various energy storage cycle coalescence engine and coalescence method for driving a simple water injection engine ship (7G).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple water injection engine (88c) which receives cheaper liquid oxygen (5K) + electricity + hot water and has two kinds of theoretical combustion chambers (4Q) air suction passages and multiple ultrahigh pressure fuel combustion injection propulsion Equivalent injection propulsion simple water injection engine ship (7G) various energy storage cycle coalescing engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple water injection engine (88c), etc. with simple liquid injection engine (88c) with multiple theoretical combustion chambers (4Q) receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression Various energy storage cycle coalescence engines and coalescence methods for driving engine ships (7G).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and reduce the compression volume to 21/60000 of air compression (4Q) Simple injection engine (88b) injection with multiple ultra high pressure fuel combustion injection propulsion Various energy conservation cycle coalescence engines and coalescence methods for propulsion airplanes.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low energy liquid oxygen (5K) + electricity is received, two types of theoretical combustion chambers (4Q) multiple ultra high pressure fuel combustion injection propulsion simple injection engine (88b) various types of energy storage cycle combined into an injection propulsion airplane Organization and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two kinds of theoretical combustion chambers (4Q) various energy to make a simple injection engine (88b) injection propulsion airplane with multiple ultra high pressure fuel combustion injection propulsion Storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and providing two kinds of theoretical combustion chambers (4Q) air suction passages with a compression volume of 21/60000 of air compression. Various energy storage cycle coalescence engine and coalescence method for making an injection engine (88b) jet propulsion airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) A simple injection engine (88b) injection propulsion airplane which receives cheaper liquid oxygen (5K) + electricity and has two types of theoretical combustion chambers (4Q) air suction passages and a plurality of ultrahigh pressure fuel combustion injection propulsion Various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple injection engine (88b) injection that receives cheaper liquid oxygen (5K) + electricity + hot water and has two types of theoretical combustion chambers (4Q) air suction passages and multiple ultra-high pressure fuel combustion injection propulsion Various energy conservation cycle coalescence engines and coalescence methods for propulsion airplanes.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and providing two kinds of theoretical combustion chambers (4Q) air suction passages with a compression volume of 21/60000 of air compression. Various energy storage cycle coalescence engine and coalescence method for driving an injection engine (88b) injection propulsion simple injection airplane (7H).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple injection engine (88b) injection propulsion simple injection that receives cheaper liquid oxygen (5K) + electricity and is equipped with two types of theoretical combustion chambers (4Q) air suction passages and multiple ultrahigh pressure fuel combustion injection propulsion Various energy storage cycle coalescence engine and coalescence method driven by an engine airplane (7H).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple injection engine (88b) injection that receives cheaper liquid oxygen (5K) + electricity + hot water and has two types of theoretical combustion chambers (4Q) air suction passages and multiple ultra-high pressure fuel combustion injection propulsion Various energy storage cycle coalescence engine and coalescence method for driving propulsion simple injection engine airplane (7H).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and have a compression volume of 21/60000 of air compression. 7H) Various energy storage cycle coalescence engines and coalescence methods to be driven.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) The simple gas engine (88a) is driven as super high pressure fuel combustion and propeller (7A ) Various energy storage cycle coalescence engines and coalescence methods that drive a rotating airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two types of theoretical combustion chamber (4Q) various energy storage cycles that drive a simple gas engine (88a) and drive a propeller (7A) as an ultra-high pressure fuel combustion Merger engine and merger method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) driving, propeller (7A) rotating airplane driving various Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and set the compression volume to 21/60000 of air compression (4Q) One or more simple gas engines (88a) are driven as super high pressure fuel combustion Propeller (7A) Various energy storage cycle coalescence engine and coalescence method for driving a multi-turn airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two kinds of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, propeller (7A) multiple rotation airplane drive Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, propeller (7A) multiple rotation Various energy storage cycle coalescence engine and coalescence method for driving an airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and set the compression volume to 21/60000 of air compression (4Q) One or more simple gas engines (88a) are driven as super high pressure fuel combustion Various energy storage cycle coalescing engine and coalescence method for driving a propeller (7A) multi-turn simple gas engine airplane (7F).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two kinds of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, propeller (7A) multiple rotation simple gas engine Various energy storage cycle coalescence engine and coalescence method for driving an airplane (7F).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive, propeller (7A) multiple rotation Various energy storage cycle coalescence engine and coalescence method for driving a simple gas engine airplane (7F).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) The simple gas engine (88a) is driven as super high pressure fuel combustion and propeller (7A ) Various energy storage cycle coalescing engine and coalescence method driven by a rotary simple gas engine airplane (7F).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple gas engine (88a) driven rotor blades (7B) Various energy storage cycle coalescence engines and coalescence methods that rotate and drive the aircraft.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two kinds of theoretical combustion chamber (4Q), ultra-high pressure fuel combustion, simple gas engine (88a) driving rotor blade (7B) rotating and various energy storage to drive airplane Cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water than two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple gas engine (88a) driving rotor blade (7B) rotating and airplane driving Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple gas engine (88a) 1 to multiple drive rotors as ultra high pressure fuel combustion (7B) Various energy storage cycle coalescing engines and coalescence methods for driving a plurality of revolutions to drive an airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two types of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) 1 to multiple drive rotor blades (7B) multiple rotation to drive airplane Various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) 1-multiple drive rotor blades (7B) multiple rotations Various energy storage cycle coalescence engines and coalescence methods that drive aircraft.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple gas engine (88a) 1 to multiple drive rotors as ultra high pressure fuel combustion (7B) Various energy storage cycle coalescence engines and coalescence methods for driving the oxygen coalesced rotor blade airplane (39P) by multiple rotations.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, simple gas engine (88a) 1 to multiple drive rotor blades (7B) as two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion and oxygen coalescence Various energy storage cycle coalescence engines and coalescence methods for driving a rotary wing airplane (39P).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, simple gas engine (88a) 1-multiple drive rotor blades (7B) multiple rotations Various energy storage cycle coalescence engines and coalescence methods that drive oxygen coalesced rotorcraft (39P).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Simple gas engine (88a) driven rotor blades (7B) Various energy storage cycle coalescence engines and coalescence methods that rotate and drive oxygen coalesced rotorcraft (39P).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression 2 types of theoretical combustion chamber (4Q) Simple gas engine (88a) drive propeller (7A) rotation as ultra high pressure fuel combustion Simple injection engine (88b) Various energy storage cycle coalescence engine and coalescence method for driving an injection propulsion airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, simple gas engine (88a) drive propeller (7A) rotates as two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple injection engine (88b) injection propulsion Various energy storage cycle coalescence engine and coalescence method for driving an airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, simple gas engine (88a) drive propeller (7A) rotating as two kinds of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple injection engine (88b) ) Various energy storage cycle coalescence engines and coalescence methods for driving jet propulsion airplanes.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) simple gas engine (88a) 1 to multiple drive propellers ( 7A) A simple injection engine (88b) with multiple rotations and various energy storage cycle coalescence engines and a coalescence method for driving an injection propulsion airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, simple gas engine (88a) 1 to multiple drive propeller (7A) as two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple injection engine ( 88b) Various energy storage cycle coalescing engines and coalescence methods for driving jet propulsion airplanes.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, simple gas engine (88a) 1-multiple drive propeller (7A) multiple rotations as 2 types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion Various energy storage cycle coalescing engine and coalescence method for driving an injection engine (88b) jet propulsion airplane.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) simple gas engine (88a) 1 to multiple drive propellers ( 7A) Various energy storage cycle coalescing engine and coalescence method for driving a plurality of rotations and driving a simple injection engine (88b) injection propulsion simple gas engine airplane (7F), etc.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, simple gas engine (88a) 1 to multiple drive propeller (7A) as two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, simple injection engine ( 88b) Various energy storage cycle coalescence engines and coalescence methods for driving an injection propulsion simple gas engine airplane (7F) or the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, simple gas engine (88a) 1-multiple drive propeller (7A) multiple rotations as 2 types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion Various energy storage cycle coalescing engine and coalescence method for driving an injection engine (88b) injection propulsion simple gas engine airplane (7F) and the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and making the compression volume 21/60000 of air compression 2 types of theoretical combustion chamber (4Q) Simple gas engine (88a) drive propeller (7A) rotation as ultra high pressure fuel combustion A simple injection engine (88b), an injection propulsion simple gas engine airplane (7F), etc. to drive various energy storage cycle coalescence engines and a coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), making the compression volume 21/60000 of the air compression, the two types of theoretical combustion chamber (4Q) super high pressure fuel combustion, high pressure high temperature combustion gas (5M) is injected Various energy storage cycle coalescence engine and coalescence method for driving a simple gas engine (88a).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two types of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, high pressure high temperature combustion gas (5M) is injected, various types of driving simple gas engine (88a) Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water to make two types of theoretical combustion chamber (4Q) ultra-high pressure fuel combustion, injecting high-pressure high-temperature combustion gas (5M), simple gas engine (88a) Various energy storage cycle coalescence engines and coalescence methods to be driven.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), making the compression volume 21/60000 of the air compression, the two types of theoretical combustion chamber (4Q) super high pressure fuel combustion, high pressure high temperature combustion gas (5M) is injected Horizontal axis (1h) Double gas reversing simple gas engine (88a) Driven by various energy storage cycle coalescing engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two kinds of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, high pressure high temperature combustion gas (5M) is injected, horizontal axis (1h) is double-reversed Various energy storage cycle coalescence engine and coalescence method for driving a simple gas engine (88a).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two kinds of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, high pressure high temperature combustion gas (5M) injected, horizontal axis (1h) 2 Various energy storage cycle coalescence engine and coalescence method driven by a simple gas engine (88a) that is repeatedly reversed.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), making the compression volume 21/60000 of the air compression, the two types of theoretical combustion chamber (4Q) super high pressure fuel combustion, high pressure high temperature combustion gas (5M) is injected Horizontal axis (1h) Double reversing two sets of simple gas engines (88a) to drive various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, make two kinds of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, inject high pressure high temperature combustion gas (5M), horizontal axis (1h) double inversion 2 Various energy storage cycle coalescence engines and coalescence methods for driving a set of simple gas engines (88a).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two kinds of theoretical combustion chamber (4Q) ultra high pressure fuel combustion, high pressure high temperature combustion gas (5M) injected, horizontal axis (1h) 2 Various energy storage cycle coalescing engine and coalescence method for driving two sets of heavy inversion simple gas engines (88a).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), making the compression volume 21/60000 of the air compression, the two types of theoretical combustion chamber (4Q) super high pressure fuel combustion, high pressure high temperature combustion gas (5M) is injected Horizontal axis (1h) Double reversing two sets of simple gas engines (88a) to drive various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Two types of theoretical combustion chambers (4Q) that receive cheaper liquid oxygen (5K) and make the compression volume 21/60000 of air compression (4Q) Various energy storage cycles that make a simple gas engine (88a) as ultra-high pressure fuel combustion Merger engine and merger method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle merging engines and merging methods that receive cheaper liquid oxygen (5K) + electricity and make a simple gas engine (88a) as two types of theoretical combustion chamber (4Q) ultrahigh pressure fuel combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + high temperature water, two kinds of theoretical combustion chambers (4Q) various energy storage cycle coalescence engines and coalescence methods for simple gas engine (88a) as ultra high pressure fuel combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), 2 types of theoretical combustion chambers (4Q) that make the compression volume 21/60000 of air compression (4Q) A simple gas engine (88a) that makes the maximum speed as ultra-high pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, 2 types of theoretical combustion chamber (4Q) various energy storage cycle coalescence engine and coalescence method to make simple gas engine (88a) to maximum speed as ultra high pressure fuel combustion .   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, two types of theoretical combustion chambers (4Q) various energy storage cycle coalesced engines (88a) for maximum speed as ultra-high pressure fuel combustion And coalescing method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), 2 types of theoretical combustion chambers (4Q) that make the compression volume 21/60000 of air compression (4Q) To a simple gas engine (88a) that makes the maximum driving speed as super high pressure fuel combustion Various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, two types of theoretical combustion chamber (4Q) various energy storage cycle coalescence engine and coalescence to make a simple gas engine (88a) to achieve maximum driving speed as ultra high pressure fuel combustion Method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water and combining various energy storage cycles into a simple gas engine (88a) that achieves maximum driving speed as two types of theoretical combustion chamber (4Q) ultrahigh pressure fuel combustion Organization and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), 2 types of theoretical combustion chambers (4Q) that make the compression volume 21/60000 of air compression (4Q) A simple gas engine (88a) that achieves the maximum speed as ultra-high pressure fuel combustion Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receives cheaper liquid oxygen (5K), compresses liquid together with liquid fuel (1c) and water (52a), and compresses the compressed volume with 2/60000 volume of air compression etc. Various energy storage cycle coalescing engine and coalescence method for a theoretical combustion chamber (4Q).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receives cheaper liquid oxygen (5K) + electricity, compresses liquid together with liquid fuel (1c) and water (52a), and burns with ultra-high pressure compressed fuel injection with a compression volume of 21/60000 volume of air compression, etc. Various energy storage cycle coalescing engines and coalescence methods for two types of theoretical combustion chambers (4Q).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, compressing liquid together with liquid fuel (1c) and water (52a), and compression volume is ultra-high pressure compressed fuel with air compression of 21/60000 volume, etc. Various energy storage cycle coalescing engines and coalescence methods for two types of theoretical combustion chambers (4Q) for injection combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engine which receives cheap liquid oxygen (5K) from liquid, compresses it with liquid fuel (1c) and water (52a), and heats it to the optimum temperature on the inner wall of two kinds of theoretical combustion chambers (4Q) And coalescing method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycles that receive cheaper liquid oxygen (5K) + electricity, compress liquid together with liquid fuel (1c) and water (52a), and heat them to the optimum temperature on the inner wall of the two types of theoretical combustion chamber (4Q) Merger engine and merger method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, liquid compression with liquid fuel (1c) and water (52a), and heating to the optimum temperature on the inner wall of the two types of theoretical combustion chamber (4Q) Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), liquid compression with liquid fuel (1c) and water (52a), and heating oxygen injection nozzle (6L) + to the optimum temperature on the inner wall of two types of theoretical combustion chamber (4Q) + Various energy storage cycle coalescence engines and coalescence methods for opening the fuel injection nozzle (6X) + superheated steam injection nozzle (6A).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receives cheaper liquid oxygen (5K) + electricity, compresses liquid together with liquid fuel (1c) and water (52a), and heats oxygen injection nozzle (6L) to the optimum temperature on the inner wall of two types of theoretical combustion chamber (4Q) ) + Fuel injection nozzle (6X) + superheated steam injection nozzle (6A) various energy storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity + hot water, compress liquid together with liquid fuel (1c) and water (52a), and heat oxygen injection to the optimum temperature on the inner wall of two types of theoretical combustion chamber (4Q) Various energy storage cycle coalescence engines and coalescence methods that open the nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + hot water, compress liquid together with liquid fuel (1c) and water (52a), and heat oxygen injection nozzle (2Q theoretical combustion chamber (4Q) inner wall to the optimum temperature) 6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) and various energy storage cycle coalescing engines and coalescence methods for injecting with open received superheated steam.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and opening the heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature More than 3000 ° C near the center of open oxygen fuel burner Various energy storage cycle coalescing engine and coalescence method to make two kinds of theoretical combustion chambers (4Q) for heating the outer superheated steam (50) by combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, open heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature. Various energy storage cycle coalescing engine and coalescence method to make two kinds of theoretical combustion chambers (4Q) for heating the outer superheated steam (50) by combustion at ℃ or higher.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, open heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature Various energy storage cycle coalescence engine and coalescence method to make two kinds of theoretical combustion chambers (4Q) for heating the peripheral superheated steam (50) by combustion in the vicinity of 3000 ° C or more.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and opening the heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature More than 3000 ° C near the center of open oxygen fuel burner Various energy storage cycle coalescing engines and coalescence methods for heating the peripheral superheated steam (50) by combustion to two types of theoretical combustion chambers (4Q) aiming partly at the center for suction pyrolysis and electrolysis.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, open heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature. Various energy storage cycle coalescence engines and coalescence methods, which are composed of two types of theoretical combustion chambers (4Q) aiming at the heating of the outer peripheral superheated steam (50) by combustion at ℃ or higher and by suction pyrolysis electrolysis in the vicinity of the center.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, open heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature Various energy storage cycle coalescence engines and coalescence methods, which are composed of two types of theoretical combustion chambers (4Q) that aim to heat the peripheral superheated steam (50) by combustion at a temperature of 3000 ° C or more in the vicinity, and to partially attract and pyrolyze and electrolyze near the center.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and opening the heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature More than 3000 ° C near the center of open oxygen fuel burner Various types of energy storage cycle coalescence engine and coalescence method for heating the peripheral superheated steam (50) by combustion and making it into two types of theoretical combustion chambers (4Q) aiming at combustion by suction pyrolysis electrolysis oxygen hydrogen hydrogen increase near the center.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, open heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature. Various types of energy storage cycle coalescence engine and coalescence method for heating the peripheral superheated steam (50) by combustion at ℃ or higher to make two types of theoretical combustion chambers (4Q) aiming at increased combustion by suction pyrolysis electrolysis oxygen hydrogen hydrogen near the center.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, open heated oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature Heating of peripheral superheated steam (50) by combustion in the vicinity of 3000 ° C or more. Participating in various types of energy storage cycle coalescence engine and coalescence method with two types of theoretical combustion chambers (4Q) aiming at suction pyrolysis, electrolysis, oxygen and hydrogen increase combustion near the center .   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + hot water and heating oxygen injection nozzle (6L) + fuel injection nozzle (6X) + superheated steam injection nozzle (6A) to the optimum temperature Various types of energy storage cycle coalescence engines, which are composed of two types of theoretical combustion chambers (4Q) aiming to increase combustion by suction pyrolysis, electrolysis, oxygen, oxygen, hydrogen, and combustion around the center of the peripheral superheated steam (50) including the received superheated steam by combustion at 3000 ° C or higher, and Merge method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low energy liquid oxygen (5K) is received and various energy conservation cycles are made into a simple water injection engine (88c) of high pressure high temperature combustion gas (5M) injection acceleration injection having a plurality of two kinds of theoretical combustion chambers (4Q). Merger engine and merger method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, various energies made into a simple water injection engine (88c) of high-pressure high-temperature combustion gas (5M) injection acceleration injection having a plurality of two kinds of theoretical combustion chambers (4Q) Storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + high-temperature water, and providing a simple water injection engine (88c) for high-speed high-temperature combustion gas (5M) injection acceleration injection having a plurality of two types of theoretical combustion chambers (4Q) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receives cheaper liquid oxygen (5K) and heats the oxygen + fuel + superheated steam on the inner wall (4Q) with the high-pressure and high-temperature combustion gas (5M) that has multiple two types of theoretical combustion chambers (4Q). A simple water injection engine (88c) for use in various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity is received, and high-temperature high-temperature combustion gas (5M) equipped with two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall (optimum temperature) Various energy storage cycle coalescing engine and coalescence method for a simple water injection engine (88c) to be used by heating.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity + hot water is received, high pressure high temperature combustion gas (5M) with multiple two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall A simple water injection engine (88c) that is used after being heated at an optimum temperature for various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receives cheaper liquid oxygen (5K) and heats the oxygen + fuel + superheated steam on the inner wall (4Q) with the high-pressure and high-temperature combustion gas (5M) that has multiple two types of theoretical combustion chambers (4Q). Various energy storage cycle coalescing engine and coalescence method in a simple water injection engine (88c) for two types of theoretical combustion chamber (4Q) combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity is received, and high-temperature high-temperature combustion gas (5M) equipped with two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall (optimum temperature) Various energy storage cycle coalescing engines and coalescence methods that are made into a simple water injection engine (88c) that is heated to make two kinds of theoretical combustion chambers (4Q) combustion, etc.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity + hot water is received, high pressure high temperature combustion gas (5M) with multiple two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall Various energy storage cycle coalescence engines and coalescence methods, which are made into a simple water injection engine (88c) that is heated to an optimal temperature to make two types of theoretical combustion chamber (4Q) combustion or the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + hot water, and (4Q) inner wall oxygen + fuel + receiving hot water with high pressure high temperature combustion gas (5M) equipped with two kinds of theoretical combustion chambers (4Q) Various energy storage cycle coalescing engines and coalescence methods in a simple water injection engine (88c) in which the superheated steam is heated to an optimum temperature to make two kinds of theoretical combustion chambers (4Q) combustion or the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K), heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and burn two types of theoretical combustion chamber (4Q) near the center oxyfuel combustion at 3000 ° C or more multiple combustion Various energy storage cycle coalescing engines and coalescence methods for a simple water injection engine (88c) aimed at superheated steam suction pyrolysis electrolysis.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and heat up two kinds of theoretical combustion chamber (4Q) near the center oxyfuel combustion 3000 ° C or more Various energy storage cycle coalescence engines and coalescence methods which are made into a simple water injection engine (88c) aimed at superheated steam suction pyrolysis electrolysis by combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam heated at the optimum temperature on one kind of inner wall, and two kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 Various energy storage cycle coalescence engines and coalescence methods that are simple water injection engines (88c) aimed at superheated steam suction pyrolysis electrolysis with multiple combustion at ℃ or higher.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K), heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and burn two types of theoretical combustion chamber (4Q) near the center oxyfuel combustion at 3000 ° C or more multiple combustion Various energy storage cycle coalescing engine and coalescence method for a simple water injection engine (88c) aimed at superheated steam suction pyrolysis electrolysis oxygen hydrogen augmentation combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and heat up two kinds of theoretical combustion chamber (4Q) near the center oxyfuel combustion 3000 ° C or more Various energy storage cycle coalescing engine and coalescence method which is a simple water injection engine (88c) aimed at combustion with superheated steam suction pyrolysis electrolysis oxygen hydrogen hydrogen combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam heated at the optimum temperature on one kind of inner wall, and two kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 Various energy storage cycle coalescing engine and coalescence method, which is a simple water injection engine (88c) aimed at superheated steam suction pyrolysis electrolysis oxygen hydrogen hydrogen augmentation combustion with multiple combustion at ℃ or more.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K), heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and burn two types of theoretical combustion chamber (4Q) near the center oxyfuel combustion at 3000 ° C or more multiple combustion Various energy storage cycle coalescence engines and coalescence methods that are a simple water injection engine (88c) that heats and injects superheated steam (50) of a combustion flow inner wall (5d) high-temperature water heating pipe (5H).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and heat up two kinds of theoretical combustion chamber (4Q) near the center oxyfuel combustion 3000 ° C or more Various energy storage cycle coalescence engines and coalescence methods that are a simple water injection engine (88c) that heats and injects superheated steam (50) of a combustion flow inner wall (5d) high-temperature water heating pipe (5H) by combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam heated at the optimum temperature on one kind of inner wall, and two kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 Various energy storage cycle coalescence engines and coalescence methods that are simple water injection engines (88c) that heat and inject superheated steam (50) of combustion flow inner wall (5d) high-temperature water heating pipe (5H) by multiple combustion at a temperature of 0 ° C or higher.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + hot water, and heat oxygen + fuel + superheated steam at the optimum temperature on one kind of inner wall, 2 kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 ° C or more Various energy storage cycle coalescence engines and coalescence methods, which are a simple water injection engine (88c) that heats and injects superheated steam (50) including superheated steam received from a combustion flow inner wall (5d) and high-temperature water heating pipe (5H) by multiple combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) A simple water injection engine (88c) which receives cheaper liquid oxygen (5K) and injects combustion into the air (28a) at the optimum location of the suction injection flow as well as a plurality of theoretical combustion chambers (4Q). Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) A simple water injection engine (88c) which receives cheaper liquid oxygen (5K) + electricity and combusts and injects the air (28a) at the optimum place of the suction injection flow in the same manner as the two kinds of theoretical combustion chambers (4Q). ) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Simple water injection that receives cheaper liquid oxygen (5K) + electricity + hot water, and also injects combustion into the optimal location of air (28a) suction injection flow in the same way with two types of theoretical combustion chambers (4Q) Various energy storage cycle coalescence engines and coalescence methods in an engine (88c).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescing engines and coalescence methods that receive cheaper liquid oxygen (5K) from a simple water injection engine (88c) and forward the air inlet.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle merging engines and merging methods that receive cheaper liquid oxygen (5K) + electricity and make a simple water injection engine (88c) forward in the air inlet.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, simple water injection engine (88c), various energy storage cycle coalescence engine and coalescence method with the air inlet facing forward.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K), make a simple water injection engine (88c), bring the air inlet forward, approach a straight line, and inject maximum bubbles into the ship bottom.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity, making it a simple water injection engine (88c), approaching a straight line with the air inlet facing forward, and various energy storage cycle coalescing engines and coalescence Method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, and combining various energy conservation cycles to make the simple water injection engine (88c) forward the air inlet close to a straight line and inject the bubbles to the bottom of the ship at the maximum Organization and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + hot water, making it a simple water injection engine (88c), bringing the air inlet forward, approaching a straight line, and maximally injecting bubbles into the bottom of the ship, various energy storage cycle coalescence engines, Merge method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) and combining various energy conservation cycles into a simple injection engine (88b) of high-pressure high-temperature combustion gas (5M) injection acceleration injection having a plurality of two types of theoretical combustion chambers (4Q) Organization and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity and saving various energy as a simple injection engine (88b) of high-pressure high-temperature combustion gas (5M) injection acceleration injection having a plurality of two kinds of theoretical combustion chambers (4Q) Cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + high temperature water to make a simple injection engine (88b) of high pressure high temperature combustion gas (5M) injection acceleration injection having a plurality of two kinds of theoretical combustion chambers (4Q). Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receives cheaper liquid oxygen (5K) and heats the oxygen + fuel + superheated steam on the inner wall (4Q) with the high-pressure and high-temperature combustion gas (5M) that has multiple two types of theoretical combustion chambers (4Q). Various energy storage cycle coalescing engines and coalescing methods in a simple injection engine (88b) to be used.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity is received, and high-temperature high-temperature combustion gas (5M) equipped with two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall (optimum temperature) Various energy storage cycle coalescing engine and coalescence method in a simple injection engine (88b) to be used by heating.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity + hot water is received, high pressure high temperature combustion gas (5M) with multiple two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall Various energy storage cycle coalescing engines and coalescence methods, which are made into a simple injection engine (88b) that is used by heating at an optimum temperature.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receives cheaper liquid oxygen (5K) and heats the oxygen + fuel + superheated steam on the inner wall (4Q) with the high-pressure and high-temperature combustion gas (5M) that has multiple two types of theoretical combustion chambers (4Q). Various energy storage cycle coalescing engines and coalescing methods made into a simple injection engine (88b) for making two types of theoretical combustion chambers (4Q) combustion or the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity is received, and high-temperature high-temperature combustion gas (5M) equipped with two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall (optimum temperature) Various energy storage cycle coalescing engines and coalescence methods that are made into a simple injection engine (88b) that is heated to make two types of theoretical combustion chamber (4Q) combustion or the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Low-priced liquid oxygen (5K) + electricity + hot water is received, high pressure high temperature combustion gas (5M) with multiple two types of theoretical combustion chambers (4Q) (4Q) oxygen + fuel + superheated steam on the inner wall Various energy storage cycle coalescing engines and coalescence methods that are made into a simple injection engine (88b) that is heated to an optimal temperature to make two types of theoretical combustion chamber (4Q) combustion or the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + hot water, and (4Q) inner wall oxygen + fuel + receiving hot water with high pressure high temperature combustion gas (5M) equipped with two kinds of theoretical combustion chambers (4Q) Various energy storage cycle coalescing engines and coalescence methods which are made into a simple injection engine (88b) in which superheated steam is heated to an optimum temperature to make two kinds of theoretical combustion chambers (4Q) combustion or the like.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K), heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and burn two types of theoretical combustion chamber (4Q) near the center oxyfuel combustion at 3000 ° C or more multiple combustion Various energy storage cycle coalescing engines and coalescence methods for a simple injection engine (88b) aimed at superheated steam suction pyrolysis electrolysis.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and heat up two kinds of theoretical combustion chamber (4Q) near the center oxyfuel combustion 3000 ° C or more Various energy storage cycle coalescence engines and coalescence methods that are made into a simple injection engine (88b) aimed at superheated steam suction pyrolysis electrolysis by combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam heated at the optimum temperature on one kind of inner wall, and two kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 Various energy storage cycle coalescing engine and coalescence method, which is a simple injection engine (88b) aimed at superheated steam suction pyrolysis electrolysis with multiple combustion at ℃.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K), heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and burn two types of theoretical combustion chamber (4Q) near the center oxyfuel combustion at 3000 ° C or more multiple combustion Various energy storage cycle coalescing engine and coalescence method which is a simple injection engine (88b) aimed at superheated steam suction pyrolysis electrolysis oxygen oxygen hydrogen increase combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and heat up two kinds of theoretical combustion chamber (4Q) near the center oxyfuel combustion 3000 ° C or more Various energy storage cycle coalescing engine and coalescence method which is a simple injection engine (88b) aimed at combustion with superheated steam suction pyrolysis electrolysis oxygen hydrogen hydrogen combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam heated at the optimum temperature on one kind of inner wall, and two kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 Various energy storage cycle coalescing engine and coalescence method, which is a simple injection engine (88b) aimed at superheated steam suction pyrolysis electrolysis oxygen hydrogen augmentation combustion with multiple combustion at ℃ and above.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K), heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and burn two types of theoretical combustion chamber (4Q) near the center oxyfuel combustion at 3000 ° C or more multiple combustion Combustion flow inner wall (5d) Various energy storage cycle coalescence engine and coalescence method in a simple injection engine (88b) for heating and injecting superheated steam (50) of a high-temperature water heating pipe (5H).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + electricity, heat oxygen + fuel + superheated steam on one kind of inner wall at the optimum temperature, and heat up two kinds of theoretical combustion chamber (4Q) near the center oxyfuel combustion 3000 ° C or more Various energy storage cycle coalescence engines and coalescence methods which are made into a simple injection engine (88b) which heats and injects superheated steam (50) of a combustion flow inner wall (5d) high-temperature water heating pipe (5H) by combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, oxygen + fuel + superheated steam heated at the optimum temperature on one kind of inner wall, and two kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 Various energy storage cycle coalescence engines and coalescence methods, which are a simple injection engine (88b) that heats and injects superheated steam (50) of a combustion flow inner wall (5d) high-temperature water heating pipe (5H) by multiple combustion at a temperature of 0 ° C or higher.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receive cheaper liquid oxygen (5K) + hot water, and heat oxygen + fuel + superheated steam at the optimum temperature on one kind of inner wall, 2 kinds of theoretical combustion chamber (4Q) near the center oxygen fuel combustion 3000 ° C or more Various energy storage cycle coalescence engines and coalescence methods that are simple injection engines (88b) that heat and inject superheated steam (50) including superheated steam received from a combustion flow inner wall (5d) high-temperature water heating pipe (5H) by multiple combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) A simple injection engine (88b) which receives cheap liquid oxygen (5K) from the air (28a) and has a plurality of theoretical combustion chambers (4Q) at the optimum place of the suction injection flow (88b) as well. Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) A simple injection engine (88b) that receives cheaper liquid oxygen (5K) + electricity and injects combustion into the air (28a) at the optimum location of the suction injection flow in the same manner as a plurality of two types of theoretical combustion chambers (4Q). Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) A simple injection engine that receives cheaper liquid oxygen (5K) + electricity + hot water and combusts and injects the air (28a) at the optimum location of the suction injection flow in the same manner as the two types of theoretical combustion chambers (4Q). (88b) Various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K), rotating together with the simple injection engine (88b) and enabling vertical ascent and descent, various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity and rotating with the simple injection engine (88b) to enable vertical ascent and descent, and various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving cheaper liquid oxygen (5K) + electricity + hot water, rotating together with the simple injection engine (88b), and enabling vertical ascent and descent, various energy storage cycle coalescence engines and coalescence methods.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) and rotate with the simple injection engine (88b) to enable reverse injection.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity and rotate with the simple injection engine (88b) to enable reverse injection.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + electricity + hot water and rotate with the simple injection engine (88b) to enable reverse injection.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that receive cheaper liquid oxygen (5K) + hot water and rotate with the simple injection engine (88b) to enable reverse injection.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various types of energy as an electrically driven theoretical gas compressor (3T) that mainly compresses electricity + high-temperature water (52b) and compresses from the outer peripheral large compression blade with the gas volume inversely proportional to the pressure to the central short compression blade Storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence, which are mainly driven by supplying electricity, and are electrically driven theoretical gas compressors (3T) that compress the gas volume from the outer peripheral long compression blades to the central short compression blades with the gas volume inversely proportional to the pressure Method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Electric energy + superheated steam supply Mainly gas-driven theoretical gas compressor (3T) that compresses from a large outer peripheral compression blade to a central short compression blade with the gas volume inversely proportional to the pressure. Organization and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Supplying electricity + high-temperature water (52b) Mainly supplying air as an electrically driven theoretical gas compressor (3T) that compresses from the outer peripheral large compression blades to the central short compression blades whose gas volume is inversely proportional to the pressure Various energy storage cycle coalescence engines and coalescence methods for compression.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycles in which air is sucked in and compressed as an electrically driven theoretical gas compressor (3T) that compresses from a large outer peripheral compressor blade with a gas volume inversely proportional to the pressure to a central short compressor blade. Merger engine and merger method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Electric + superheated steam is mainly supplied, and the gas volume is inversely proportional to the pressure. The electric driven theoretical gas compressor (3T) that compresses from the outer peripheral large compression blade to the central short compression blade. Energy conservation cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Supplying electricity + high-temperature water (52b) Mainly supplying air as an electrically driven theoretical gas compressor (3T) that compresses from the outer peripheral large compression blades to the central short compression blades whose gas volume is inversely proportional to the pressure Various energy storage cycle coalescence engine and coalescence method for producing compressed heat exchange superheated steam.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) As the electrically driven theoretical gas compressor (3T), which compresses the gas from the outer circumferential long large compression blade to the central short compression blade whose volume is inversely proportional to the pressure. Various energy storage cycle coalescence engines and coalescence methods to be manufactured.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Supplying electricity + superheated steam As the electrically driven theoretical gas compressor (3T) that compresses from the outer peripheral large compression blade to the central short compression blade with the gas volume inversely proportional to pressure Various energy storage cycle coalescence engine and coalescence method for producing superheated steam.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Electrically driven high-temperature water (52b) + superheated steam is mainly driven, and the gas volume is inversely proportional to the pressure. Various energy storage cycle coalescence engine and coalescence method for producing compressed heat exchange superheated steam by sucking air as   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Supplying electricity + high-temperature water (52b) Mainly supplying air as an electrically driven theoretical gas compressor (3T) that compresses from the outer peripheral large compression blades to the central short compression blades whose gas volume is inversely proportional to the pressure Various energy storage cycle coalescence engines and coalescence methods for producing superheated steam with a compressed air compressor (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) As the electric driven theoretical gas compressor (3T), which compresses the gas volume from the outer peripheral long large compression blades to the central short compression blades, the gas volume is inversely proportional to the pressure. Various energy storage cycle coalescence engine and coalescence method for producing superheated steam at (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) As the electrically driven theoretical gas compressor (3T) that compresses from the large outer peripheral compressor blade to the central short compressor blade whose gas volume is inversely proportional to the pressure. Various energy storage cycle coalescence engine and coalescence method for producing superheated steam with a heat exchanger (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Supplying electricity + high-temperature water (52b) Mainly supplying air as an electrically driven theoretical gas compressor (3T) that compresses from the outer peripheral large compression blades to the central short compression blades whose gas volume is inversely proportional to the pressure Various energy storage cycle coalescence engines and coalescence methods for supplying superheated steam to the production supply facility (3D) with a compressed air compressor (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) As the electric driven theoretical gas compressor (3T), which compresses the gas volume from the outer peripheral long large compression blades to the central short compression blades, the gas volume is inversely proportional to the pressure. (2Y) Various energy storage cycle coalescence engines and coalescence methods for supplying superheated steam to the production supply facility (3D).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) As the electrically driven theoretical gas compressor (3T) that compresses from the large outer peripheral compressor blade to the central short compressor blade whose gas volume is inversely proportional to the pressure. Various energy storage cycle coalescence engines and coalescence methods for supplying superheated steam to the production supply facility (3D) with a heat exchanger (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Supplying electricity + high-temperature water (52b) Mainly supplying air as an electrically driven theoretical gas compressor (3T) that compresses from the outer peripheral large compression blades to the central short compression blades whose gas volume is inversely proportional to the pressure Various energy storage cycle coalescence engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) with a compressed air compressor heat exchanger (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) As the electric driven theoretical gas compressor (3T), which compresses the gas volume from the outer peripheral long large compression blades to the central short compression blades, the gas volume is inversely proportional to the pressure. Various energy storage cycle coalescence engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) at (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) As the electrically driven theoretical gas compressor (3T) that compresses from the large outer peripheral compressor blade to the central short compressor blade whose gas volume is inversely proportional to the pressure. Various energy storage cycle coalescence engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) with a heat exchanger (2Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Electrically driven high-temperature water (52b) + superheated steam is mainly driven, and the gas volume is inversely proportional to the pressure. Various energy storage cycle coalescing engines and coalescence methods for supplying compressed air + superheated steam to the production supply facility (3D) with a suction compressed air compressor (2Y).   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure In compliance, various energy storage cycle coalescence engines and coalescence methods configured to compress from the outer peripheral large compression blade (8h) to the central short final compression blade (6).   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure In compliance, various energy storage cycle coalescing engines and coalescence methods that compress air as a configuration that compresses from the outer peripheral large compression blade (8h) to the center short final compression blade (6).   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for compressing air (28a) as a configuration for compressing from the outer peripheral large compression blade (8h) to the center short final compression blade (6) as a observance.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods in which air (28a) is compressed from the outer circumference to the suction center as a configuration in which the outer circumference long compression blade (8h) is compressed to the center short final compression blade (6) as a compliance.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods that heat air (28a) compressed water from the outer circumference to the suction center as a configuration in which the outer circumference large compression blade (8h) is compressed to the center short final compression blade (6) as a compliance.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for heating air (28a) compressed high-temperature water from the outer circumference to the suction center as a configuration in which compression is performed from the outer peripheral long large compression blade (8h) to the center short final compression blade (6).   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for heating air (28a) compressed superheated steam from the outer circumference to the suction center as a configuration for compressing from the outer peripheral long large compression blade (8h) to the center short final compression blade (6) as observance.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycles in which water is heated from the outer periphery to the suction center by air (28a) compressed air and compressed air heat exchanger (2Y) as a configuration to compress from the outer peripheral large compression blade (8h) to the center short final compression blade (6) Merger engine and merger method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure In compliance with the compression from the outer peripheral long large compressor blade (8h) to the center short final compressor blade (6), air (28a) is compressed from the outer periphery to the suction center, and various types of energy are stored in the compressed air heat exchanger (2Y). Cycle coalescence engine and coalescence method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure As a configuration to compress from the outer peripheral long large compression blade (8h) to the center short final compression blade (6), air (28a) is compressed from the outer periphery to the suction center. Cycle coalescence engine and coalescence method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for producing superheated steam with a compressed air heat exchanger (2Y) as a configuration for compressing from the outer peripheral long large compression blade (8h) to the center short final compression blade (6) as observance.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for producing compressed air + superheated steam with a compressed air heat exchanger (2Y) as a configuration for compressing from the outer peripheral long large compression blade (8h) to the center short final compression blade (6) as observance.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycle coalescence engines and coalescence methods for producing high-pressure compressed air + high-pressure superheated steam with a compressed air heat exchanger (2Y) as a configuration for compressing from the outer peripheral large compression blade (8h) to the center short final compression blade (6) .   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure In compliance, various energy storage cycle coalescence engines that produce ultra-high pressure compressed air + ultra-high pressure superheated steam with a compressed air heat exchanger (2Y) as a configuration that compresses from the outer peripheral large compression blade (8h) to the central short final compression blade (6), and Merge method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy storage cycles to supply compressed air + superheated steam production and supply facility (3D) with compressed air heat exchanger (2Y) as a configuration to compress from the outer peripheral long large compression blade (8h) to the central short final compression blade (6) Merger engine and merger method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy supplied to the high pressure compressed air + high pressure superheated steam production and supply equipment (3D) by the compressed air heat exchanger (2Y) as a structure to compress from the outer peripheral long large compression blade (8h) to the center short final compression blade (6) Storage cycle coalescence engine and coalescence method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure In compliance, the compressed air heat exchanger (2Y) supplies the ultra-high-pressure compressed air + ultra-high-pressure superheated steam production and supply equipment (3D) as a configuration that compresses from the outer peripheral long large compression blade (8h) to the central short final compression blade (6). Various energy storage cycle coalescence engines and coalescence methods.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure Various energy supplied to the production and supply equipment for liquid air + super high pressure superheated steam (3D) in the compressed air heat exchanger (2Y) as a configuration to compress from the outer peripheral large compression blade (8h) to the center short final compression blade (6) Storage cycle coalescence engine and coalescence method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure As a configuration, the compressed air heat exchanger (2Y) supplies the liquid oxygen + liquid nitrogen + super high pressure superheated steam production and supply equipment (3D) as a configuration that compresses from the outer peripheral large compression blade (8h) to the center short final compression blade (6). Various energy storage cycle coalescence engine and coalescence method.   Magnetically utilized bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) Theoretical gas compressor (3T) of extremely inexpensive power generation electric drive, gas volume is inversely proportional to pressure In compliance, the compressed air heat exchanger (2Y) is configured to compress from the outer peripheral large compression blade (8h) to the center short final compression blade (6). Electricity + liquid oxygen + liquid nitrogen + super high pressure superheated steam production and supply equipment (3D) Various energy storage cycle coalescence engine and coalescence method to be supplied to   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods for receiving cheaper liquid oxygen (5K) by receiving fuel injection combustion + combustion fuel injection into compressed air.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that make cheaper liquid oxygen (5K) into two types: received fuel injection combustion + compressed air fuel injection combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that make cheaper liquid oxygen (5K) into two types of theoretical combustion chambers: receiving fuel injection combustion + compressed air and fuel injection combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Various energy storage cycle coalescence engines and coalescence methods that make cheaper liquid oxygen (5K) into two types of theoretical combustion chambers (4Q) of receiving fuel injection combustion + compressed air into fuel injection combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Receiving less expensive liquid oxygen (5K), fuel injection combustion + compressed air fuel injection combustion, two kinds of theoretical combustion chamber (4Q), one kind of energy storage cycle coalescing engine and coalescence equipped with on-off valve (1Q) Method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + fuel injection combustion into compressed air 2 types of theoretical combustion chamber (4Q), 1 type of various energy provided on-off valve (1Q) oxygen injection nozzle (6L) Storage cycle coalescence engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) is received fuel injection combustion + compressed air and fuel injection combustion into two types of theoretical combustion chamber (4Q) and one type of inlet is an on-off valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle ( 6X) Various energy storage cycle coalescence engines and coalescence methods provided.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) is received fuel injection combustion + compressed air and fuel injection combustion into two types of theoretical combustion chamber (4Q) and one type of inlet is an on-off valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle ( 6X) On-off valve (1Q) Various energy storage cycle coalescence engine and coalescence method for closing.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) is received fuel injection combustion + compressed air and fuel injection combustion into two types of theoretical combustion chamber (4Q) and one type of inlet is an on-off valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle ( 6X) On-off valve (1Q) Various energy storage cycle coalescence engine and coalescence method for closed oxygen fuel injection combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) is received fuel injection combustion + compressed air and fuel injection combustion into two types of theoretical combustion chamber (4Q) and one type of inlet is an on-off valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle ( 6X) On-off valve (1Q) Various energy storage cycle coalescing engine and coalescence method for increasing the closed oxygen fuel injection combustion rotation output.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) is received fuel injection combustion + compressed air and fuel injection combustion into two types of theoretical combustion chamber (4Q) and one type of inlet is an on-off valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle ( 6X) On-off valve (1Q) Closed oxygen fuel injection combustion rotation output increase 2 types (4Q) Superheated steam (50) Various energy storage cycle coalescing engine and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) is received fuel injection combustion + compressed air and fuel injection combustion into two types of theoretical combustion chamber (4Q) and one type of inlet is an on-off valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle ( 6X) On-off valve (1Q) Closed oxygen fuel injection Combustion rotation output increase 2 types (4Q) Various energy storage cycle coalescence engine and coalescence method for sucking and injecting combustion gas (49) by superheated steam (50) injection.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) is received fuel injection combustion + compressed air and fuel injection combustion into two types of theoretical combustion chamber (4Q) and one type of inlet is an on-off valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle ( 6X) On-off valve (1Q) Closed oxygen fuel injection combustion rotation output increase 2 types (4Q) Various energy storage cycle coalescence engine and coalescence method for increasing suction injection injection propulsion output of combustion gas (49) by superheated steam (50) injection .   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + compressed air fuel injection combustion into two types of theoretical combustion chamber (4Q), one type inlet / outlet with opening / closing valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle (6X) Various energy storage cycle coalescence engines and coalescence methods included.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + compressed air fuel injection combustion into two types of theoretical combustion chamber (4Q), one type inlet / outlet with opening / closing valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle (6X) The on-off valve (1Q) Various energy storage cycle coalescence engines and coalescence methods for closing.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + compressed air fuel injection combustion into two types of theoretical combustion chamber (4Q), one type inlet / outlet with opening / closing valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle (6X) On-off valve (1Q) Various energy storage cycle coalescence engine and coalescence method for closed oxygen fuel injection combustion.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + compressed air fuel injection combustion into two types of theoretical combustion chamber (4Q), one type inlet / outlet with opening / closing valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle (6X) The on-off valve (1Q) closed oxygen fuel injection combustion high-pressure high-temperature combustion gas (5M) various energy storage cycle coalescence engine and coalescence method for injecting the outer periphery (6Y).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + compressed air fuel injection combustion into two types of theoretical combustion chamber (4Q), one type inlet / outlet with opening / closing valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle (6X) Various opening-and-closing valves (1Q) Closed oxygen fuel injection combustion High-pressure high-temperature combustion gas (5M) The outer periphery (6Y) The injection superheated steam (50) is also injected into the outer periphery (6A).   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + compressed air fuel injection combustion into two types of theoretical combustion chamber (4Q), one type inlet / outlet with opening / closing valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle (6X) Open / close valve (1Q) Closed oxygen fuel injection combustion High pressure high temperature combustion gas (5M) Outer periphery (6Y) Rocket injection superheated steam (50) Also outer periphery (6A) Various energy storage cycle coalescence to increase rocket injection injection propulsion output Organization and coalescence method.   Vertically moving blade ratio critical material gravity turbine (8Q) with magnetic approaching bearing load 0 approach + super high speed circumferential speed Electricity + liquid air cold heat + hot water to superheated steam heat supply facility (8Q) 3D) Cheaper liquid oxygen (5K) received fuel injection combustion + compressed air fuel injection combustion into two types of theoretical combustion chamber (4Q), one type inlet / outlet with opening / closing valve (1Q) oxygen injection nozzle (6L) fuel injection nozzle (6X) equipped open / close valve (1Q) closed oxygen fuel injection combustion high pressure high temperature combustion gas (5M) outer periphery (6Y) rocket injection superheated steam (50) also outer periphery (6A) rocket injection and suction water injection forward propulsion Various energy storage cycle coalescence engines and coalescence methods with increased output.   Cylindrical all-blade ratio critical material gravity turbine (8Q) with a magnetic bearing load of 0 approach + super-high-speed circumferential speed. Various energy storage cycle coalescing engines that use an electrically driven solar heater (21) + theoretical gas compressor (3T) for power generation as a turbine utilizing a magnetic force that reversely inverts the group (60C) and the cylindrical outer blade group (60D); Merge method.   Magnet type bearing load approaching 0 + super high speed circumferential speed blade-type all blade ratio critical material gravity turbine (8Q) Ultra-high pressure vertical under vacuum mixed material injection including mixed injection and acceleration of gravitational acceleration, inside multiple cylinders Combined with various energy conservation cycles to make a power-driven solar heater (21) + theoretical gas compressor (3T) for power generation as a turbine utilizing magnetic force that double-reverses the blade group (60C) and the cylindrical outer blade group (60D) Organization and coalescence method.   Magnet type bearing load approaching 0 + super high speed circumferential speed blade-type all blade ratio critical material gravity turbine (8Q) Ultra-high pressure vertical under vacuum mixed material injection including mixed injection and acceleration of gravitational acceleration, inside multiple cylinders Various types of energy conservation using a rotating blade group (60C) and a cylindrical outer moving blade group (60D) as magnetically utilizing multiple magnetic turbines to generate electricity as an electrically driven solar heater (21) + theoretical gas compressor (3T) Cycle coalescence engine and coalescence method.   Cylindrical all-blade ratio critical material gravity turbine (8Q) with a magnetic bearing load of 0 approach + super-high-speed circumferential speed. Electric drive solar heater (21) + theoretical gas compressor (3T) for power generation as a magnetic force turbine that double-reverses the group (60C) and the outer cylindrical blade group (60D) with a double reversal magnetic device (85) Various energy storage cycle coalescence engines and coalescence methods.   Magnet type bearing load approaching 0 + super high speed circumferential speed blade-type all blade ratio critical material gravity turbine (8Q) Ultra-high pressure vertical under vacuum mixed material injection including mixed injection and acceleration of gravitational acceleration, inside multiple cylinders Electricly driven solar heater (21) + theoretical gas compressor for power generation as a turbine using magnetic force to reverse the moving blade group (60C) and the outer cylindrical moving blade group (60D) with a counter rotating magnetic device (85) 3T) various energy storage cycle coalescence engines and coalescence methods.   Magnet type bearing load approaching 0 + super high speed circumferential speed blade-type all blade ratio critical material gravity turbine (8Q) Ultra-high pressure vertical under vacuum mixed material injection including mixed injection and acceleration of gravitational acceleration, inside multiple cylinders Electric power driven solar heater (21) + theoretical gas compression as a large number of turbines using magnetic force to double-rotate the blade group (60C) and the cylindrical outer blade group (60D) with a counter-rotating magnetic device (85) Various energy storage cycle coalescence engine and coalescence method to make machine (3T).   Cylindrical all-blade ratio critical material gravity turbine (8Q) with a magnetic bearing load of 0 approach + super-high-speed circumferential speed. Electricly driven solar heater (21) + theoretical gas compressor for power generation as a weight-supported magnetic force turbine that double-reverses the group (60C) and the cylindrical outer blade group (60D) with a double reversal magnetic device (85) (3T) Various energy storage cycle coalescence engines and coalescence methods.   Magnet type bearing load approaching 0 + super high speed circumferential speed blade-type all blade ratio critical material gravity turbine (8Q) Ultra-high pressure vertical under vacuum mixed material injection including mixed injection and acceleration of gravitational acceleration, inside multiple cylinders Electric drive solar heater (21) + theoretical gas for power generation as a weight-supporting magnetic force turbine that reverses the rotor blade group (60C) and the cylindrical outer rotor blade group (60D) with a counter rotating magnetic device (85) Various energy storage cycle coalescence engines and coalescence methods for a compressor (3T).   Magnet type bearing load approaching 0 + super high speed circumferential speed blade-type all blade ratio critical material gravity turbine (8Q) Ultra-high pressure vertical under vacuum mixed material injection including mixed injection and acceleration of gravitational acceleration, inside multiple cylinders Electric drive solar heater (21) + for power generation as a large number of turbines using weight-supporting magnetic force, etc., in which the rotor blade group (60C) and the cylindrical outer rotor blade group (60D) are double-reversed by a counter-rotating magnetic device (85) Various energy storage cycle coalescing engines and coalescence methods for a theoretical gas compressor (3T).   Various types of energy to drive a simple water injection engine (88c), etc. as a vertical type moving blade ratio critical material gravity turbine (8Q) power generation electrical product + rocket combustion + jet combustion with magnetic bearing load approaching 0 + super high speed circumferential speed Storage cycle coalescence engine and coalescence method.   Magnetically-enhanced bearing load approaching 0 + super-high speed circumferential speed of all blades critical material gravity turbine (8Q) power generation electrical product + rocket combustion 2 locations + jet combustion 2 locations simple water injection engine (88c) etc. Various energy storage cycle coalescence engines and coalescence methods to be driven.   Magnetically-enhanced bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) power generation electrical product + rocket combustion 3 locations + jet combustion 3 locations, simple water injection engine (88c), etc. Various energy storage cycle coalescence engines and coalescence methods to be driven.   Magnetically-enhanced bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) power generation electrical product + rocket combustion 4 locations + jet combustion 4 locations simple water injection engine (88c) etc. Various energy storage cycle coalescence engines and coalescence methods to be driven.   Magnetically-enhanced bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) power generation electrical product + rocket combustion 5 locations + jet combustion 5 locations simple water injection engine (88c) etc. Various energy storage cycle coalescence engines and coalescence methods to be driven.   Magnetically-enhanced bearing load approaching 0 + super-high speed circumferential speed with full blade ratio critical material gravity turbine (8Q) power generation electrical product + rocket combustion 6 locations + jet combustion 6 locations, simple water injection engine (88c), etc. Various energy storage cycle coalescence engines and coalescence methods to be driven.   Various energy storage cycles driven by a simple injection engine (88b) as a vertical type moving blade ratio critical material gravity turbine (8Q) power generation electrical product + rocket combustion + jet combustion with magnetic bearing load approaching 0 + super high speed circumferential speed Merger engine and merger method.   A simple injection engine (88b) is driven as a saddle-type full-blade ratio critical material gravity turbine (8Q) power generation electric product + 2 rocket combustion + 2 jet combustion 2 locations with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   A simple injection engine (88b) is driven as a vertical type moving blade ratio critical material gravity turbine (8Q) power generation electrical product + three rocket combustion + three jet combustion locations with magnetically approaching bearing load 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   A simple injection engine (88b) is driven as a saddle-type full-blade ratio critical material gravity turbine (8Q) power generation electric product + 4 rocket combustion + 4 jet combustion 4 locations with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   A simple injection engine (88b) is driven as a vertical type moving blade ratio critical material gravity turbine (8Q) power generation electrical product + 5 rocket combustion + 5 jet combustion 5 locations with magnetically approaching bearing load 0 approach + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   A simple injection engine (88b) is driven as a vertical type moving blade ratio critical material gravity turbine (8Q) power generation electrical product + 6 rocket combustion + 6 jet combustion 6 locations with magnetic bearing load approaching 0 + super high speed circumferential speed Various energy storage cycle coalescence engines and coalescence methods.   Vertical type moving blade ratio critical material gravity turbine (8Q) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D), simple water Various energy storage cycle coalescence engine and coalescence method for jetting the maximum amount of air bubbles into the bottom vertical parallel plate (9Q) using a simple water injection engine such as an injection engine (88c) and a ship (7G).   Vertical type moving blade ratio critical material gravity turbine (8Q) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D), simple water Various energy storage cycle coalescing engine and coalescence method in which a jet screw ship such as an injection engine (88c) is used to inject a maximum amount of bubbles into a vertical bottom plate (9Q).   Vertical type moving blade ratio critical material gravity turbine (8Q) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D), simple water Various energy storage cycle coalescence engine and coalescence method for maximizing air levitation by providing a simple water injection engine such as an injection engine (88c) and a ship bottom (7G) with a wide vertical bottom plate (9Q).   Vertical type moving blade ratio critical material gravity turbine (8Q) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D), simple water Various energy storage cycle coalescing engines and coalescence methods for making a screw-injected ship such as an injection engine (88c) wide and having a bottom vertical parallel plate (9Q) wide to maximize the amount of air floating.   Vertical type moving blade ratio critical material gravity turbine (8Q) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D), simple water Various energy storage cycle coalescing engine and coalescence method for maximizing friction reduction by making the bottom of the ship's vertical parallel plate (9Q) wide by making the driving simple water injection engine ship (7G) such as the injection engine (88c).   Vertical type moving blade ratio critical material gravity turbine (8Q) Receives low-priced liquid oxygen (5K) from electricity + liquid air cold heat + hot water to superheated steam heat supply equipment (3D), simple water Various energy storage cycle coalescing engines and coalescence methods for making a screw-injected ship such as an injection engine (88c) wide and having a bottom vertical parallel plate (9Q) wide to maximize friction reduction.