JP2009209921A - Various energy conservation cycle combined engine - Google Patents

Various energy conservation cycle combined engine Download PDF

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JP2009209921A
JP2009209921A JP2008202677A JP2008202677A JP2009209921A JP 2009209921 A JP2009209921 A JP 2009209921A JP 2008202677 A JP2008202677 A JP 2008202677A JP 2008202677 A JP2008202677 A JP 2008202677A JP 2009209921 A JP2009209921 A JP 2009209921A
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power generation
accelerating
air
turbine
downward
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Hiroyasu Tanigawa
浩保 谷川
Kazunaga Tanigawa
和永 谷川
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Hiroyasu Tanigawa
浩保 谷川
Kazunaga Tanigawa
和永 谷川
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/20Solar thermal
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02BCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
    • Y02B10/00Integration of renewable energy sources in buildings
    • Y02B10/50Hydropower in dwellings
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/40Solar thermal energy, e.g. solar towers
    • Y02E10/46Conversion of thermal power into mechanical power, e.g. Rankine, Stirling or solar thermal engines
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/14Combined heat and power generation [CHP]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/16Combined cycle power plant [CCPP], or combined cycle gas turbine [CCGT]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P80/00Climate change mitigation technologies for sector-wide applications
    • Y02P80/10Efficient use of energy, e.g. using compressed air or pressurized fluid as energy carrier
    • Y02P80/15On-site combined power, heat or cool generation or distribution, e.g. combined heat and power [CHP] supply
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/10Internal combustion engine [ICE] based vehicles
    • Y02T10/12Improving ICE efficiencies

Abstract

<P>PROBLEM TO BE SOLVED: To solve problems in conventional thermal power plants and nuclear power plants wherein the temperature of seawater is raised by the entire heat quantity generated by the power generation, if China continues to grow at the rate of 10%, the rise of the temperature exceeds 1,000 times in one hundred years, concentrated downpour occurs and typhoon wind velocity is increased near 10 to one hundred times, and the threat of annihilation of mankind comes. <P>SOLUTION: An opposed, series, all moving blade flywheel water turbine is driven by the gravitational acceleration of (water + compressed air) x steel balls in a theoretically best hydraulic air force solar power generation exhausting no CO<SB>2</SB>and requiring no fuel cost. An atmospheric pressure equal speed power is 1,700×7.8= approximately 13,000 times that of an existing steam turbine. A gravity acceleration of 9.8 m/sec vertically downward is added to the gravitational acceleration in vacuum to enhance the acceleration. A head drop is increased to 1,000 m to increase the power generation amount. The power generation amount is increased to 1,000 times the existing hydraulic power generation. The power generation is increased ten times the existing power generation amount of the world by the air force solar power and gravitational acceleration power generation + gravitational acceleration power generation exhausting no additional CO<SB>2</SB>and requiring no fuel cost. Various automobiles, various ships, and various fully electrical houses driven by an extremely inexpensive air force solar power and gravitational acceleration power generation storage battery can be easily and widely used by everybody for preventing global warming. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

地球最大加速が重力加速度で最大熱量が太陽光で理論最良エンジンは、空気力太陽光重力加速度発電+重力加速度発電となり、重力加速度発電では1000m以上等限り無く落差を増大出力増大して、水銀や鋼球等の比重大物質1c等の出力増大球2Eを真空中で垂直下方に重力加速度加速し、被覆や潤滑油等衝撃低減手段2Gを設けた比重大物質1c等を重力加速度加速の過程で、全動翼弾み車重力タービン8Fを駆動重力加速度発電として、例えば水銀の重力加速度発電にすると大気圧同速度仕事率kg重m/秒を、既存蒸気タービン発電の1700×13.5倍=22950倍にし、理論的には白金球が1700×21.3=36210倍で最良ですが、資源量や単価を考えて軸受大量生産中の鋼球の重力加速度発電にすると、既存蒸気タービン発電の1700×7.8倍=約1.3万倍にして、消費熱量0タービン以外の設備費0として9.8m/毎秒毎秒の加速とし、既存蒸気タービン発電の1000倍発電量を余裕最大で狙う重力加速度発電技術に関する。   The Earth's maximum acceleration is gravitational acceleration and the maximum amount of heat is sunlight. The best engine is aerodynamic solar gravity acceleration power generation + gravity acceleration power generation. In the process of acceleration of gravity acceleration, the gravity-accelerated acceleration of the power-enhancing sphere 2E such as a steel ball or the like in a vacuum is vertically accelerated in a vacuum and the impact reduction means 2G such as a coating or lubricating oil is provided. , If the whole moving blade bouncer gravity turbine 8F is driven as gravitational acceleration power generation, for example, mercury gravity acceleration power generation, the atmospheric pressure same speed power kg weight m / second is 1700 × 13.5 times = 2950 times that of the existing steam turbine power generation. Theoretically, the platinum ball is the best at 1700 × 21.3 = 36210 times, but considering the amount of resources and unit price, if the gravity acceleration power generation of the steel ball in mass production of bearings, Turbine power generation 1700 x 7.8 times = approx. 13,000 times, heat consumption is 0, equipment cost other than turbine is 9.8m / second acceleration per second, 1000 times power generation capacity of existing steam turbine power generation It relates to the gravitational acceleration power generation technology that is aimed at the maximum.
噴射推進やメタンハイドレート回収等熱量を必要とする簡単構成は、空気力太陽光重力加速度エンジン乃至空気力太陽光重力加速度発電として、太陽光加熱器2や太陽熱増大吊橋2bや夫々を変形の空気管空気28aや内部空気28aを加熱し、熱ポンプ1Gで繰り返し圧縮熱回収冷却繰り返し600〜1000度として、最終熱回収冷却の過程で必要に応じて燃料噴射燃焼や液体酸素圧入燃料噴射燃焼し、過熱蒸気50温度や水52b温度を上昇して、圧縮熱回収器2Cの圧縮空気を40度前後400MPa等とし、水52bは100〜300度等として水噴射ポンプ6zにより400MPa噴射等として、水52bを真空中で垂直下方に重力加速度加速の過程で大量の鋼球等出力増大球2Eを加速し、対向直列全動翼弾み車水タービン又は直列全動翼弾み車水タービンを駆動して、空気力太陽光重力加速度発電水タービン駆動で、既存蒸気タービン発電の1000倍発電量を狙うと共に、圧縮熱回収器2Cの過熱蒸気50温度を400〜540度に上昇し、メタンハイドレート回収やオイルサンド回収や永久凍土メタン回収や噴射推進船舶の駆動等、水温熱52dや過熱蒸気温熱52dとしても各種用途に使用する、空気力太陽光重力加速度発電や空気力太陽光重力加速度エンジン技術に関する。   A simple configuration that requires a quantity of heat, such as injection propulsion and methane hydrate recovery, is an aerodynamic solar gravity acceleration engine or aerodynamic solar gravity acceleration power generation, in which the solar heater 2 and the solar thermal suspension suspension bridge 2b are each deformed air. The pipe air 28a and the internal air 28a are heated, and repeatedly compressed heat recovery cooling 600 to 1000 degrees with the heat pump 1G, and fuel injection combustion or liquid oxygen injection fuel injection combustion is performed as necessary in the process of final heat recovery cooling, The temperature of the superheated steam 50 and the temperature of the water 52b are increased, the compressed air of the compressed heat recovery unit 2C is set to 400 MPa around 40 degrees, the water 52b is set to 100 to 300 degrees, etc. Accelerates a large number of steel balls, such as steel balls, with increased output in the process of accelerating gravitational acceleration vertically downward in a vacuum. A series full blade impeller water turbine is driven, and aerodynamic solar gravity acceleration power generation water turbine drive is aimed at generating power 1000 times that of the existing steam turbine power generation, and the superheated steam 50 temperature of the compression heat recovery unit 2C is set to 400 to 400 Pneumatic solar gravity acceleration power generation, which is used for various purposes such as water heat 52d and superheated steam heat 52d, such as methane hydrate recovery, oil sand recovery, permafrost methane recovery, and jet propulsion ship drive. And aerodynamic solar gravity acceleration engine technology.
圧縮熱回収器2Cの40度前後400MPa等の圧縮空気速度により、大量の鋼球等出力増大球2Eを垂直下方に重力加速度加速し、対向直列全動翼弾み車ガスタービン又は直列全動翼弾み車ガスタービンを駆動して、既存蒸気タービン発電の1000倍発電量を狙い、排気空気温度を絶対0度に近付ける過程で液体窒素や液体酸素でも回転出力を発生し、排気後は圧縮熱で水52bや過熱蒸気50を加熱した熱量に近い膨大な冷熱52eを回収して、例えば非常に安価な氷大量生産都市部を氷冷却して冷夏都市に逆転する等各種用途に使用し、残りの冷熱は海水冷却の過程で海底に窒素や酸素等と共に各種栄養分を供給して、植物プランクトンや海藻類等を大増殖し、食物連鎖により魚類等を大増殖して、既存火力原子力発電が海面温度を7度上昇し、冬場に海面を冷却海底に栄養分を供給する自然現象を不可能として、テレビ報道でも日本近海の海藻類や魚類が絶滅に近付いており、海底に酸素や窒素の冷熱を供給する過程でCO2等の栄養分も同時に供給し、食物連鎖で海藻類や魚類激減を逆転する各種空気力発電技術に関する。   A large amount of steel ball and other power increase spheres 2E are accelerated in the vertical direction by gravitational acceleration by a compressed air velocity of about 400 degrees Celsius or the like of the compressed heat recovery unit 2C, and the opposed series full blade pusher gas turbine or series full blade pusher gas The turbine is driven to produce 1000 times the amount of power generated by existing steam turbine power generation, and in the process of bringing the exhaust air temperature close to absolute 0 °, rotational output is generated even with liquid nitrogen or liquid oxygen. A large amount of cold heat 52e close to the amount of heat generated by heating the superheated steam 50 is recovered, and used for various purposes such as ice cooling of a very inexpensive ice mass production city area and reversing to a cold summer city. In the process of cooling, various nutrients are supplied to the sea floor along with nitrogen and oxygen, etc., and phytoplankton and seaweeds are proliferated. As the natural phenomenon of supplying nutrients to the sea floor becomes impossible, the sea surface of Japan near sea is approaching extinction, and the process of supplying cold oxygen and nitrogen to the sea floor The present invention relates to various aerodynamic power generation technologies that simultaneously supply nutrients such as CO2 and reverse the drastic decline of seaweed and fish in the food chain.
後追いエンジン発明阻止のため、高校や大学で理論最良エンジンと徹底的に騙しており、小学校理科に戻って理論最良エンジンを考えると、出力や仕事率の単位がkg重m/秒等重量×速度のため、重い物質を高速度にして回転出力発生が理論最良エンジンです。回転出力発生で充分な頃発明の火力原子力発電海面温度7度上昇を100年続けると、CO2排出量や海水表面温度7度上昇海域が10%成長で1000倍を超えるため、旱魃や豪雨や風速を10倍の300m/秒台風や季節風として南極の氷を0に近付け、陸と海の食糧が0に近付き、人類が絶滅する背景があります。火力原子力発電では海面温度7度上昇は環境に影響皆無と騙しており、日本近海の海藻類や魚類が絶滅に近付くテレビ報道が実際です。IPCC北極予測も7度上昇がコンピュータ計算外のため、衛星去年観測北極海海氷面積がIPCC予測40年後に近い状態で観測された報道があり、IPCC予測全部を大誤報と考えるのが良く、平均的に1度温度上昇しても異状気象は困難で、90%前後が海面温度7度上昇と考えると、100年前後で海面温度2〜3回上昇14〜21度上昇海域が出現し、南極の氷が0に近付き、海面上昇が77mに近付く背景があります。   In order to prevent the invention of the follow-up engine, I was thoroughly fooled by the theoretical best engine in high school and university, and when I went back to elementary school science and thought about the theoretical best engine, the unit of output and work rate was kg weight m / second equal weight x speed Therefore, it is the theoretical best engine that generates heavy output at a high speed with heavy substances. When the generation of rotational power is sufficient, the thermal nuclear power generation of the invention will continue to rise by 7 degrees in sea surface temperature for 100 years. CO2 emissions and sea surface temperature increase by 7 degrees will exceed 1000 times by 10% growth, so dredging, heavy rain and wind speed There is a background that the Antarctic ice is brought close to 0 as a typhoon and seasonal wind of 10 times, and the food of land and sea approaches 0, and the human race is extinct. With thermal nuclear power generation, a 7-degree rise in sea surface temperature is said to have no impact on the environment, and TV reports that seaweeds and fish near Japan are nearing extinction are actual. Since the IPCC Arctic forecast also rose by 7 degrees outside the computer calculation, there was a report that the satellite last year observed the Arctic sea ice area was in a state close to 40 years after the IPCC forecast, and it is good to consider the entire IPCC forecast as a big misinformation, Even if the temperature rises by 1 degree on average, abnormal weather is difficult, and if about 90% thinks that the sea surface temperature will rise by 7 degrees, the sea area will rise 2 to 3 times in about 100 years and the sea area will rise 14 to 21 degrees, There is a background that Antarctic ice approaches 0 and sea level rise approaches 77m.
出力や仕事率の単位がkg重m/秒等重量×速度のため、重い物質を重力加速度加速にして回転出力を発生するのが理論最良エンジンですが、考えた痕跡が皆無という背景があります。そこで空気力太陽光発電として、水の気化爆発力タービン駆動にすると消費熱量を既存蒸気タービンの1/539にし、大気圧同速度同熱量仕事率kg重m/秒を539×1700倍=約91万倍にし、水銀の気化爆発力タービン駆動にすると、大気圧同速度同熱量仕事率が91万倍×13.5×28/13.5=2548万倍になり、白金球や水銀や鋼球等比重大物質を垂直下方に重力加速度加速にすると、低速で落差を増大する入力より重力加速度加速だけでも出力発生は大幅に増大し、タービンの大型化多数化+落差を1000m以上に増大限り無く出力を増大できる背景があります。地球での最大加速が重力加速度で最大熱源が太陽光であり、重力加速度源も熱源も無限大に近く、CO2排気0や燃料費0の理論最良エンジン空気力太陽光重力加速度発電として、無限大に近い発電量とし、重力加速度発電+太陽光発電蓄電池駆動や電気駆動の、各種自動車類全盛や各種船舶類全盛や全面電化住宅全盛等、極端に安価な電気駆動が得られる背景があります。   Since the unit of output and power is kg weight m / sec, equal weight x speed, the best engine theoretically generates a rotating output by accelerating gravitational acceleration of heavy substances, but there is a background that there is no trace of thought. Therefore, when the aerodynamic photovoltaic power generation is used to drive the vaporization explosive power of water, the heat consumption is reduced to 1/539 of that of the existing steam turbine, and the atmospheric pressure, the same speed, and the same calorific power, kg weight m / sec, are 539 × 1700 times = about 91 If the mercury vaporization explosive power turbine drive is used, the atmospheric pressure, the same speed and the same caloric power will be 910,000 times x 13.5 x 28 / 13.5 = 25.48 million times, and platinum balls, mercury and steel balls When gravity-accelerated acceleration is applied to a material with an equal ratio in the vertical direction, the generation of output is greatly increased only by acceleration of gravitational acceleration, rather than the input that increases the head at low speed, and the number of turbines increases and the head increases to 1000 m or more. There is a background that can increase the output. The maximum acceleration on the earth is gravitational acceleration and the maximum heat source is sunlight, the gravity acceleration source and the heat source are almost infinite, and the theoretical best engine aerodynamic solar gravity acceleration power generation with zero CO2 exhaust and zero fuel cost is infinite. There is a reason that it is possible to obtain extremely low-priced electric drive, such as gravitational acceleration power generation + photovoltaic power storage battery drive and electric drive, such as various types of automobiles, various types of ships, and full-scale electrified houses.
昭和17〜18年に理論最良エンジンの発明を決意実際は改良から始め、昭和38年岡山地方発明センターの請負で試作を開始して、自分でも試作を続けましたがエンジンの試作は非常に困難です。そこで昭和57年2月より国内大企業等多数にご協力のお願い始めましたが、日本企業等の協力が皆無で、外国唯一お願いしたクリントン大統領の協力がお願いの都度3年3回得られ、1992年米国特許5133305号、1993年米国特許5230307号、1995年米国特許5429078号の駄目発明が判明したのです。既存のエンジンに致命的な欠点が非常に多く一発発明不可能が判明し、急がば回れと1997年ホームページを開設して欠点を1つづつ改良特許出願して、2006年理論最良エンジン近くに到達したものです。
米国特許第6119650号、中国特許第8818号、EU英国特許902175号、米国特許第6263664号があり、上記多数の背景技術を改良や、下記特許文献2も理論最良エンジン発明の過程の発明です。 先の出願として特願2007−179204号、特願2007−221970号、特願2007−237367号、特願2007−250348号、特願2007−265115号、特願2008−6612号、特願2008−22246号、特願2008−24656号、特願2008−28582号、特願2008−30162号、特願2008−94452号、特願2008−99870号、特願2008−125665号、特願2008−134046号、特願2008−137629号、特願2008−157556号、特願2008−158830号、特願2008−162842号、特願2008−164111号、特願2008−166907号、特願2008−169979号、特願2008−173046号、特願2008−174231号、特願2008−178700号、特願2008−179872号、特願2008−181052号、特願2008−182325号、特願2008−186795号、特願2008−188165号があります。
Decided to invent the theoretical best engine in 1958 and 1980. Actually started with improvements, and started prototyping at the contract of the Okayama Regional Invention Center in 1963. . Therefore, in February 1982, we started requesting cooperation from a large number of domestic large corporations, etc., but there was no cooperation from Japanese companies, etc., and every time we asked for the cooperation of President Clinton, the only request from foreign countries, three times a year, The 1992 US Patent 5133305, 1993 US Patent 5230307, and 1995 US Patent 5429078 were found to be useless. It was found that there were so many fatal faults in the existing engine that it was impossible to invent the first one, and suddenly, the 1997 homepage was opened and an improvement patent was filed one by one for the faults. It is what you have reached.
There are US Pat. No. 6,119,650, Chinese Patent No. 8818, EU British Patent No. 902175, US Pat. No. 6,263,664, and many of the above background technologies have been improved, and the following Patent Document 2 is also an invention in the process of theoretical best engine invention. As prior applications, Japanese Patent Application No. 2007-179204, Japanese Patent Application No. 2007-221970, Japanese Patent Application No. 2007-237367, Japanese Patent Application No. 2007-250348, Japanese Patent Application No. 2007-265115, Japanese Patent Application No. 2008-6612, and Japanese Patent Application No. 2008- No. 22246, No. 2008-24656, No. 2008-28582, No. 2008-30162, No. 2008-94452, No. 2008-99870, No. 2008-125665, No. 2008-125665, No. 2008-134046. No., Japanese Patent Application No. 2008-137629, Japanese Patent Application No. 2008-157556, Japanese Patent Application No. 2008-158830, Japanese Patent Application No. 2008-162842, Japanese Patent Application No. 2008-164111, Japanese Patent Application No. 2008-166907, Japanese Patent Application No. 2008-169799. Japanese Patent Application No. 2008-173046, Japanese Patent Application No. 20 No. 8-174231, Japanese Patent Application No. 2008-178700, Japanese Patent Application No. 2008-179872, Japanese Patent Application No. 2008-181052, Japanese Patent Application No. 2008-182325, Japanese Patent Application No. 2008-186795, there is Japanese Patent Application No. 2008-188165.
既存世界の火力原子力発電所では、CO2増大地球温暖化加速や海水表面温度摂氏7度上昇海域を100年で1000倍等とし、冬場に海面冷却海底に栄養分を供給していた自然現象を不可能として、植物プランクトンや海草類やサンゴ等を激減、食物連鎖により魚類の食糧激減魚類を大幅に激減人類の海中食物を限り無く減少し、旱魃や集中豪雨や台風や季節風を10倍等に増大して、例えば台風や季節風を300m/秒等として陸上での食糧生産も加速度的に困難とし、人類絶滅の危険を増大のため、理論最良エンジン空気力太陽光重力加速度発電により既存世界の1000倍発電量として、既存世界の火力原子力発電所を全廃し、空気力太陽光重力加速度発電蓄電池駆動各種自動車類全盛や、蓄電池駆動各種船舶類全盛や全面電化住宅全盛にし、CO2排気0燃料費0で人類絶滅を先送りする最大の課題が在ります。   In the existing world thermal power plants, CO2 increases global warming acceleration and sea surface temperature rises 7 degrees Celsius by 1000 times in 100 years, and the natural phenomenon of supplying nutrients to the sea surface cooling seabed in winter is impossible As a result, phytoplankton, seaweeds, corals, etc. are drastically reduced, fish food is drastically reduced by the food chain, mankind's marine foods are drastically reduced, droughts, torrential rains, typhoons and seasonal winds are increased 10 times, etc. For example, the typhoon and seasonal winds are 300m / second, etc., making it difficult to produce food on land at an accelerated rate and increasing the danger of human extinction. As a result, the existing nuclear power plants in the world will be completely abolished, aerodynamic solar gravitational acceleration power generation battery powered all types of automobiles, storage battery powered various ships primed and fully electrified houses To Sheng, there is the biggest challenge to put off the human race extinct in CO2 emissions 0 fuel costs 0.
CO2排気0燃料費0の理論最良エンジン空気力太陽光重力加速度発電により、例えば鋼球の重力加速度発電にすることで、大気圧同速度仕事率kg重m/秒を既存蒸気タービンの1.3万倍にして、既存世界の発電量の10倍発電量を超えて、空気力太陽光重力加速度発電蓄電池駆動各種自動車類全盛や、蓄電池駆動各種船舶類全盛や全面電化住宅全盛にし、既存世界の火力原子力発電所全廃CO2排気0にして、地球温暖化を防止し、海面7度上昇海域を0にして、人類絶滅を先送りする効果があります。   Theoretical best engine aerodynamic solar gravitational acceleration power generation with CO2 exhaust 0 fuel cost 0 By making the gravity acceleration power generation of, for example, a steel ball, the atmospheric pressure, the same speed power kg load m / second is 1.3 of the existing steam turbine. Over 10,000 times the amount of power generation in the existing world, aerodynamic solar gravitational acceleration power generation battery powered various cars prime, storage battery driven various ships primed, full electrified housing prime, It has the effect of preventing the global warming by reducing the total abolishment of CO2 emissions from thermal nuclear power plants, setting the sea level rising by 7 degrees to 0, and delaying the extinction of mankind.
発明の実施の形態や実施例を、図面を参照して説明するが、実施形態や実施例と既説明とその構成が略同じ部分には、同一の名称又は符号を付して、重複説明はできるだけ省略し、特徴的な部分や説明不足部分は、順次追加重複説明する。又非常に難解な脳内理論最良エンジン発明のためと、意図する所及び予想を具体的に明快に説明するため、アイディアを仮説数字で説明するが、正解は実験数字として理論最良エンジンの仮説数字に限定しません。最良と思われるアイディアを多数の用途で重複説明し、用途に合せてアイディアを選択使用して、請求項では多用途に合せて選択使用するため千変万化します。   Embodiments and examples of the invention will be described with reference to the drawings, but the same names or reference numerals are given to the same parts as those of the embodiments and examples and the description above, and duplicate description will be omitted. Omitted as much as possible, and the characteristic parts and the lack of explanation will be added and explained sequentially. The idea is explained with hypothetical numbers for the very difficult brain invention best engine invention and to explain the intention and expectation concretely clearly, but the correct answer is the hypothetical number of the theoretical best engine as an experimental number. It is not limited to. The idea that seems to be the best is duplicated in many applications, the idea is selected and used according to the application, and the claims are changed to be used according to the various applications.
図1の対向直列全動翼弾み車重力タービン8Kは、対向に全動翼弾み車重力タービン8F8Fを夫々対向直列垂直に限り無く多段に設けて、出力増大手段2Dを開放出力増大球Eの鋼球等比重大物質1cを落下し、空気抽出器51で真空にして、鋼球等比重大物質1cの出力増大球2E+真空中で重力加速度9.8m/毎秒毎秒の加速を、落差増大で出力増大効率良く利用し、選択したタービン翼断面4Xのタービン翼8c及び側板8dの、全動翼弾み車重力タービン8F径や加速距離を選択して回転数を1万回転以下に低減して、タービン翼8cに作用させる鋼球重量を、既存蒸気タービンの1.3万倍から10〜1000倍に低減するため、軸方向長は100〜500m等として多数に分割します。   The opposed series full blade impeller gravity turbine 8K shown in FIG. 1 is provided with all the movable blade pushwheel gravity turbines 8F8F facing the opposite series vertically in multiple stages, and the output increasing means 2D is a steel ball of an open output increasing sphere E or the like. Specific critical material 1c is dropped and vacuumed by air extractor 51. Sphere 2E is increased in output power of steel material, such as steel ball. The turbine blade 8c and the side plate 8d of the selected turbine blade cross section 4X are frequently used, and the total blade impeller gravity turbine 8F diameter and acceleration distance are selected and the rotational speed is reduced to 10,000 revolutions or less. In order to reduce the weight of steel balls to be applied from 13,000 times to 10 to 1000 times that of existing steam turbines, the axial length is divided into a large number such as 100 to 500 m.
両側に発電機や空気圧縮機の熱ポンプ1Gを駆動可能に具備して、タービン外箱77a内に最適間隔で具備し、磁気摩擦動機装置55・55等により同期して、対向無接触に適宜に接近又は噛合せて噴射質量に合せた強度大きさ間隔で多数設けて、タービン翼8c8cを夫々の円筒胴8e8eの外周軸方向半径方向に用途出力に合せて延長拡大し、出力発生タービン翼8cを1/10前後にし、対向直列や直列の全動翼弾み車重力タービン8Fタービン翼8cや出力増大球2Eに、被覆や潤滑油等の衝撃低減手段2Gを設けて衝撃を低減して、例えば鋼球を潤滑油や不燃液体と共に噴射して転がり接触の回転出力発生にし、落差1000m等に可能な限り増大燃料費0CO2排気0設備費最少として、既存蒸気タービン発電の1000倍発電量を狙います。   A heat pump 1G of a generator or an air compressor is provided on both sides so that it can be driven, and is provided in the turbine outer box 77a at an optimal interval, and is synchronized with the magnetic friction motor devices 55, 55, etc. so as not to contact each other. A plurality of turbine blades 8c8c are extended or enlarged in the radial direction of the outer peripheral axis of each cylindrical body 8e8e in accordance with the output of the power supply, and output generation turbine blades 8c are provided. Is reduced to about 1/10, and impact reduction means 2G such as a coating or lubricating oil is provided on the opposed series or series of all-wheel impeller gravity turbine 8F turbine blade 8c and output increasing sphere 2E to reduce the impact, for example, steel The ball is injected together with lubricating oil and non-combustible liquid to generate rolling contact rotation output. Increased as much as possible to a drop of 1000m, etc. Fuel cost 0CO2 Exhaust 0 Equipment cost is minimized 1000 times that of existing steam turbine power generation It aims for.
図2の直列全動翼弾み車重力タービン8Lは、全動翼弾み車重力タービン8Fを外箱垂直部94Aと平行垂直に限り無く多段に設けて、出力増大手段2Dを開放出力増大球Eの鋼球等比重大物質1cを落下して、空気抽出器51で真空にして重力加速度9.8m/毎秒毎秒加速落差増大で出力増大し、選択したタービン翼断面4Xのタービン翼8c及び測板8dの、全動翼弾み車重力タービン8F径を大径等として高速の回転数を1万回転等に低減して、タービン翼8cに作用させる鋼球重量を、既存蒸気タービンの1.3万倍大気圧同速度仕事率から5〜500倍に低減するため、軸方向長は200〜1000m等として多数に分割します。   2 is a steel ball of an open output increasing sphere E in which the all blade impeller gravity turbine 8F is provided in multiple stages without limitation in parallel and perpendicular to the outer casing vertical portion 94A. Equivalent critical material 1c is dropped, vacuumed by air extractor 51, and the output is increased by increasing the gravitational acceleration of 9.8 m / second and increasing the acceleration drop per second, and the turbine blade 8c and measuring plate 8d of the selected turbine blade cross section 4X, Reduce the high-speed rotation speed to 10,000 revolutions by setting the diameter of the all-wheel impeller gravity wheel gravity turbine 8F to be large, etc., and the weight of the steel ball acting on the turbine blade 8c is 13,000 times the atmospheric pressure of the existing steam turbine. In order to reduce the speed work factor to 5 to 500 times, the axial length is divided into a large number such as 200 to 1000 m.
両側に発電機や空気圧縮機の熱ポンプ1Gを駆動可能に具備して、タービン外箱77a内に最適間隔で具備して最適間隔で設けて、噴射質量に合せた強度大きさ間隔で多数設けて、タービン翼8cを円筒胴8eの外周軸方向半径方向に用途出力に合せて延長拡大して、出力発生タービン翼8cを1/10前後にし、全動翼弾み車重力タービン8Fタービン翼8cに衝撃低減手段2Gを設けて衝撃を低減して、転がり接触の回転出力発生にし、落差1000m等に可能な限り増大燃料費0CO2排気0設備費最少として、既存蒸気タービン発電の1000倍発電量を狙います。   A heat pump 1G of a generator or an air compressor can be driven on both sides, provided in the turbine outer box 77a at an optimal interval, and provided at an optimal interval, and provided at a number of strength magnitude intervals according to the injection mass. Then, the turbine blade 8c is extended and enlarged in the radial direction of the outer peripheral axial direction of the cylindrical body 8e in accordance with the application output, the output generating turbine blade 8c is reduced to about 1/10, and an impact is exerted on the turbine blade 8F turbine blade 8c. Reduction means 2G is provided to reduce impact and generate rotational output of rolling contact, increase as much as possible to a drop of 1000m, etc. As much as possible Fuel cost 0CO2 Exhaust 0 Equipment cost is aimed at 1000 times the amount of power generation of existing steam turbine power generation .
図3の図1図2側面図対向直列全動翼弾み車重力タービン8K乃至、直列全動翼弾み車重力タービン8Lは、全動翼弾み車重力タービン8Fを平行水平垂直に限り無く多段に設けて、出力増大手段2Dを開放出力増大球Eの鋼球等比重大物質1cを落下して真空中で重力加速度9.8m/毎秒毎秒を効率良く利用し、選択したタービン翼断面4Xの図1図2タービン翼8c及び測板8dの、全動翼弾み車重力タービン8F径を10m近い大径として、回転数を3千〜1万回転等に低減し、対向直列ではタービン翼8cに作用させる鋼球重量を、既存蒸気タービンの10〜1000倍等に増大して、軸方向長は100〜500m等長大として多数に分割し、両側に発電機1や熱ポンプ1G等を具備して、タービン外箱77a内に最適間隔で具備し、噴射質量に合せた強度大きさ間隔で多数設けて、タービン翼8cを円筒胴8eの外周軸方向半径方向に用途出力に合せて延長拡大し、全動翼弾み車重力タービン8Fタービン翼8cに衝撃低減手段2Gを設けて衝撃を低減して、転がり接触の回転出力発生にし、落差1000m以上等に増大します。   1 and 2 side view of FIG. 3, the opposed series full blade impeller gravity turbine 8K to the series full blade impeller gravity turbine 8L are provided with multistage impeller gravity turbines 8F in multiple stages without being limited to parallel horizontal and vertical, and output. The increasing means 2D drops the steel ball equivalent material 1c of the open output increasing sphere E and efficiently uses the gravitational acceleration of 9.8 m / second per second in the vacuum, and the selected turbine blade cross section 4X in FIG. The diameter of the rotor blade gravity wheel gravity turbine 8F of the blade 8c and the measuring plate 8d is set to a large diameter close to 10 m, the rotation speed is reduced to 3,000 to 10,000 rotations, and the weight of the steel ball acting on the turbine blade 8c in the opposed series is reduced. The axial length is increased to 10 to 1000 times that of the existing steam turbine, and the axial length is divided into a large number such as 100 to 500 m. The generator 1 and the heat pump 1G are provided on both sides, and the turbine outer box 77a With optimal spacing Many turbine blades 8c are provided in the radial direction of the outer circumference of the cylindrical body 8e in accordance with the application output, and are expanded and expanded in accordance with the output of the turbine blade 8c. Reducer 2G is provided to reduce impact and generate rotational output of rolling contact, increasing the drop to over 1000m.
図4噴射推進船舶駆動等熱量を必要とする用途では、図5図6の太陽光加熱器2や太陽熱増大吊橋2bを翼形にして水上を音速以下で安定飛行にし、夫々の空気管空気28aや内部空気28aを熱ポンプ1Gで吸入複数回圧縮熱回収して、最終圧縮熱回収冷却の過程で必要に応じて液体酸素の圧入燃料噴射燃焼熱交換冷却燃焼し、限り無く高圧燃焼熱交換冷却燃焼して、400〜540度400MPa等過熱蒸気50+150度400MPa等圧縮空気28aに分割保存使用とし、出力増大手段2D過熱蒸気制御弁25を開放、540度400MPa等過熱蒸気50爆発速度により出力増大球2Eを加速して、対向直列全動翼弾み車タービン8Kの全動翼弾み車水タービン8bを駆動し、合体機関燃焼部を駆動して噴射推進船舶駆動の場合は、150度400MPa等の圧縮空気を燃焼器に供給燃料噴射燃焼して、温度上昇の過程で外周400度等の過熱蒸気50を過熱して夫々最良噴射とし、空気吸引噴射では既存船舶の20倍速度狙いにします。   FIG. 4 Injecting propulsion ship drive and other applications that require heat, the solar heater 2 and the solar heat increase suspension bridge 2b of FIG. 5 and FIG. And the internal air 28a is sucked by the heat pump 1G and compressed heat is recovered several times, and the final compressed heat recovery cooling process is carried out as required by the liquid oxygen injection fuel injection combustion heat exchange cooling combustion, and the high pressure combustion heat exchange cooling is infinite Combusted and used as divided storage in compressed air 28a of superheated steam 50 + 150 ° 400MPa of 400 to 540 ° 400MPa, etc., and the output increasing means 2D superheated steam control valve 25 is opened. In the case of driving a propulsion vessel by driving 2E, driving the full blade impeller water turbine 8b of the opposed series full blade impeller turbine 8K and driving the combined engine combustion section Compressed air, such as 150 degrees 400 MPa, is supplied to the combustor, fuel is injected and burned, and the superheated steam 50, such as the outer periphery 400 degrees, is superheated in the course of the temperature rise to make the best injection, respectively. I will aim.
図4メタンハイドレート回収等温熱と冷熱を必要とする発電では、図5図6の太陽光加熱器2や太陽熱増大吊橋2bの、空気管空気28aや内部空気28aを熱ポンプ1Gで吸入複数回圧縮熱回収して、最終圧縮熱回収冷却の過程で液体酸素の圧入燃料噴射燃焼熱交換冷却燃焼し、限り無く高圧燃焼熱交換冷却燃焼して、100〜300度24MPa等高温水52b+40度400MPa等圧縮空気28aに分割保存使用とし、出力増大手段2D2D圧縮空気制御弁24A高温水制御弁25Bを開放、40度24MPa等高温水52bを水噴射ポンプ1Gで400MPa噴射として、その水速度と重力加速度と真空により出力増大球2Eを加速し、40度400MPa等圧縮空気28a膨張速度と重力加速度により出力増大球2Eを加速して、対向直列全動翼弾み車タービン8Kの全動翼弾み車水タービン8b+全動翼弾み車ガスタービン8aを駆動し、既存蒸気タービンの1000倍発電量狙いにして、100〜300度等の高温水52bをメタンハイドレートに注入メタンを回収し、全動翼弾み車ガスタービン8a排気温度を絶対0度に近付け、膨大な冷熱を回収してメタンを冷却液化して、安価氷の大量生産として都市部を氷冷却冷夏都市にする等、各種用途に使用します。   4 For power generation requiring isothermal heat and cold heat for methane hydrate recovery, the air pipe air 28a and the internal air 28a of the solar heater 2 and the solar thermal augmentation suspension bridge 2b of FIG. Compressed heat recovery, liquid oxygen injection fuel injection combustion heat exchange cooling combustion in the process of final compression heat recovery cooling, high pressure combustion heat exchange cooling combustion without limitation, high temperature water 52b + 40 degrees 400 MPa, etc. 100-300 degrees 24 MPa, etc. The compressed air 28a is divided and used for storage, the output increasing means 2D2D compressed air control valve 24A is opened, the high-temperature water control valve 25B is opened, and high-temperature water 52b such as 40 degrees and 24 MPa is injected by the water injection pump 1G to 400 MPa. The output increasing sphere 2E is accelerated by vacuum, and the output increasing sphere 2E is accelerated by the expansion velocity of 40 degrees 400MPa compressed air 28a and the gravitational acceleration. Drives all blade impeller water turbine 8b + opposite blade impeller gas turbine 8a of opposed series all blade impeller turbine 8K, and aims at 1000 times the power generation amount of existing steam turbine, and methane is used for high temperature water 52b such as 100 to 300 degrees. The methane injected into the hydrate is recovered, the exhaust temperature of the all-wheel impeller gas turbine 8a is brought close to 0 ° C, the huge amount of cold energy is recovered, the methane is cooled and liquefied, and the urban area is ice-cooled as mass production of inexpensive ice Used for various purposes such as making it a cold summer city.
図5の太陽光加熱器2は各種水面を利用して、発泡プラスチック等の断熱材2cを半筒外箱77Bで囲って半円等の長大な筒を設けて、その中に耐熱材2Aを設けて空気管空気28aを既存の熱吸収材2B含めて具備し、上部に複数等の幅広長大な長レンズ2dを継手80A+締付具80Bで密封真空断熱可能に設けて、長手方向には継手80Aで無限延長可能に、180度方向転換の場合は管端をU型管52Aで接続太陽光に直角維持回転する装置を設ける等とし、既存技術で真空等として断熱して太陽光を複数併設含む空気管空気28aに集中して、長レンズ2dの幅や長さ増大で空気28a温度を急速上昇し、1日で3日分温度上昇する等として、既存のレンズ断面全部を選択使用可能とし、選択したレンズ断面を直線状に延長して太陽光を直線状に集光して、レンズ材質全部を選択使用可能とし、半円長大筒状等の太陽光加熱器2を水上非常に僅少な動力で太陽光と直角方向に回転して、限り無く大量の空気管空気28aを燃料費0CO2排気0で高温として、内部空気28a+複数併設型を含む空気管空気28aは、熱ポンプ1Gで吸入複数回圧縮熱回収冷却複数回600〜1000度等として、図6圧縮熱回収器2Cで水52aを水温熱52dや過熱蒸気50にします。   The solar heater 2 in FIG. 5 uses various water surfaces, surrounds a heat insulating material 2c such as foamed plastic with a half-cylinder outer box 77B, and provides a long cylinder such as a semicircle, and includes a heat-resistant material 2A therein. Air tube air 28a including the existing heat absorbing material 2B is provided, and a plurality of wide and long long lenses 2d are provided on the upper part so as to be sealed and thermally insulated by the joint 80A + fastener 80B. 80A can be extended indefinitely, and in the case of 180 degree change of direction, the tube end is provided with a U-shaped tube 52A to maintain and rotate at right angles to the connected sunlight, etc. Concentrate on the air tube air 28a, and increase the width and length of the long lens 2d to rapidly increase the temperature of the air 28a and increase the temperature for three days in one day. , Extend the selected lens cross-section in a straight line Concentrate the light in a straight line, make it possible to select and use all the lens materials, and rotate the solar heater 2 such as a semi-circular large cylindrical shape in the direction perpendicular to the sunlight with very little power on the water. A large amount of air pipe air 28a is heated at a high fuel cost with 0CO2 exhaust gas, and the air pipe air 28a including the internal air 28a + multiple types is used as a heat pump 1G for multiple times of compression heat recovery cooling multiple times 600-1000 degrees, etc. , Fig. 6 The water 52a is converted into water temperature heat 52d and superheated steam 50 by the compression heat recovery unit 2C.
図6の太陽熱増大吊橋2b実施例5長レンズ2dは、前記と略同様に構成して複数を更に幅方向に締付具80Bで締付密封し、太陽光と直角に設けて吊具左2f吊具右2gの最上部で左右を上下に移動して、太陽熱増大吊橋2bを太陽光の移動方向に合せて傾斜太陽光との直角受光とし、複数の空気管空気28aに複数の長レンズ2dをセットで設けて、加熱温度に合せた長レンズ2dの幅で複数具備して断熱や焦点距離の短縮を可能にし、太陽熱増大吊橋2bを発泡プラスチック等の断熱材2cで構成保温して、落差を300〜1000mに増大の過程で複数の空気管空気28a温度を高温とし、内部空気28a+空気管空気28aは、熱ポンプ1Gで吸入複数回圧縮熱回収冷却複数回600〜1000度等として、図6圧縮熱回収器2Cで水52aを水温熱52dや過熱蒸気50にし、540度400MPa等の過熱蒸気50速度+重力加速度+真空で出力増大球2Eを加速して、対向直列全動翼弾み車タービン8K乃至直列全動翼弾み車タービン8Lを駆動し、空気力太陽光重力加速度発電として、空気力太陽光重力加速度発電蓄電池駆動の、各種自動車類全盛や各種船舶類全盛や全面電化住宅全盛にします。   6 is constructed in substantially the same manner as described above, and a plurality of lenses are further tightened and sealed with a fastener 80B in the width direction, and provided at a right angle to the sun light 2f. By moving right and left up and down at the uppermost part of the right 2g of the hanging tool, the solar thermal augmentation suspension bridge 2b is made to receive light at right angles to the inclined sunlight in accordance with the moving direction of sunlight, and a plurality of long lenses 2d on a plurality of air tube air 28a. Is provided as a set, and a plurality of long lenses 2d having a width corresponding to the heating temperature are provided so that heat insulation and focal length can be shortened. In the process of increasing the pressure to 300 to 1000 m, the temperature of the plurality of air pipe air 28a is increased, and the internal air 28a + air pipe air 28a is drawn by the heat pump 1G as multiple times of compression heat recovery cooling multiple times 600 to 1000 degrees, etc. 6 compression heat recovery unit 2C The water 52a is converted into water temperature heat 52d and superheated steam 50, the superheated steam 50 speed of 540 degrees 400MPa + gravity acceleration + vacuum accelerates the output increasing sphere 2E, and the opposed series full blade impeller turbine 8K through the series full blade impeller. The turbine 8L is driven, and as aerodynamic solar gravity acceleration power generation, aerodynamic solar gravity acceleration power storage battery drive, various types of automobiles, various types of ships, and full-scale electrified housing.
図6先の出願水熱交換器2Yの酸素量増大手段1B+燃料噴射弁7を使用し、圧縮熱回収器2Cとしても使用して、最終圧縮熱回収冷却の過程で液体酸素の圧入燃料噴射燃焼熱交換冷却燃焼し、限り無く高圧燃焼熱交換冷却燃焼して、100〜300度24MPa等高温水52b+40度400MPa等圧縮空気28aに分割保存使用とし、100〜300度24MPa高温水52bは図4タービン駆動の他に水温熱52dとして、メタンハイドレートに注入メタンを回収する等各種用途に使用し、業務用や家庭用の各種温水設備機器類や各種蒸留水製造設備類や各種温室類や各種暖房設備機器類や各種調理設備機器類や各種洗濯乾燥機類や各種食器洗い機類等を製造販売します。40度400MPa圧縮空気28a図4全動翼弾み車ガスタービン回転出力発生排気の過程で、絶対0度に近付く膨大な排気を圧縮空気冷熱52eとし、アルコール冷熱52eや氷冷熱52eとして熱交換貯蔵して、業務用や家庭用の各種冷凍設備機器類や各種冷蔵設備機器類や各種冷房設備機器類や各種製氷設備機器類や各種温熱冷熱配管ビル類等を製造販売運用し、安価氷の行列等で都市部を丸ごと冷却して、ヒートアイランド現象を逆転して冷夏都市にします。   6 uses the oxygen amount increasing means 1B + fuel injection valve 7 of the previous application water heat exchanger 2Y, and is also used as the compression heat recovery unit 2C, and injecting fuel injection combustion of liquid oxygen in the process of final compression heat recovery cooling Heat exchange cooling combustion, infinitely high pressure combustion heat exchange cooling combustion, 100 to 300 degrees 24 MPa high temperature water 52b + 40 degrees 400 MPa, etc. compressed air 28a is divided and used for storage, 100 to 300 degrees 24 MPa high temperature water 52b is a turbine shown in FIG. In addition to driving, water temperature heat 52d is used for various purposes such as recovering methane injected into methane hydrate, and various hot water equipment for business use and household use, various distilled water production equipment, various greenhouses and various heating systems. Manufactures and sells equipment, various cooking equipment, various washing and drying machines, and various dishwashers. 40 degree 400MPa compressed air 28a Fig. 4 All rotor blade bouncer gas turbine rotation output generation Exhaust exhaust gas approaching absolute 0 degree is compressed air cold heat 52e, and alcohol cold heat 52e and ice cold heat 52e are heat exchange stored. Manufacture and sell various types of commercial and household refrigeration equipment, various refrigeration equipment, various air conditioning equipment, various ice making equipment, various heating and cooling piping buildings, etc. Cool the whole city and reverse the heat island phenomenon to make it a cool summer city.
CO2排気0燃料費0の理論最良エンジン空気力太陽光重力加速度発電により、既存世界発電量の10倍発電量とし、非常に安価な空気力太陽光重力加速度発電蓄電池駆動や電気使用の、各種自動車類全盛や各種船舶類全盛や全面電化住宅全盛等にして、安価膨大な温熱利用によりメタンハイドレートやオイルサンドから燃料等を回収し、安価膨大な冷熱利用により都市部を氷冷却冷夏都市にして、地球温暖化防止する可能性があります。   CO2 exhaust 0 fuel cost 0 theory Best engine aerodynamic solar gravitational acceleration power generation, 10 times the existing world power generation, very cheap aerodynamic solar gravitational acceleration power generation Various types of automobiles driving and using electricity It is a prime for various types of ships, various types of ships, full-scale electrified houses, etc., recovering fuel from methane hydrate and oil sand by using a huge amount of cheap heat, and making an urban area an ice-cooled cold summer city by using a huge amount of cheap cold , May prevent global warming.
対向直列全動翼弾み車水タービン8K重力加速度利用の断面図(実施例1)Cross section of opposed series full blade impeller water turbine using 8K gravity acceleration (Example 1) 直列全動翼弾み車水タービン8Lで重力加速度利用の断面図(実施例2)Cross-sectional view of using gravity acceleration in series all blade impeller water turbine 8L (Example 2) 直列全動翼弾み車水タービン8K8L+発電機の説明図(実施例3)Explanatory drawing of serial all blade impeller water turbine 8K8L + generator (Example 3) 直列全動翼弾み車ガスタービン8K8L+発電機の説明図(実施例4)Explanatory drawing of serial all blade impeller gas turbine 8K8L + generator (Example 4) 太陽光加熱器2の説明図(実施例5)Explanatory drawing of the solar heater 2 (Example 5) 太陽熱増大吊橋2b+圧縮熱回収器2Cの説明図(実施例6)Explanatory drawing of solar heat increase suspension bridge 2b + compression heat recovery device 2C (Example 6)
符号の説明Explanation of symbols
1:発電機、 1A:水銀排気検査室、 1B:酸素量増大手段、 1C:アルコール冷熱、 1F:水ポンプ、 1G:熱ポンプ、 1H:揚水ポンプ、 1c:比重大物質、 2:太陽光加熱器(水面浮上長レンズ複数段で太陽光追跡) 2a:復水器、 2b:太陽熱増大吊橋(吊具左右を上下して長レンズ複数段で太陽光追跡) 2c:断熱材、 2d:長レンズ、 2e:水面、 2f:吊具左、 2g:吊具右、 2A:耐熱材、 2B:熱吸収材、 2C:圧縮熱回収器、 2D:出力増大手段、 2E:出力増大球、 2F:増大球上昇装置、 2G:衝撃低減手段、 2H:冷熱復水器、 2Y:水熱交換器、 3:摩擦損失低減手段(撥水作用や加熱高温手段等で摩擦損失を低減) 3A:撥水作用(水との摩擦損失低減手段) 3B:加熱高温手段(電気抵抗や電磁加熱等既存技術で高温にする) 3C:冷熱回収手段、 3G:撥水作用(水銀との摩擦損失低減手段) 4A:タービン翼断面(既存断面) 4B:タービン翼断面(出力面湾曲少断面) 4C:タービン翼断面(出力面直線断面) 4D:タービン翼断面(出力反対面直線断面) 4E:タービン翼断面(出力反対面湾曲少断面) 4F:タービン翼断面(既存の反対断面) 4X:タービン翼断面(4A〜4Fより選択断面) 5C:空気排気室、 6:ノズル、 6a:ノズル噴射部、 6b:ノズル噴射部、 6d:ノズル噴射部、 6z:水噴射ポンプ、 6F:圧縮空気噴射ノズル、 7:燃料噴射弁、 8a:全動翼弾み車ガスタービン(全動翼ガスタービン)、 8b:全動翼弾み車水タービン(全動翼水タービン)、 8c:タービン翼、 8d:側板、 8e:円筒胴、 8E:全動翼弾み車水銀タービン(全動翼水銀タービン)8F:全動翼弾み車重力タービン、 8K:対向直列全動翼弾み車タービン(対向直列全動翼弾み車水銀タービン対向直列全動翼弾み車水タービン対向直列全動翼弾み車ガスタービン対向直列全動翼弾み車重力タービン)、 8L:直列全動翼弾み車タービン(直列全動翼弾み車水銀タービン直列全動翼弾み車水タービン直列全動翼弾み車ガスタービン直列全動翼弾み車重力タービン)、 11A:隔壁、 11B:水室 11C:空気室、 24A:圧縮空気制御弁、 25:過熱蒸気制御弁、 25B:高温水制御弁、 28a:空気、 28a:内部空気、 28a:空気管空気、 28b:圧縮空気熱量、 49:燃焼ガス、 49B:煙突燃焼ガス熱量、 49C:工場使用熱量、 50:過熱蒸気、 51:空気抽出器、 52a:水、 52b:水(太陽光で温度が変る水) 52b:高温水、 52d:温熱、 52d:水温熱、 52d:過熱蒸気温熱、 52e:冷熱、 52e:水冷熱、 52e:圧縮空気冷熱、 52e:アルコール冷熱、 52e:氷冷熱、 77B:半筒外箱、 77a:タービン外箱、 80A:継手、 80B:締付具、 81:支軸、 81a:支点、 94A:外箱垂直部、 95:高温水溜、 95b:圧縮空気溜、 103:冷熱回収器、   DESCRIPTION OF SYMBOLS 1: Generator, 1A: Mercury exhaust test room, 1B: Oxygen amount increasing means, 1C: Alcohol cold heat, 1F: Water pump, 1G: Heat pump, 1H: Pumping pump, 1c: Specific critical substance, 2: Solar heating 2a: Condenser, 2b: Solar heat increasing suspension bridge (tracking sunlight with multiple long lenses by moving up and down the left and right sides) 2c: Thermal insulation, 2d: Long lens 2e: water surface, 2f: hanger left, 2g: hanger right, 2A: heat-resistant material, 2B: heat absorbing material, 2C: compression heat recovery device, 2D: output increasing means, 2E: output increasing ball, 2F: increasing Ball lifting device, 2G: impact reducing means, 2H: cold condenser, 2Y: hydrothermal exchanger, 3: friction loss reducing means (reducing friction loss by water repellent action, heating high temperature means, etc.) 3A: water repellent action (Friction loss reducing means with water) 3B: High temperature means (high temperature by existing technology such as electric resistance and electromagnetic heating) 3C: Cold heat recovery means, 3G: Water repellent action (means for reducing friction loss with mercury) 4A: Turbine blade cross section (existing cross section) 4B: Turbine blade cross section 4C: Turbine blade cross section (output surface straight cross section) 4D: Turbine blade cross section (output opposite surface straight cross section) 4E: Turbine blade cross section (output opposite surface curved small cross section) 4F: Turbine blade cross section (existing) 4X: Turbine blade cross section (selected cross section from 4A to 4F) 5C: Air exhaust chamber, 6: Nozzle, 6a: Nozzle injection section, 6b: Nozzle injection section, 6d: Nozzle injection section, 6z: Water injection pump 6F: Compressed air injection nozzle, 7: Fuel injection valve, 8a: Full blade impeller gas turbine (full blade gas turbine), 8b: Full blade impeller water turbine (full blade water turbine) 8c: Turbine blades, 8d: Side plate, 8e: Cylindrical barrel, 8E: Full bucket vane mercury turbine (full bucket mercury turbine) 8F: Full bucket vane gravity turbine, 8K: Opposite series full bucket vane turbine (Opposite series full blade propeller mercury turbine opposed series full bucket pusher water turbine opposed series full bucket propeller gas turbine opposed series full bucket propeller gravity turbine), 8L: series full bucket fullwheel turbine (series full bucket flywheel mercury) Turbine series full blade impeller water turbine series full blade impeller gas turbine series full blade impeller gravity turbine), 11A: partition wall, 11B: water chamber, 11C: air chamber, 24A: compressed air control valve, 25: superheated steam control valve 25B: High-temperature water control valve, 28a: Air, 28a: Internal air, 28a: Air pipe air, 28b: Compressed air calorie, 49: Combustion Gas, 49B: calorific value of chimney combustion gas, 49C: calorific value for factory use, 50: superheated steam, 51: air extractor, 52a: water, 52b: water (water whose temperature changes due to sunlight) 52b: hot water, 52d: heat 52d: Water heat / heat 52d: Superheated steam heat / heat 52e: Cool heat 52e: Water heat / cool 52e: Compressed air heat / heat 52e: Cold alcohol / heat 52e: Ice heat / cooling 77B: Outer cylinder box 77a: Turbine outer box, 80A: Joint, 80B: Fastening tool, 81: Support shaft, 81a: Support point, 94A: Outer box vertical part, 95: Hot water reservoir, 95b: Compressed air reservoir, 103: Cold recovery device,

Claims (5000)

  1. 理論最良エンジン空気力太陽光重力加速度発電燃料費0CO2排気0で発電量温熱量冷熱量増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Fuel Cost 0CO2 Exhaust 0 Power Generation Amount of Heat Heat Amount of Cold Heat + Accelerating Output Increase Sphere (2E) with Impact Reduction Means (2G) + Gravity Acceleration Downward Vertically Various energy conservation cycle coalescing engines with a method of increasing the power generation amount by increasing the width of the long lens (2d) for accelerating + dividing fastener (80B).
  2. 理論最良エンジン空気力太陽光重力加速度発電燃料費0CO2排気0で発電量温熱量冷熱量増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Fuel Cost 0CO2 Exhaust 0 Power Generation Amount of Heat Heat Amount of Cold Heat + Accelerating Output Increase Sphere (2E) with Impact Reduction Means (2G) + Gravity Acceleration Downward Vertically Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of a plurality of long lenses (2d) for accelerating + dividing and fastening fasteners (80B).
  3. 理論最良エンジン空気力太陽光重力加速度発電燃料費0CO2排気0で発電量温熱量冷熱量増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Fuel Cost 0CO2 Exhaust 0 Power Generation Amount of Heat Heat Amount of Cold Heat + Accelerating Output Increase Sphere (2E) with Impact Reduction Means (2G) + Gravity Acceleration Downward Vertically Accelerating + Combined engine of various energy conservation cycles with a long production length lens (2d) selected from existing materials and a method of increasing power generation.
  4. 理論最良エンジン空気力太陽光重力加速度発電燃料費0CO2排気0で発電量温熱量冷熱量増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Fuel Cost 0CO2 Exhaust 0 Power Generation Amount of Heat Heat Amount of Cold Heat + Accelerating Output Increase Sphere (2E) with Impact Reduction Means (2G) + Gravity Acceleration Downward Vertically Accelerating + Combined engine with various energy storage cycles that uses a method to increase the amount of concentrated power generation in the air tube air (28a) by using a lens (2d) with a long section (2d).
  5. 理論最良エンジン空気力太陽光重力加速度発電燃料費0CO2排気0で発電量温熱量冷熱量増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Fuel Cost 0CO2 Exhaust 0 Power Generation Amount of Heat Heat Amount of Cold Heat + Accelerating Output Increase Sphere (2E) with Impact Reduction Means (2G) + Gravity Acceleration Downward Vertically Various energy conservation cycle coalescing engines with a method of increasing power generation by maintaining heat-insulated long lens (2d) and sunlight in the vicinity of a right angle near the acceleration + vacuum.
  6. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerating the increased output sphere (2E) + Accelerating the gravitational acceleration + Accelerating vertically downward + Increasing the width of the long lens (2d) for tightening the split fastener (80B) Cycle coalescence engine.
  7. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerating the increased output sphere (2E) + Accelerating the gravitational acceleration vertically downward + Dividing and providing a set of multiple long lenses (2d) for fastening the fastener (80B) Energy conservation cycle coalescence engine.
  8. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerating the increased output sphere (2E) + Accelerating the gravitational acceleration vertically + Combined various energy storage cycle engines using a method of increasing the power generation amount by making the selected production length lens (2d) long from existing materials.
  9. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerate the output increase sphere (2E) + Accelerate gravitational acceleration vertically + Various types of methods for increasing the amount of concentrated power generation from the existing lens cross section to the air tube air (28a) with the selected cross section long lens (2d) Energy conservation cycle coalescence engine.
  10. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerate the output increase sphere (2E) + Accelerate gravitational acceleration vertically + Various types of methods to increase power generation by maintaining heat insulation long lens (2d) and sunlight near right angle in the part close to vacuum Energy conservation cycle coalescence engine.
  11. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerating the increased output sphere (2E) + Accelerating the gravitational acceleration + Accelerating vertically downward + Increasing the width of the long lens (2d) for tightening the split fastener (80B) Cycle coalescence engine.
  12. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerating the increased output sphere (2E) + Accelerating the gravitational acceleration vertically downward + Dividing and providing a set of multiple long lenses (2d) for fastening the fastener (80B) Energy conservation cycle coalescence engine.
  13. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerating the increased output sphere (2E) + Accelerating the gravitational acceleration vertically + Combined various energy storage cycle engines using a method of increasing the power generation amount by making the selected production length lens (2d) long from existing materials.
  14. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerate the output increase sphere (2E) + Accelerate gravitational acceleration vertically + Various types of methods for increasing the amount of concentrated power generation from the existing lens cross section to the air tube air (28a) with the selected cross section long lens (2d) Energy conservation cycle coalescence engine.
  15. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて水銀を垂直下方に加速する構造や方法+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate mercury vertically downward + solar heater (2) rotated perpendicular to sunlight + impact reduction means (2G) Accelerate the output increase sphere (2E) + Accelerate gravitational acceleration vertically + Various types of methods to increase power generation by maintaining heat insulation long lens (2d) and sunlight near right angle in the part close to vacuum Energy conservation cycle coalescence engine.
  16. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and Methods to Accelerate Coated Mercury Down Vertically + Make Battery-powered Various Ships Prime + Solar Heater (2) in Right Angle Direction of Sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration + Accelerating vertically downward + Dividing fastener (80B) Tightening long lens (2d) width Combined with various energy storage cycle engines that have increased power generation.
  17. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and Methods to Accelerate Coated Mercury Down Vertically + Make Battery-powered Various Ships Prime + Solar Heater (2) in Right Angle Direction of Sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Dividing and setting multiple length lens (2d) tightening clamp (80B) Various energy storage cycle coalescing engines that were installed in the plant and used as a method for increasing power generation.
  18. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and Methods to Accelerate Coated Mercury Down Vertically + Make Battery-powered Various Ships Prime + Solar Heater (2) in Right Angle Direction of Sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select from existing materials Various lengthening method of production length lens (2d) to increase power generation amount Energy conservation cycle coalescence engine.
  19. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and Methods to Accelerate Coated Mercury Down Vertically + Make Battery-powered Various Ships Prime + Solar Heater (2) in Right Angle Direction of Sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select the long lens (2d) from the cross section of the existing lens and sunlight through air tube air (28a) ) Various energy storage cycle coalescing engines that use the method of increasing the amount of concentrated power generation.
  20. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and Methods to Accelerate Coated Mercury Down Vertically + Make Battery-powered Various Ships Prime + Solar Heater (2) in Right Angle Direction of Sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Heat insulation long lens (2d) and sunlight near right angle Various energy storage cycle coalescing engines that maintain and increase power generation.
  21. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat recovery + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically + Increase width of long lens (2d) for split clamp (80B) tightening Various energy storage cycle coalescing engines that are used to increase power generation.
  22. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the covered mercury vertically downward + battery powered by various vessels + air pipe air (28a) internal air (28a) heat Compressive heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens for tightening split clamp (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of 2d).
  23. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Various Battery Drives + Air Tube Air (28a) Internal Air (28a) Compression Heat By heating the water (52b) with the compression heat recovery unit (2C) + accelerating the output increasing sphere (2E) provided with the impact reducing means (2G) + accelerating the gravitational acceleration vertically downward + split fastener (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  24. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating the storage battery-powered ships + air tube air (28a) compression of internal air (28a) Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Tightening of split fastener (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  25. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Battery Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the split fastener (80B) is increased to increase the power generation amount.
  26. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Split multiple length lens (2d) tightened with clamp (80B) Various energy storage cycle coalescing engines provided as a set to increase power generation.
  27. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the covered mercury vertically downward + battery powered by various vessels + air pipe air (28a) internal air (28a) heat Compressing heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing multiple fasteners (80B) Various energy storage cycle coalescing engines with a long lens (2d) as a set to increase power generation.
  28. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Various Battery Drives + Air Tube Air (28a) Internal Air (28a) Compression Heat Heating the water (52b) with the compression heat recovery unit (2C) + accelerating the output increasing sphere (2E) provided with the impact reducing means (2G) + accelerating the gravitational acceleration downward + dividing and fastening (80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  29. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating the storage battery-powered ships + air tube air (28a) compression of internal air (28a) Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration additionally vertically downward + Clamping tool (80B) Various energy storage cycle coalescing engines that use a set of tightening multiple long lenses (2d) as a set to increase power generation.
  30. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Battery Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines that are divided and provided with a plurality of long lenses (2d) tightened with a fastener (80B) as a set to increase the amount of power generation.
  31. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat recovery + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select from existing material Long production lens (2d) is long, and increase power generation method Various energy conservation cycle coalescence engine.
  32. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the covered mercury vertically downward + battery powered by various vessels + air pipe air (28a) internal air (28a) heat Compressed heat recovery with pump (1G) + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Select from existing material Long lens (2d) is made long Various energy storage cycle coalescing engines with increased power generation.
  33. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Various Battery Drives + Air Tube Air (28a) Internal Air (28a) Compression Heat Heating water (52b) with compression heat recovery unit (2C) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select manufacturing length from existing materials Various energy storage cycle coalescing engines with a long lens (2d) and a method of increasing power generation.
  34. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating the storage battery-powered ships + air tube air (28a) compression of internal air (28a) Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long lens (2d) ) Is an energy storage cycle coalescence engine with a method of increasing power generation.
  35. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Battery Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines with a method of increasing power generation by selecting a long lens (2d) as a selected production length from existing materials.
  36. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select pipe length from existing lens cross section long lens (2d) to air pipe air ( 28a) Various energy storage cycle coalescing engines as a method for increasing the amount of concentrated power generation.
  37. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the covered mercury vertically downward + battery powered by various vessels + air pipe air (28a) internal air (28a) heat Compressive heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select section long lens (2d) from the existing lens section Sun Various energy storage cycle coalescing engine that uses light as air tube air (28a) to increase concentrated power generation.
  38. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Various Battery Drives + Air Tube Air (28a) Internal Air (28a) Compression Heat Heating water (52b) with compression heat recovery unit (2C) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Select cross section from existing lens cross section Various energy storage cycle coalescing engines that use a long lens (2d) to increase sunlight concentration into air tube air (28a).
  39. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating the storage battery-powered ships + air tube air (28a) compression of internal air (28a) Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-sectional length lens from existing lens cross section ( 2d) Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase the amount of concentrated power generation.
  40. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Battery Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines using a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long lens (2d) selected from the existing lens cross section.
  41. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat recovery + Accelerate output augmenting sphere (2E) with impact reduction means (2G) + Add gravitational acceleration vertically downward + Heat insulation long lens (2d) and sunlight near right angle Various energy conservation cycle coalescing engines that are maintained in the above and used as a method for increasing power generation.
  42. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the covered mercury vertically downward + battery powered by various vessels + air pipe air (28a) internal air (28a) heat Compressed heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens (2d) for heat insulation in the part close to vacuum And various energy conservation cycle coalescence engines that maintain solar power near right angles and increase power generation.
  43. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Various Battery Drives + Air Tube Air (28a) Internal Air (28a) Compression Heat By heating the water (52b) with the compression heat recovery unit (2C) + accelerating the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerating the gravitational acceleration vertically downward + at the part close to the vacuum Various energy storage cycle coalescence engine that uses a heat insulating long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  44. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating the storage battery-powered ships + air tube air (28a) compression of internal air (28a) Heating water (52b) with air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Length of heat insulation in the part close to vacuum Various energy storage cycle coalescing engines that maintain the lens (2d) and sunlight in the vicinity of a right angle and increase the power generation amount.
  45. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Battery Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy conservation cycle coalescence engines that use a heat insulating long lens (2d) and sunlight in the vicinity of a right angle in the vicinity of vacuum to increase power generation.
  46. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Various energy conservation cycle coalescing engines that use heat recovery + accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravitational acceleration vertically downward.
  47. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the covered mercury vertically downward + battery powered by various vessels + air pipe air (28a) internal air (28a) heat Various energy storage cycle coalescence engines that use a power generation method that accelerates the output increasing sphere (2E) provided with compression heat recovery + impact reduction means (2G) by the pump (1G) + acceleration of gravitational acceleration vertically downward.
  48. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Various Battery Drives + Air Tube Air (28a) Internal Air (28a) Compression Heat Heating water (52b) with compression heat recovery unit (2C) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Various energy as a power generation method for accelerating gravitational acceleration downward vertically Conservation cycle coalescence organization.
  49. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating the storage battery-powered ships + air tube air (28a) compression of internal air (28a) Heating water (52b) with air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Combined with various energy conservation cycles as a power generation method for accelerating gravitational acceleration vertically downward organ.
  50. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Battery Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward Various energy storage cycle coalescing engines as power generation methods.
  51. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Pumping Pump (1H) Increase Ball Drop Device (2F) + Impact Reduction Means (2G) Accelerate the output increasing sphere (2E) provided with + Accelerate gravitational acceleration vertically + Various types of methods for increasing power generation by increasing the width of the long lens (2d) for tightening the split fastener (80B) Energy conservation cycle coalescence engine.
  52. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Pumping Pump (1H) Increase Ball Drop Device (2F) + Impact Reduction Means (2G) A method for increasing the amount of power generation by accelerating the output increasing sphere (2E) provided with + acceleration of gravitational acceleration vertically downward and dividing and providing a plurality of long lenses (2d) for fastening the fastener (80B) as a set; Various energy conservation cycle coalescence engine.
  53. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Pumping Pump (1H) Increase Ball Drop Device (2F) + Impact Reduction Means (2G) Accelerating output increasing sphere (2E) provided with + acceleration of gravitational acceleration vertically downward + selection of existing materials to make long production lens (2d) long and various energy storage cycle coalescing engine.
  54. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Pumping Pump (1H) Increase Ball Drop Device (2F) + Impact Reduction Means (2G) Accelerate the output increasing sphere (2E) provided with + Accelerate gravitational acceleration vertically downward + Concentrated power generation method for increasing sunlight into air tube air (28a) with a cross-section long lens (2d) from the existing lens cross section and Various energy conservation cycle coalescence engine.
  55. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Pumping Pump (1H) Increase Ball Drop Device (2F) + Impact Reduction Means (2G) Accelerating the output increasing sphere (2E) provided with + Accelerating gravitational acceleration vertically downward + Insulating long lens (2d) and sunlight in the vicinity of the right angle in the vicinity of the vacuum and increasing the amount of power generation Various energy conservation cycle coalescence engine.
  56. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structure and Method to Accelerate Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Impact Reduction Means Accelerating output increasing sphere (2E) provided with (2G) + Accelerating gravity acceleration vertically downward + Increasing the width of long lens (2d) for tightening split fastener (80B) to increase power generation amount Various energy conservation cycle coalescing engines.
  57. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structure and Method to Accelerate Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Impact Reduction Means Accelerate the output increasing sphere (2E) provided with (2G) + Accelerate gravity acceleration vertically downward + Divide and provide a set of multiple long lenses (2d) for fastening the fastener (80B) to generate power Various energy conservation cycle coalescing engine as an increase method.
  58. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structure and Method to Accelerate Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Impact Reduction Means Accelerating the power increasing sphere (2E) provided with (2G) + Accelerating gravity acceleration vertically downward + Various energy conservation cycle coalescing engines using a method of increasing the power generation by making the long lens (2d) selected from existing materials long .
  59. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structure and Method to Accelerate Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Impact Reduction Means Accelerate the output increasing sphere (2E) provided with (2G) + Accelerate gravity acceleration vertically downward + Concentrated power generation from sunlight to air tube air (28a) with a cross-section long lens (2d) from existing lens cross section Various energy conservation cycle coalescing engine as an increase method.
  60. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structure and Method to Accelerate Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Impact Reduction Means Accelerate the output increasing sphere (2E) provided with (2G) + Accelerate gravitational acceleration vertically + Keep heat-insulated long lens (2d) and sunlight near right angle in the part close to vacuum Various energy conservation cycle coalescing engine as an increase method.
  61. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Electricity Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) that is long with joint (80A) Accelerate output increase sphere (2E) + Gravity acceleration Various energy storage cycle coalescing engines that increase the power generation amount by increasing the width of the long lens (2d) for vertically accelerating and dividing the fastener (80B).
  62. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Electricity Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) that is long with joint (80A) Accelerate output increase sphere (2E) + Gravity acceleration Additional energy storage cycle coalescing engine with a method of increasing power generation by accelerating + dividing vertically and dividing and providing a set of multiple long lenses (2d) for tightening the fastener (80B).
  63. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Electricity Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) that is long with joint (80A) Accelerate output increase sphere (2E) + Gravity acceleration Accelerating vertically downward + Select from existing materials Long production lens (2d) is used as a method for increasing the amount of power generation.
  64. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Electricity Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) that is long with joint (80A) Accelerate output increase sphere (2E) + Gravity acceleration Accelerating vertically downward + Various energy storage cycle coalescence engine using a method of increasing the amount of concentrated power generation in the air tube air (28a) with the long lens (2d) selected from the cross section of the existing lens.
  65. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Electricity Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) that is long with joint (80A) Accelerate output increase sphere (2E) + Gravity acceleration Accelerating vertically downward + Long-heat-insulated lens (2d) in the part approaching the vacuum and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase power generation.
  66. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや出力増大球(2E)を加速タービン駆動する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Generator Turbine is installed in multiple stages to accelerate specific critical materials vertically and vertically + long lens and output augmenting sphere (2E) that enable vacuuming with fasteners (80B) Accelerated turbine drive + Gravity acceleration added vertically downward + Divided fastener (80B) tightening The long lens (2d) tightened to increase the width of the various energy storage cycle coalescence engine.
  67. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや出力増大球(2E)を加速タービン駆動する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Generator Turbine is installed in multiple stages to accelerate specific critical materials vertically and vertically + long lens and output augmenting sphere (2E) that enable vacuuming with fasteners (80B) Accelerated turbine drive + Accelerating gravity acceleration + Vertically downward + Dividing various energy storage cycle coalescing engines with a plurality of long lenses (2d) tightened with a fastener (80B) as a set to increase power generation.
  68. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや出力増大球(2E)を加速タービン駆動する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Generator Turbine is installed in multiple stages to accelerate specific critical materials vertically and vertically + long lens and output augmenting sphere (2E) that enable vacuuming with fasteners (80B) Accelerated turbine drive + Gravity acceleration added vertically downward + Select from existing materials Long production length lens (2d) is used to increase the power generation amount Various energy storage cycle coalescence engine.
  69. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや出力増大球(2E)を加速タービン駆動する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Generator Turbine is installed in multiple stages to accelerate specific critical materials vertically and vertically + long lens and output augmenting sphere (2E) that enable vacuuming with fasteners (80B) Acceleration turbine drive + Gravity acceleration added vertically downward + Various energy conservation cycle coalescence engine using solar power to air tube air (28a) with a long section (2d) selected from existing lens cross section.
  70. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや出力増大球(2E)を加速タービン駆動する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Generator Turbine is installed in multiple stages to accelerate specific critical materials vertically and vertically + long lens and output augmenting sphere (2E) that enable vacuuming with fasteners (80B) Accelerated turbine drive + Accelerating gravity acceleration vertically + Combined engine of various energy conservation cycles with a heat insulating long lens (2d) and sunlight kept near right angle in the part close to the vacuum to increase power generation.
  71. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and methods for accelerating the coverage ratio of critical substances vertically downward + Making the entire electrified house primed + Power increasing sphere with impact reduction means (2G) ( 2E) + Accelerating gravity acceleration Accelerating vertically downward + Increasing the width of the long lens (2d) for tightening the split fastener (80B) to increase the amount of power generation and combining various energy storage cycles.
  72. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and methods for accelerating the coverage ratio of critical substances vertically downward + Making the entire electrified house primed + Power increasing sphere with impact reduction means (2G) ( 2E) + Accelerating gravity acceleration + Accelerating vertically downward + Dividing and providing a set of multiple long lenses (2d) for tightening the fastener (80B) and using various energy storage cycle coalescence engines as a method for increasing power generation .
  73. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and methods for accelerating the coverage ratio of critical substances vertically downward + Making the entire electrified house primed + Power increasing sphere with impact reduction means (2G) ( 2E) + Accelerating gravity acceleration + Accelerating vertically downward + Select from existing materials Long production lens (2d) is long and various energy storage cycle coalescing engines with increased power generation method.
  74. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and methods for accelerating the coverage ratio of critical substances vertically downward + Making the entire electrified house primed + Power increasing sphere with impact reduction means (2G) ( 2E) + Gravity acceleration added vertically downward + Various energy conservation cycle coalescence engines using a method of increasing the concentrated power generation amount to the air tube air (28a) with the lens (2d) selected from the cross section of the existing lens .
  75. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Accelerating Turbine Structures and methods for accelerating the coverage ratio of critical substances vertically downward + Making the entire electrified house primed + Power increasing sphere with impact reduction means (2G) ( 2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Various energy conservation cycle coalescence engines with heat-insulating long lens (2d) and sunlight kept near right angle in the part close to vacuum .
  76. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Increase Sphere (2E) Accelerating vertically downward with compressed air velocity + Putting battery-powered cars into full swing + Increased output with impact reduction means (2G) Accelerating the sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Various energy storage cycle coalescing engine using a method of increasing the power generation amount by increasing the width of the long lens (2d) tightening the split fastener (80B) .
  77. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Increase Sphere (2E) Accelerating vertically downward with compressed air velocity + Putting battery-powered cars into full swing + Increased output with impact reduction means (2G) Accelerating the sphere (2E) + Accelerating gravitational acceleration vertically + Dividing and providing a set of multiple long lenses (2d) for fastening the fastener (80B), and various energy conservation cycles using a method for increasing power generation Combined organization.
  78. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Increase Sphere (2E) Accelerating vertically downward with compressed air velocity + Putting battery-powered cars into full swing + Increased output with impact reduction means (2G) Accelerating the sphere (2E) + Accelerating gravity acceleration vertically downward + Select from existing materials The long lens (2d) is made long, and various energy storage cycle coalescing engines using a method of increasing power generation.
  79. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Increase Sphere (2E) Accelerating vertically downward with compressed air velocity + Putting battery-powered cars into full swing + Increased output with impact reduction means (2G) Accelerate the sphere (2E) + Accelerate gravitational acceleration + Accelerate downward vertically + Various energy storage cycles using the existing lens cross-section with a selected cross-section long lens (2d) to increase solar energy into the air tube air (28a) Combined organization.
  80. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Increase Sphere (2E) Accelerating vertically downward with compressed air velocity + Putting battery-powered cars into full swing + Increased output with impact reduction means (2G) Accelerating the sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Various energy conservation cycles using a heat insulating long lens (2d) and sunlight in the vicinity of a right angle near the vacuum to increase power generation Combined organization.
  81. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated steel ball vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + solar heating Rotating the container (2) in the direction perpendicular to the sunlight + Accelerating the output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Split clamp (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  82. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated steel ball vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + solar heating Rotating the container (2) in the direction perpendicular to the sunlight + Accelerating the output increasing sphere (2E) provided with the impact reduction means (2G) + Accelerating the gravitational acceleration vertically + Dividing and tightening the clamp (80B) Various energy storage cycle coalescing engines with a plurality of long lenses (2d) attached as a set to increase power generation.
  83. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated steel ball vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + solar heating Rotating vessel (2) in the direction perpendicular to sunlight + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long lens (2d) Various energy storage cycle coalescing engine with a long and large power generation method.
  84. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated steel ball vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + solar heating Rotating the container (2) in the direction perpendicular to the sunlight + Accelerating the output increasing sphere (2E) provided with the impact reducing means (2G) + Accelerating the gravitational acceleration vertically + Select the long lens (2d) from the existing lens cross section ) Various energy conservation cycle coalescence engines that use sunlight as air tube air (28a) to increase the amount of concentrated power generation.
  85. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated steel ball vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + solar heating Rotating vessel (2) perpendicular to sunlight + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens for heat insulation in the part close to vacuum (2d) and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase the power generation amount.
  86. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) with solar joint (2) + impact reduction means 2G) to increase the output increasing sphere (2E) + acceleration of gravitational acceleration vertically downward + increase the width of the long lens (2d) of the split fastener (80B) and Various energy conservation cycle coalescence engine.
  87. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) with solar joint (2) + impact reduction means Accelerate the output increasing sphere (2E) provided with 2G) + Accelerate gravity acceleration vertically downward + Divide and provide multiple sets of lenses (2d) tightened with fasteners (80B) to increase power generation Various energy conservation cycle coalescence engine as a method.
  88. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) with solar joint (2) + impact reduction means 2G) Accelerating the power increasing sphere (2E) + Accelerating gravity acceleration vertically downward + Various energy conservation cycle coalescence engine with a method of increasing the power generation by lengthening the selected production length lens (2d) from existing materials.
  89. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) with solar joint (2) + impact reduction means 2G) Accelerating the power increasing sphere (2E) + Accelerating gravity acceleration vertically downward + Increasing the amount of concentrated power generation from the existing lens cross-section to the air tube air (28a) with the selected cross-section long lens (2d) Various energy conservation cycle coalescence engine as a method.
  90. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Generation Equipment method that makes turbine blades around 1/10 + Solar thermal increase suspension bridge (2b) with solar joint (2) + impact reduction means 2G) Accelerates the power increasing sphere (2E) + Accelerates gravitational acceleration vertically + Increases the amount of power generation by keeping the heat insulating long lens (2d) and sunlight in the vicinity of a right angle near the vacuum Various energy conservation cycle coalescence engine as a method.
  91. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Accelerate the output increasing sphere (2E) provided with the solar heater (2) + impact reduction means (2G) + accelerate the gravitational acceleration vertically + long lens for fastening the split fastener (80B) Various energy storage cycle coalescing engines that increase the width of (2d) and increase the power generation amount.
  92. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Accelerate the output heating sphere (2E) provided with the solar heater (2) + impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + divide and tighten the fastener (80B) Various energy storage cycle coalescing engines that use a set of multiple long lenses (2d) to increase power generation.
  93. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select production length lens (2d) from existing material is long Various energy storage cycle coalescing engines as a method of increasing power generation.
  94. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downwards) 2b) Accelerate the output heating sphere (2E) provided with the solar heater (2) + impact reducing means (2G) + accelerate the gravitational acceleration vertically downward + select the long lens (2d) from the existing lens cross section Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase the amount of concentrated power generation.
  95. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downwards) 2b) Accelerate the output heating sphere (2E) provided with the solar heater (2) + impact reducing means (2G) + accelerate the gravitational acceleration vertically downward + insulation long lens (2d) near the vacuum ) And various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  96. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + solar heater (2) perpendicular to sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration + Accelerating vertically downward + Dividing fastener (80B) Tightening long lens (2d) width Combined with various energy storage cycle engines that have increased power generation.
  97. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + solar heater (2) perpendicular to sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Dividing and setting multiple length lens (2d) tightening clamp (80B) Various energy storage cycle coalescing engines that were installed in the plant and used as a method for increasing power generation.
  98. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + solar heater (2) perpendicular to sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select from existing materials Various lengthening method of production length lens (2d) to increase power generation amount Energy conservation cycle coalescence engine.
  99. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + solar heater (2) perpendicular to sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select the long lens (2d) from the cross section of the existing lens and sunlight through air tube air (28a) ) Various energy storage cycle coalescing engines that use the method of increasing the amount of concentrated power generation.
  100. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + solar heater (2) perpendicular to sunlight Rotating + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Heat insulation long lens (2d) and sunlight near right angle Various energy storage cycle coalescing engines that maintain and increase power generation.
  101. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Accelerates vertically downward at the compressed air speed + Makes all kinds of battery-powered cars + Solar heater (2) perpendicular to sunlight Rotate in the direction + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Add gravity acceleration Accelerate vertically downward + Increase the width of the long lens (2d) for tightening the split fastener (80B) Various energy storage cycle coalescing engines that have been increased to increase power generation.
  102. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Accelerates vertically downward at the compressed air speed + Makes all kinds of battery-powered cars + Solar heater (2) perpendicular to sunlight Rotate in the direction + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate the gravitational acceleration vertically downward + Divide and clamp the clamp (80B) Multiple length lens (2d) Various energy conservation cycle coalescing engines that are used as a method of increasing power generation by providing a set of
  103. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Accelerates vertically downward at the compressed air speed + Makes all kinds of battery-powered cars + Solar heater (2) perpendicular to sunlight Rotating in the direction + Accelerating the output increasing sphere (2E) provided with the impact reducing means (2G) + Accelerating the gravitational acceleration vertically + Selecting the existing material from the existing long lens (2d) and increasing the power generation amount Various energy conservation cycle coalescence engine.
  104. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Accelerates vertically downward at the compressed air speed + Makes all kinds of battery-powered cars + Solar heater (2) perpendicular to sunlight Rotate in the direction + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select the long lens (2d) from the existing lens cross-section and sunlight through the air tube air (28a) A combined energy storage cycle engine that uses a method for increasing the amount of concentrated power generation.
  105. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+太陽光加熱器(2)を太陽光直角方向に回転+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Accelerates vertically downward at the compressed air speed + Makes all kinds of battery-powered cars + Solar heater (2) perpendicular to sunlight Rotating in the direction + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration + Accelerating vertically downward + Insulating long lens (2d) and sunlight at right angle Various energy storage cycle coalescing engines maintained in the vicinity and used as a method for increasing power generation.
  106. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) compression heat recovery + Accelerating output increase sphere (2E) provided with impact reduction means (2G) + Gravity acceleration added vertically downward + Split clamp (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  107. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Compressing internal air (28a) + accelerating output increasing sphere (2E) provided with impact reducing means (2G) + accelerating gravitational acceleration vertically downward + splitting fastener (80B) Various energy storage cycle coalescing engines that use a set of tightening multiple long lenses (2d) as a set to increase power generation.
  108. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select from existing material Long lens (2d ) Is an energy storage cycle coalescence engine with a method of increasing power generation.
  109. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Compression heat recovery of internal air (28a) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-sectional length lens from existing lens cross section ( 2d) Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  110. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Recover internal air (28a) by compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Length of heat insulation at the part approaching vacuum Various energy storage cycle coalescing engines that maintain the lens (2d) and sunlight in the vicinity of a right angle and increase the power generation amount.
  111. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration + Width of long lens (2d) tightening split clamp (80B) Various energy storage cycle coalescing engines with increased power generation method.
  112. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing multiple long lens (2d) by tightening fastener (80B) ) Is a set of various energy storage cycle coalescence engines that are used as a method for increasing power generation.
  113. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long manufacturing length lens (2d) to increase power generation method Various energy conservation cycle coalescing engines.
  114. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressed heat recovery + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravitational acceleration + Accelerating vertically downward + Selective lens long section (2d) from existing lens cross section Various energy storage cycle coalescing engines with a method of increasing the amount of power generation in the air (28a).
  115. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressing heat recovery + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravitational acceleration + Accelerating vertically downward + Insulating long lens (2d) and sunlight Various energy conservation cycle coalescing engines maintained near a right angle and used as a method for increasing power generation.
  116. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + internal air (28a) compression heat recovery + acceleration of output increasing sphere (2E) provided with impact reduction means (2G) + acceleration of gravitational acceleration vertically downward + split fastener (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  117. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + recovery of internal air (28a), compression heat recovery + acceleration of the output increasing sphere (2E) provided with the impact reduction means (2G) + acceleration of gravitational acceleration vertically downward + dividing and fastening tool (80B) Various energy storage cycle coalescing engines that use a set of tightening multiple long lenses (2d) as a set to increase power generation.
  118. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + Compression heat recovery of internal air (28a) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Selecting from existing material Long lens (2d) ) Is an energy storage cycle coalescence engine with a method of increasing power generation.
  119. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + internal air (28a) compression heat recovery + acceleration of output increasing sphere (2E) provided with impact reduction means (2G) + acceleration of gravitational acceleration vertically downward + cross section of existing lens selected from long section ( 2d) Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  120. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + Internal air (28a) compression heat recovery + Accelerating output increase sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Length of heat insulation near the vacuum Various energy storage cycle coalescing engines that maintain the lens (2d) and sunlight in the vicinity of a right angle and increase the power generation amount.
  121. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified house prime + Air pipe air (28a) Internal air (28a) compressed Heat recovery + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically + Increase width of long lens (2d) for split clamp (80B) tightening Various energy storage cycle coalescing engines that are used to increase power generation.
  122. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified house prime + Air pipe air (28a) Internal air (28a) compressed Heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Split multiple length lens (2d) tightened with clamp (80B) Various energy storage cycle coalescing engines provided as a set to increase power generation.
  123. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified house prime + Air pipe air (28a) Internal air (28a) compressed Heat recovery + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select from existing material Long production lens (2d) is long, and increase power generation method Various energy conservation cycle coalescence engine.
  124. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified house prime + Air pipe air (28a) Internal air (28a) compressed Heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select pipe length from existing lens cross section long lens (2d) to air pipe air ( 28a) Various energy storage cycle coalescing engines as a method for increasing the amount of concentrated power generation.
  125. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified house prime + Air pipe air (28a) Internal air (28a) compressed Heat recovery + Accelerate output augmenting sphere (2E) with impact reduction means (2G) + Add gravitational acceleration vertically downward + Heat insulation long lens (2d) and sunlight near right angle Various energy conservation cycle coalescing engines that are maintained in the above and used as a method for increasing power generation.
  126. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration + Width of long lens (2d) tightening split clamp (80B) Various energy storage cycle coalescing engines with increased power generation method.
  127. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing multiple long lens (2d) by tightening fastener (80B) ) Is a set of various energy storage cycle coalescence engines that are used as a method for increasing power generation.
  128. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long manufacturing length lens (2d) to increase power generation method Various energy conservation cycle coalescing engines.
  129. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressed heat recovery + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravitational acceleration + Accelerating vertically downward + Selective lens long section (2d) from existing lens cross section Various energy storage cycle coalescing engines with a method of increasing the amount of power generation in the air (28a).
  130. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressing heat recovery + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravitational acceleration + Accelerating vertically downward + Insulating long lens (2d) and sunlight Various energy conservation cycle coalescing engines maintained near a right angle and used as a method for increasing power generation.
  131. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) is compressed by heat recovery (1G) with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split tightening Various energy storage cycle coalescing engines that use a method of increasing power generation by increasing the width of the long lens (2d) for tightening the tool (80B).
  132. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Compress the internal air (28a) with a heat pump (1G) + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravity acceleration further downward vertically + split Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a fastener (80B).
  133. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) is recovered by compressing heat with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + From existing material Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the selected production long lens (2d) long.
  134. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) is recovered by compressing heat with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Cross section of existing lens Various energy storage cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long section (2d).
  135. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + approaching vacuum Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation by maintaining the heat insulating long lens (2d) and sunlight in the vicinity of a right angle at the part.
  136. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressing heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split clamp (80B) tightening length Various energy storage cycle coalescing engines with increased power generation by increasing the width of the lens (2d).
  137. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing and tightening clamp (80B) Various energy storage cycle coalescing engines that use a plurality of long lenses (2d) as a set to increase power generation.
  138. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long lens (2d) Various energy storage cycle coalescing engine that is a long and large power generation method.
  139. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-sectional length lens from existing lens cross section (2d) Various energy storage cycle coalescing engines that use sunlight as a method of increasing the amount of power generation in air tube air (28a).
  140. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens for heat insulation in the part close to vacuum ( 2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  141. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + internal air (28a) heat pump (1G) recovers heat with compression + accelerates output augmenting sphere (2E) provided with impact reduction means (2G) + accelerates gravitational acceleration vertically downward + split tightening Various energy storage cycle coalescing engines that use a method of increasing power generation by increasing the width of the long lens (2d) for tightening the tool (80B).
  142. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + internal air (28a) compressed heat recovery with heat pump (1G) + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravitational acceleration vertically downward + dividing Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a fastener (80B).
  143. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + internal air (28a) with heat pump (1G) to recover compression heat + accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + accelerate gravitational acceleration vertically downward + from existing materials Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the selected production long lens (2d) long.
  144. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + internal air (28a) with heat pump (1G) recovering compression heat + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration vertically downward + cross section of existing lens Various energy storage cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long section (2d).
  145. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + internal air (28a) with heat pump (1G) recovering compression heat + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravitational acceleration vertically downward + approaching vacuum Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation by maintaining the heat insulating long lens (2d) and sunlight in the vicinity of a right angle at the part.
  146. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + air pipe air (28a) internal air (28a) heat Compressive heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens for tightening split clamp (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of 2d).
  147. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + air pipe air (28a) internal air (28a) heat Compressing heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing multiple fasteners (80B) Various energy storage cycle coalescing engines with a long lens (2d) as a set to increase power generation.
  148. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + air pipe air (28a) internal air (28a) heat Compressed heat recovery with pump (1G) + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Select from existing material Long lens (2d) is made long Various energy storage cycle coalescing engines with increased power generation.
  149. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + air pipe air (28a) internal air (28a) heat Compressive heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select section long lens (2d) from the existing lens section Sun Various energy storage cycle coalescing engine that uses light as air tube air (28a) to increase concentrated power generation.
  150. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + air pipe air (28a) internal air (28a) heat Compressed heat recovery with pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens (2d) for heat insulation in the part close to vacuum And various energy conservation cycle coalescence engines that maintain solar power near right angles and increase power generation.
  151. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressing heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split clamp (80B) tightening length Various energy storage cycle coalescing engines with increased power generation by increasing the width of the lens (2d).
  152. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing and tightening clamp (80B) Various energy storage cycle coalescing engines that use a plurality of long lenses (2d) as a set to increase power generation.
  153. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long lens (2d) Various energy storage cycle coalescing engine that is a long and large power generation method.
  154. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-sectional length lens from existing lens cross section (2d) Various energy storage cycle coalescing engines that use sunlight as a method of increasing the amount of power generation in air tube air (28a).
  155. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens for heat insulation in the part close to vacuum ( 2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  156. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Compressed heat recovery device (2C) heats water (52b) by compression heat + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Adds gravitational acceleration vertically Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating and clamping the split fastener (80B) downward.
  157. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Compressed heat recovery device (2C) heats water (52b) by compression heat + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Adds gravitational acceleration vertically Various energy storage cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided downward and tightened with a fastener (80B).
  158. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Compressed heat recovery device (2C) heats water (52b) by compression heat + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Adds gravitational acceleration vertically Accelerating downward + Various energy storage cycle coalescing engines with a method of increasing power generation by making the long lens (2d) selected from existing materials longer.
  159. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Compressed heat recovery device (2C) heats water (52b) by compression heat + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Adds gravitational acceleration vertically Accelerating downward + Combined engine with various energy storage cycles using a method of increasing the amount of concentrated power generation in the air tube air (28a) with the lens (2d) selected from the cross section of the existing lens.
  160. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Compressed heat recovery device (2C) heats water (52b) by compression heat + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Adds gravitational acceleration vertically Various energy conservation cycle coalescence engines that use a method of increasing power generation by maintaining the long lens (2d) and sunlight in the vicinity of a right angle near the acceleration + vacuum near the bottom.
  161. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method to make turbine blades around 1/10 + air pipe air (28a) which is long with joint (80A) 2C) heating water (52b) + accelerating output increasing sphere (2E) provided with impact reducing means (2G) + accelerating gravitational acceleration vertically + long lens for split clamp (80B) tightening Various energy storage cycle coalescing engines that increase the width of (2d) and increase the power generation amount.
  162. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method to make turbine blades around 1/10 + air pipe air (28a) which is long with joint (80A) 2C) heating water (52b) + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravitational acceleration vertically downward + splitting and tightening fastener (80B) Various energy storage cycle coalescing engines that use a set of multiple long lenses (2d) to increase power generation.
  163. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method to make turbine blades around 1/10 + air pipe air (28a) which is long with joint (80A) 2C) Heating water (52b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select production length lens (2d) from existing material is long Various energy storage cycle coalescing engines as a method of increasing power generation.
  164. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method to make turbine blades around 1/10 + air pipe air (28a) which is long with joint (80A) 2C) heating water (52b) + accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + accelerating gravitational acceleration vertically downward + from existing lens cross section with selected cross section long lens (2d) Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase the amount of concentrated power generation.
  165. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method to make turbine blades around 1/10 + air pipe air (28a) which is long with joint (80A) 2C) heating water (52b) + accelerating the output increasing sphere (2E) provided with impact reducing means (2G) + accelerating gravitational acceleration vertically downward + heat insulating long lens (2d) ) And various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  166. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heat the air (28a) with the compression / compression heat recovery unit (2C) + heat the water (52b) + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + split Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the fastener (80B) is increased and the power generation amount is increased.
  167. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heat the air (28a) with the compression / compression heat recovery unit (2C) + heat the water (52b) + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + split Various energy storage cycle coalescing engines provided with a plurality of long lenses (2d) for fastening the fastener (80B) as a set to increase the power generation amount.
  168. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heat the air (28a) with the compression / compression heat recovery unit (2C), heat the water (52b) + accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + existing Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the production long lens (2d) long from the material.
  169. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heat the air (28a) with the compression / compression heat recovery unit (2C), heat the water (52b) + accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + existing Various energy conservation cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight to air pipe air (28a) with a lens having a long section (2d) selected from the lens section.
  170. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Air (28a) is heated by compression / compression heat recovery unit (2C), water (52b) is heated + output increasing sphere (2E) provided with impact reduction means (2G) is accelerated + gravitational acceleration is further accelerated vertically downward + vacuum Various energy conservation cycle coalescence engines that use a heat generation long lens (2d) and sunlight in the vicinity of the right angle to maintain a right angle in the vicinity.
  171. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat By heating the water (52b) with the compression heat recovery unit (2C) + accelerating the output increasing sphere (2E) provided with the impact reducing means (2G) + accelerating the gravitational acceleration vertically downward + split fastener (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  172. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Heating the water (52b) with the compression heat recovery unit (2C) + accelerating the output increasing sphere (2E) provided with the impact reducing means (2G) + accelerating the gravitational acceleration downward + dividing and fastening (80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  173. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Heating water (52b) with compression heat recovery unit (2C) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select manufacturing length from existing materials Various energy storage cycle coalescing engines with a long lens (2d) and a method of increasing power generation.
  174. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Heating water (52b) with compression heat recovery unit (2C) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Select cross section from existing lens cross section Various energy storage cycle coalescing engines that use a long lens (2d) to increase sunlight concentration into air tube air (28a).
  175. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat By heating the water (52b) with the compression heat recovery unit (2C) + accelerating the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerating the gravitational acceleration vertically downward + at the part close to the vacuum Various energy storage cycle coalescence engine that uses a heat insulating long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  176. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + Split fastener (80B) Various energy storage cycle coalescing engines in which the width of the tightening long lens (2d) is increased and the power generation amount is increased.
  177. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing and tightening Various energy storage cycle coalescing engines in which a plurality of long lenses (2d) tightened with attachments (80B) are provided as a set to increase power generation.
  178. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing materials Various energy storage cycle coalescing engines with a long production length lens (2d) and a method of increasing power generation.
  179. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heat the water (52b) with the compression heat recovery unit (2C) by the compression heat + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically + from the cross section of the existing lens Various energy storage cycle coalescing engines that use a method of increasing the amount of concentrated power generation with sunlight in the air tube air (28a) with the selected cross-section long lens (2d).
  180. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + approaching vacuum Various energy conservation cycle coalescence engine that uses a long lens (2d) that is thermally insulated and sunlight in the vicinity of a right angle to increase power generation.
  181. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the split fastener (80B) is increased to increase the power generation amount.
  182. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines that are divided and provided with a plurality of long lenses (2d) tightened with a fastener (80B) as a set to increase power generation.
  183. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines with a method of increasing power generation by selecting a long lens (2d) as a selected production length from existing materials.
  184. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines using a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long lens (2d) selected from the existing lens cross section.
  185. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy conservation cycle coalescence engines that use a heat insulating long lens (2d) and sunlight in the vicinity of a right angle in the vicinity of vacuum to increase power generation.
  186. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + air pipe air (28a) that is long with joint (80A) (28a) internal air (28a) heat quantity of compressed air (28b) ) To heat the water (52b) + accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + accelerate the gravitational acceleration vertically + long lens (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of 2d).
  187. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + air pipe air (28a) that is long with joint (80A) (28a) internal air (28a) heat quantity of compressed air (28b) ) To heat the water (52b) + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + divide and tighten the fastener (80B). Various energy storage cycle coalescing engines with a long lens (2d) as a set to increase power generation.
  188. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + air pipe air (28a) that is long with joint (80A) (28a) internal air (28a) heat quantity of compressed air (28b) ) To heat the water (52b) + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + select the existing material from the long lens (2d) Various energy storage cycle coalescing engines with increased power generation.
  189. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + air pipe air (28a) that is long with joint (80A) (28a) internal air (28a) heat quantity of compressed air (28b) ) To heat the water (52b) + accelerate the output augmenting sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + select the long lens (2d) from the existing lens section and sun Various energy storage cycle coalescing engine that uses light as air tube air (28a) to increase concentrated power generation.
  190. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + air pipe air (28a) that is long with joint (80A) (28a) internal air (28a) heat quantity of compressed air (28b) ) To heat the water (52b) + accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + accelerate the gravitational acceleration vertically downward + insulate long lens (2d) near the vacuum And various energy conservation cycle coalescence engines that maintain solar power near right angles and increase power generation.
  191. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heating water (52b) with compressed air calorie (28b) of air (28a) calorie + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Divided tightening Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the attachment (80B) is increased and the power generation amount is increased.
  192. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heating water (52b) with compressed air calorie (28b) of air (28a) calorie + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration + dividing vertically Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a clamp (80B).
  193. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heat the water (52b) with the compressed air calorie (28b) of the air (28a) calorie + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Existing materials Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the production long lens (2d) long.
  194. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heating water (52b) with compressed air calorie (28b) of air (28a) calorie + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Existing lens Various energy storage cycle coalescence engines that use a method for increasing the amount of concentrated power generation from sunlight to air pipe air (28a) with a long section lens (2d) selected from the cross section.
  195. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズと空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate specific critical materials vertically downward + long lens and air tube air (28a) inside that can be evacuated with fastener (80B) Heat the water (52b) with the compressed air calorie (28b) of the air (28a) calorie + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically downward + vacuum Various energy conservation cycle coalescence engines that use a heat insulating long lens (2d) and sunlight at a right angle near the approaching part to increase power generation.
  196. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified Housing Prime + Air Tube Air (28a) Internal Air (28a) Compression Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Tightening of split fastener (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  197. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified Housing Prime + Air Tube Air (28a) Internal Air (28a) Compression Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration additionally vertically downward + Clamping tool (80B) Various energy storage cycle coalescing engines that use a set of tightening multiple long lenses (2d) as a set to increase power generation.
  198. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified Housing Prime + Air Tube Air (28a) Internal Air (28a) Compression Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long lens (2d) ) Is an energy storage cycle coalescence engine with a method of increasing power generation.
  199. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified Housing Prime + Air Tube Air (28a) Internal Air (28a) Compression Heating water (52b) with air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-sectional length lens from existing lens cross section ( 2d) Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  200. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified Housing Prime + Air Tube Air (28a) Internal Air (28a) Compression Heating water (52b) with air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Length of heat insulation in the part close to vacuum Various energy storage cycle coalescing engines that maintain the lens (2d) and sunlight in the vicinity of a right angle and increase the power generation amount.
  201. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split fastener (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  202. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing and tightening tool ( 80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  203. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Various energy storage cycle coalescing engines in which (2d) is long and the power generation amount is increased.
  204. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heat water (52b) with compressed air calorie (28b) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section length from existing lens cross section Various energy conservation cycle coalescing engines that use a lens (2d) to increase the amount of concentrated power generation from sunlight into air tube air (28a).
  205. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Heat insulation in the part close to vacuum Long energy lens (2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle and increase power generation.
  206. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with internal air (28a) compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating the power increase ball (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically + Combined engine of various energy conservation cycles using a method of increasing power generation by increasing the width of the long lens (2d) for tightening the split fastener (80B).
  207. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with internal air (28a) compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating the power increase ball (2E) provided with impact reduction means (2G) + Energy acceleration cycle coalescing engine with a method of increasing power generation by accelerating gravitational acceleration vertically downward + dividing and providing a set of multiple long lenses (2d) tightened with a fastener (80B).
  208. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with internal air (28a) compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating the power increase ball (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically accelerated + Select from existing materials Long production lens (2d) is used to increase the amount of power generation.
  209. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with internal air (28a) compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating the power increase ball (2E) provided with impact reduction means (2G) + Gravity acceleration added vertically accelerated + Various energy storage cycle coalescence engines that use concentrated lens power generation method to increase the amount of sunlight to air tube air (28a) from the existing lens cross section with a selected cross section long lens (2d).
  210. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Heating water (52b) with internal air (28a) compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating the power increase ball (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically + Combined various energy storage cycle engines that maintain heat insulation long lens (2d) and sunlight near right angle in the part close to vacuum and increase power generation.
  211. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output generation equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) solar heater (2) compressed air calorie (28b) ) To heat water (52b) + enable liquid oxygen injection fuel injection combustion + accelerate output increasing sphere (2E) provided with impact reduction means (2G) + accelerate gravity acceleration further vertically downward + split tightening Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the attachment (80B) is increased and the power generation amount is increased.
  212. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output generation equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) solar heater (2) compressed air calorie (28b) ) Heating water (52b) + enabling liquid oxygen injection fuel injection combustion + accelerating the power increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration + vertically dividing + dividing Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a clamp (80B).
  213. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output generation equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) solar heater (2) compressed air calorie (28b) ) To heat the water (52b) + enable liquid oxygen injection fuel injection combustion + accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + accelerate gravity acceleration further downward vertically + existing materials Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the production long lens (2d) long.
  214. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output generation equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) solar heater (2) compressed air calorie (28b) ) To heat the water (52b) + enable liquid oxygen injection fuel injection combustion + accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + accelerate gravity acceleration further downward vertically + existing lens Various energy storage cycle coalescence engines that use a method for increasing the amount of concentrated power generation from sunlight to air pipe air (28a) with a long section lens (2d) selected from the cross section.
  215. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output generation equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) solar heater (2) compressed air calorie (28b) ) To heat water (52b) + enable liquid oxygen injection fuel injection combustion + accelerate output increase sphere (2E) provided with impact reduction means (2G) + accelerate gravity acceleration further downward vertically + to vacuum Various energy conservation cycle coalescence engines that use a heat insulating long lens (2d) and sunlight at a right angle near the approaching part to increase power generation.
  216. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reducing means (2G) Accelerating + Gravitational acceleration added Accelerating vertically downward + Various energy storage cycle coalescing engines using the method of increasing power generation by increasing the width of the long lens (2d) for tightening the split fastener (80B).
  217. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reducing means (2G) Accelerating + Accelerating gravitational acceleration + Vertically accelerating + splitting and combining multiple long-lens lenses (2d) tightened with a fastener (80B) as a set, and various energy storage cycle coalescing engines using a method for increasing power generation.
  218. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reducing means (2G) Accelerating + Accelerating gravity acceleration Accelerating vertically downward + Various energy conservation cycle coalescing engines with a method of increasing power generation by making the selected production length lens (2d) long from existing materials.
  219. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reducing means (2G) Accelerate + Gravity acceleration added vertically downward + Various energy storage cycle coalescence engine that uses concentrated lens power generation method to increase sunlight generation into air tube air (28a) from the existing lens cross section with a selected cross section long lens (2d).
  220. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reducing means (2G) Accelerating + Accelerating gravitational acceleration + Accelerating vertically downward + Various energy conservation cycle coalescing engines that maintain heat insulation long lens (2d) and sunlight in the vicinity of a right angle near the vacuum and increase power generation.
  221. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coverage Ratio Critical Substances Vertically Down + Fully Electrified Houses Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the split fastener (80B) is increased to increase the power generation amount.
  222. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coverage Ratio Critical Substances Vertically Down + Fully Electrified Houses Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines that are divided and provided with a plurality of long lenses (2d) tightened with a fastener (80B) as a set to increase power generation.
  223. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coverage Ratio Critical Substances Vertically Down + Fully Electrified Houses Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines with a method of increasing power generation by selecting a long lens (2d) as a selected production length from existing materials.
  224. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coverage Ratio Critical Substances Vertically Down + Fully Electrified Houses Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines using a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long lens (2d) selected from the existing lens cross section.
  225. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coverage Ratio Critical Substances Vertically Down + Fully Electrified Houses Prime + Air Tube Air (28a) Internal Air (28a) Compressed Air Heating water (52b) with calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravity acceleration additional vertically downward + Various energy conservation cycle coalescence engines that use a heat insulating long lens (2d) and sunlight in the vicinity of a right angle in the vicinity of vacuum to increase power generation.
  226. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating + split fastener (80B).
  227. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Various energy storage cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided and tightened with a fastener (80B).
  228. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Accelerating + Combined engine of various energy storage cycles with a method of increasing power generation by making the long lens (2d) selected from existing materials long.
  229. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Accelerating + Combined engine with various energy storage cycles using a method of increasing the amount of concentrated power generation in the air tube air (28a) by using a lens (2d) with a long section (2d) selected from the existing lens cross section.
  230. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Accelerating + Combined engine with various energy conservation cycles that uses a heat-insulating long lens (2d) and sunlight in the vicinity of a right angle in the part close to vacuum to increase power generation.
  231. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Maximum increase in vaporization explosive force by the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Split fastener (80B) Various energy storage cycle coalescing engines in which the width of the tightening long lens (2d) is increased and the power generation amount is increased.
  232. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Maximum increase in vaporization explosive force by the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Divide and tighten Various energy storage cycle coalescing engines in which a plurality of long lenses (2d) tightened with attachments (80B) are provided as a set to increase power generation.
  233. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Increase in vaporization explosion force to the maximum by the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select from existing materials Various energy storage cycle coalescing engines with a long production length lens (2d) and a method of increasing power generation.
  234. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Increase in vaporization explosive force to the maximum by the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + From existing lens cross section Various energy storage cycle coalescing engines that use a method of increasing the amount of concentrated power generation with sunlight in the air tube air (28a) with the selected cross-section long lens (2d).
  235. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating coated steel balls vertically downward + heat resistant material (2A) heat insulating material (2c) half-cylinder outer box (77B) + air tube air (28a) Internal air (28a) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Close to vacuum Various energy conservation cycle coalescence engine that uses a long lens (2d) that is thermally insulated and sunlight in the vicinity of a right angle to increase power generation.
  236. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Increase in vaporization explosion force to maximum with compression heat amount + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Long lens for tightening split clamp (80B) Various energy storage cycle coalescing engines that increase the width of (2d) and increase the power generation amount.
  237. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Acceleration of the output sphere (2E) provided with impact reduction means (2G) + acceleration of gravitational acceleration vertically downward + splitting and fastening of the fastener (80B) Various energy storage cycle coalescing engines that use a set of multiple long lenses (2d) to increase power generation.
  238. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Increases vaporization explosive force to maximum with compression heat amount + Accelerates output increasing sphere (2E) equipped with impact reduction means (2G) + Accelerates gravitational acceleration vertically + Selects existing material from long lens (2d) Various energy storage cycle coalescing engines as a method of increasing power generation.
  239. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Compressive calorie increases maximum vaporization explosive force + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Accelerates gravitational acceleration vertically downward + Select long lens (2d) from existing lens cross section Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase the amount of concentrated power generation.
  240. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) and air pipe air (28a) + internal air (28a) that is long with joint (80A) Accelerating the power increase sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additionally vertically downward + Heat insulation long lens (2d) near the vacuum ) And various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  241. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + Internal air (28a) Increase in vaporization and explosion force to the maximum with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Split clamp (80B) Various energy storage cycle coalescing engines in which the width of the tightening long lens (2d) is increased and the power generation amount is increased.
  242. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + Internal air (28a) Increase in vaporization and explosion force to the maximum with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration further vertically downward + Divide and tighten Various energy storage cycle coalescing engines in which a plurality of long lenses (2d) tightened with attachments (80B) are provided as a set to increase power generation.
  243. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + Internal air (28a) Increases vaporization explosive force to the maximum with the amount of compression heat + Accelerates the power increasing sphere (2E) with impact reduction means (2G) + Accelerates gravitational acceleration vertically + Select from existing materials Various energy storage cycle coalescing engines with a long production length lens (2d) and a method of increasing power generation.
  244. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + Internal air (28a) Increases vaporization explosion force to the maximum with the amount of compression heat + Accelerates the output increase sphere (2E) provided with impact reduction means (2G) + Accelerates gravitational acceleration vertically downward + From existing lens cross section Various energy storage cycle coalescing engines that use a method of increasing the amount of concentrated power generation with sunlight in the air tube air (28a) with the selected cross-section long lens (2d)
  245. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と空気管空気(28a)+内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and air tube air (with a structure and method for accelerating specific critical substances vertically downward with a fastener (80B) and vacuum tube air (2d) 28a) + Internal air (28a) Maximum increase in vaporization explosive force by the amount of compression heat + Accelerate the power increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Close to vacuum Various energy conservation cycle coalescence engine that uses a long lens (2d) that is thermally insulated and sunlight in the vicinity of a right angle to increase power generation.
  246. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Fully electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Vaporization explosion force is increased to the maximum + output increasing sphere (2E) provided with impact reduction means (2G) is accelerated + gravitational acceleration is added vertically downward + long lens (2d) for tightening split clamp (80B) ) Various energy storage cycle coalescing engines with increased power generation method.
  247. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Fully electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Vaporization explosive force is increased to the maximum + Accelerating output increasing ball (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing multiple lengths of fastening tool (80B) Various energy storage cycle coalescing engines that use a set of lenses (2d) to increase power generation.
  248. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Fully electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Vaporization explosive force is increased to the maximum + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing materials Long production lens (2d) is used for power generation Various energy storage cycle coalescing engines with increased quantity.
  249. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Fully electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Vaporization explosive force is increased to the maximum + output increasing sphere (2E) provided with impact reduction means (2G) is accelerated + gravitational acceleration is further accelerated vertically downward + sunlight is selected from the cross section of the existing lens with the long lens (2d) Various energy storage cycle coalescing engines using a method for increasing the amount of power generation in the air pipe air (28a).
  250. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + Fully electrified house prime + Air pipe air (28a) Internal air (28a) Compression heat Vaporization explosive force is increased to the maximum + output increasing sphere (2E) provided with impact reduction means (2G) is accelerated + gravitational acceleration is further accelerated vertically downward + heat insulating long lens (2d) Various energy conservation cycle coalescing engines that maintain the sunlight near right angles and increase power generation.
  251. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Increase in vaporization explosion force to maximum with compression heat amount + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Long lens for tightening split clamp (80B) Various energy storage cycle coalescing engines that increase the width of (2d) and increase the power generation amount.
  252. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Acceleration of the output sphere (2E) provided with impact reduction means (2G) + acceleration of gravitational acceleration vertically downward + splitting and fastening of the fastener (80B) Various energy storage cycle coalescing engines that use a set of multiple long lenses (2d) to increase power generation.
  253. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Increases vaporization explosive force to maximum with compression heat amount + Accelerates output increasing sphere (2E) equipped with impact reduction means (2G) + Accelerates gravitational acceleration vertically + Selects existing material from long lens (2d) Various energy storage cycle coalescing engines as a method of increasing power generation.
  254. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Compressive calorie increases maximum vaporization explosive force + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Accelerates gravitational acceleration vertically downward + Select long lens (2d) from existing lens cross section Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase the amount of concentrated power generation.
  255. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic force solar gravity acceleration power generation output increasing sphere (2E) structure and method for accelerating vertically downward with compressed air speed + accelerating various battery-powered vehicles + air tube air (28a) internal air (28a) Accelerating the power increase sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additionally vertically downward + Heat insulation long lens (2d) near the vacuum ) And various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  256. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the increasing sphere (2E) + Accelerating gravity acceleration + Accelerating vertically downward + Increasing the width of the long lens (2d) for tightening the split fastener (80B) to increase the power generation amount organ.
  257. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the expanding sphere (2E) + Accelerating the gravitational acceleration vertically + Dividing and providing a set of multiple long lenses (2d) for tightening the fastener (80B) to save various types of energy Cycle coalescence engine.
  258. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the expanding sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Various energy conservation cycle coalescing engine with a method of increasing the power generation by making the long lens (2d) selected from existing materials long.
  259. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Preserving various energy from the existing lens cross-section by selecting the long-length lens (2d) to the solar air to the air tube air (28a) Cycle coalescence engine.
  260. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the expanding sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Keeping heat-insulated long lens (2d) and sunlight in the vicinity of a right angle in the vicinity of the vacuum, various energy conservation methods to increase power generation Cycle coalescence engine.
  261. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the increasing sphere (2E) + Accelerating gravity acceleration + Accelerating vertically downward + Increasing the width of the long lens (2d) for tightening the split fastener (80B) to increase the power generation amount organ.
  262. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the expanding sphere (2E) + Accelerating the gravitational acceleration vertically + Dividing and providing a set of multiple long lenses (2d) for tightening the fastener (80B) to save various types of energy Cycle coalescence engine.
  263. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the expanding sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Various energy conservation cycle coalescing engine with a method of increasing the power generation by making the long lens (2d) selected from existing materials long.
  264. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Preserving various energy from the existing lens cross-section by selecting the long-length lens (2d) to the solar air to the air tube air (28a) Cycle coalescence engine.
  265. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output Increased sphere (2E) suction / acceleration vertically downward with vacuum + output with water surface floating solar heater (2) + impact reduction means (2G) Accelerating the expanding sphere (2E) + Accelerating gravitational acceleration + Accelerating vertically downward + Keeping heat-insulated long lens (2d) and sunlight in the vicinity of a right angle in the vicinity of the vacuum, various energy conservation methods to increase power generation Cycle coalescence engine.
  266. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coated Mercury Vertically Down + Accelerate Battery Storage Various Ships + Water Floating Solar Heater (2) + Impact Reduction Accelerating output increasing sphere (2E) provided with means (2G) + Accelerating gravitational acceleration + Accelerating vertically downward + Increasing the width of long lens (2d) for tightening split fastener (80B) to increase power generation Various energy conservation cycle coalescence engine as a method.
  267. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coated Mercury Vertically Down + Accelerate Battery Storage Various Ships + Water Floating Solar Heater (2) + Impact Reduction Accelerate output augmenting sphere (2E) provided with means (2G) + Accelerate gravitational acceleration vertically + Divide and provide multiple sets of lens (2d) tightened with clamp (80B) to generate electricity Various energy storage cycle coalescing engines with increased quantity.
  268. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coated Mercury Vertically Down + Accelerate Battery Storage Various Ships + Water Floating Solar Heater (2) + Impact Reduction Accelerating output increasing sphere (2E) provided with means (2G) + Accelerating gravitational acceleration vertically downward + Combined various energy conservation cycles with a method of increasing power generation by lengthening selected production length lens (2d) from existing materials organ.
  269. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coated Mercury Vertically Down + Accelerate Battery Storage Various Ships + Water Floating Solar Heater (2) + Impact Reduction Accelerate the output increasing sphere (2E) provided with means (2G) + Accelerate gravitational acceleration vertically downward + Concentrated power generation of sunlight into air tube air (28a) with a long section lens (2d) selected from existing lens cross section Various energy storage cycle coalescing engines with increased quantity.
  270. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Coated Mercury Vertically Down + Accelerate Battery Storage Various Ships + Water Floating Solar Heater (2) + Impact Reduction Accelerate the output augmenting sphere (2E) provided with means (2G) + Accelerate gravity acceleration vertically downward + Keep heat-insulated long lens (2d) and sunlight near right angle in the part close to vacuum Various energy storage cycle coalescing engines with increased quantity.
  271. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Compress the heat recovery + Accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + Accelerate the gravitational acceleration vertically + Split clamp (80B) Fastening of the long lens (2d) Various energy conservation cycle coalescing engines with increased width and increased power generation.
  272. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) With heat pump (1G) to accelerate heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Split clamp (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  273. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + Split tightening Various energy storage cycle coalescing engines that use a method of increasing power generation by increasing the width of the long lens (2d) for tightening the tool (80B).
  274. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split fastener (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  275. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating + dividing fastener (80B) tightening downward.
  276. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Compress the heat recovery + Accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + Accelerate the gravitational acceleration vertically downward + Divide and tighten the clamp (80B) multiple length lens ( Various energy storage cycle coalescing engines provided as a method for increasing power generation by providing 2d) as a set.
  277. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) With heat pump (1G) + accelerating output increasing sphere (2E) with impact reduction means (2G) + accelerating gravitational acceleration vertically downward + splitting and tightening clamp (80B) Various energy storage cycle coalescing engines with a plurality of long lenses (2d) attached as a set to increase power generation.
  278. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration + dividing vertically Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a fastener (80B).
  279. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration additionally vertically downward + Tightening tool (80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  280. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy storage cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided downward and tightened with a fastener (80B).
  281. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Compressing heat recovery + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing materials Long production lens (2d) is increased to increase power generation Various energy conservation cycle coalescence engine as a method.
  282. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heat recovery with compression pump (1G) + Accelerate output sphere (2E) with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Select from existing material Long lens (2d) Various energy storage cycle coalescing engine with a long and large power generation method.
  283. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increase sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + From existing material Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the selected production long lens (2d) long.
  284. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select production length from existing materials Various energy storage cycle coalescing engines with a long lens (2d) and a method of increasing power generation.
  285. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Accelerating downward + Various energy storage cycle coalescing engines with a method of increasing power generation by making the long lens (2d) selected from existing materials longer.
  286. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Compressive heat recovery + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically + Select sunlight from the existing lens cross section with the selected cross-section length lens (2d) Various energy storage cycle coalescing engines with a method of increasing the amount of concentrated power generation in the tube air (28a).
  287. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) With a heat pump (1G) + accelerating the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerating the gravitational acceleration vertically downward + selecting the long lens (2d) from the cross section of the existing lens ) Various energy conservation cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  288. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Cross section of existing lens Various energy storage cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long section (2d).
  289. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heat water (52b) with compressed air calorie (28b) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section from existing lens cross section Various energy storage cycle coalescing engines that use a long lens (2d) to increase sunlight concentration into air tube air (28a).
  290. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Accelerating downward + Combined engine with various energy storage cycles using a method of increasing the amount of concentrated power generation in the air tube air (28a) with the lens (2d) selected from the cross section of the existing lens.
  291. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Compressing heat recovery + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Heat insulation long lens (2d) and sunlight near the vacuum Is an energy conservation cycle coalescence engine that maintains power in the vicinity of a right angle and increases power generation.
  292. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) With heat pump (1G) to compress heat recovery + Accelerate output sphere (2E) with shock reduction means (2G) + Accelerate gravity acceleration vertically downward + Insulate long lens close to vacuum (2d) and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase the power generation amount.
  293. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + approaching vacuum Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation by maintaining the heat insulating long lens (2d) and sunlight in the vicinity of a right angle at the part.
  294. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + In the part approaching vacuum Various energy storage cycle coalescence engine that uses a heat insulating long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  295. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy conservation cycle coalescence engines that use a method of increasing power generation by maintaining the long lens (2d) and sunlight in the vicinity of a right angle near the acceleration + vacuum near the bottom.
  296. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Is a power generation method for accelerating the power increasing sphere (2E) provided with compression heat recovery + impact reducing means (2G) + accelerating the gravitational acceleration further vertically downward.
  297. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) By heat pump (1G), compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Additional power storage cycle combined engine that accelerates gravitational acceleration vertically downward .
  298. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Power generation method for accelerating gravitational acceleration further downward vertically Various energy conservation cycle coalescence engine.
  299. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Various energy as a power generation method for accelerating gravitational acceleration downward vertically Conservation cycle coalescence organization.
  300. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Downward + Plurality of Ships Driven by Storage Battery + Plural Side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy conservation cycle coalescing engines that generate electricity in a downward direction.
  301. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)で落差1200m増大+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Steel Balls Vertically Down + Head Drop Increased by 1200m with Pump (1H) + Solar Floating Type Solar Heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Increase the width of the long lens (2d) tightening the split fastener (80B) to generate electricity Various energy storage cycle coalescing engines with increased quantity.
  302. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)で落差1200m増大+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Steel Balls Vertically Down + Head Drop Increased by 1200m with Pump (1H) + Solar Floating Type Solar Heater (2) + Accelerate output augmenting sphere (2E) with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Divide and provide multiple lens (2d) for tightening fastener (80B) as a set Combined with various energy storage cycle engines that have increased power generation.
  303. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)で落差1200m増大+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Steel Balls Vertically Down + Head Drop Increased by 1200m with Pump (1H) + Solar Floating Type Solar Heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select from existing materials Select a long lens (2d) to make the power generation amount increase method, and save various energy Cycle coalescence engine.
  304. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)で落差1200m増大+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Steel Balls Vertically Down + Head Drop Increased by 1200m with Pump (1H) + Solar Floating Type Solar Heater (2) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select cross-section long lens (2d) from existing lens cross-section to air tube air (28a) Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation.
  305. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)で落差1200m増大+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods to Accelerate Steel Balls Vertically Down + Head Drop Increased by 1200m with Pump (1H) + Solar Floating Type Solar Heater (2) + Accelerate the output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Keep heat-insulated long lens (2d) and sunlight in the vicinity of right angle near the vacuum Combined with various energy storage cycle engines that have increased power generation.
  306. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically + Long lens for split clamp (80B) tightening ( Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of 2d).
  307. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing multiple fasteners (80B) Various energy storage cycle coalescing engines with a long lens (2d) as a set to increase power generation.
  308. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select from existing material Long manufacturing lens (2d) Various energy storage cycle coalescing engines with increased power generation.
  309. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-section long lens (2d) from existing lens section Various energy storage cycle coalescing engine that uses light as air tube air (28a) to increase concentrated power generation.
  310. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens (2d) for heat insulation in the part close to vacuum And various energy conservation cycle coalescence engines that maintain solar power near right angles and increase power generation.
  311. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Generation Equipment method that makes turbine blades around 1/10 + Solar thermal suspension suspension bridge that is long with joint (80A) Solar surface heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Increase the width of the long lens (2d) tightening the split fastener (80B) to generate electricity Various energy storage cycle coalescing engines with increased quantity.
  312. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Generation Equipment method that makes turbine blades around 1/10 + Solar thermal suspension suspension bridge that is long with joint (80A) Solar surface heater (2) + Accelerate output augmenting sphere (2E) with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Divide and provide multiple lens (2d) for tightening fastener (80B) as a set Combined with various energy storage cycle engines that have increased power generation.
  313. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Generation Equipment method that makes turbine blades around 1/10 + Solar thermal suspension suspension bridge that is long with joint (80A) Solar surface heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select from existing materials Select a long lens (2d) to make the power generation amount increase method, and save various energy Cycle coalescence engine.
  314. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Generation Equipment method that makes turbine blades around 1/10 + Solar thermal suspension suspension bridge that is long with joint (80A) Solar surface heater (2) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select cross-section long lens (2d) from existing lens cross-section to air tube air (28a) Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation.
  315. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Generation Equipment method that makes turbine blades around 1/10 + Solar thermal suspension suspension bridge that is long with joint (80A) Solar surface heater (2) + Accelerate the output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Keep heat-insulated long lens (2d) and sunlight in the vicinity of right angle near the vacuum Combined with various energy storage cycle engines that have increased power generation.
  316. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating type solar heater (2) + Accelerating output increasing ball (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Split clamp (80B) tightening length Various energy storage cycle coalescing engines with increased power generation by increasing the width of the lens (2d).
  317. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating type solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing and tightening clamp (80B) Various energy storage cycle coalescing engines that use a plurality of long lenses (2d) as a set to increase power generation.
  318. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating type solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Select manufacturing long lens (2d) from existing material Various energy storage cycle coalescing engine that is a long and large power generation method.
  319. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating type solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select cross section long lens from existing lens cross section (2d) Various energy storage cycle coalescing engines that use sunlight as a method of increasing the amount of power generation in air tube air (28a).
  320. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating type solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically + Long lens for heat insulation in the part close to vacuum ( 2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  321. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages and structure and method for accelerating the material with significant coverage ratio vertically downward + Making the whole electrified house primed + Solar surface heater (2) + impact Accelerating the output increasing sphere (2E) provided with the reduction means (2G) + Accelerating gravity acceleration vertically downward + Increasing the width of the long lens (2d) for tightening the split fastener (80B) to increase the amount of power generation Various energy conservation cycle coalescing engine as an increase method.
  322. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages and structure and method for accelerating the material with significant coverage ratio vertically downward + Making the whole electrified house primed + Solar surface heater (2) + impact Accelerate the output increasing sphere (2E) provided with the reducing means (2G) + accelerate the gravitational acceleration vertically downward and divide it, and provide a set of multiple lenses (2d) for fastening the fastener (80B) Various energy storage cycle coalescing engines with increased power generation.
  323. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages and structure and method for accelerating the material with significant coverage ratio vertically downward + Making the whole electrified house primed + Solar surface heater (2) + impact Accelerating output increasing sphere (2E) provided with reduction means (2G) + Accelerating gravitational acceleration vertically downward + Various energy conservation cycles using a method of increasing power generation by lengthening selected production length lens (2d) from existing materials Combined organization.
  324. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages and structure and method for accelerating the material with significant coverage ratio vertically downward + Making the whole electrified house primed + Solar surface heater (2) + impact Accelerate the output increasing sphere (2E) provided with the reduction means (2G) + Accelerate gravity acceleration vertically downward + Concentrate sunlight on the air tube air (28a) from the existing lens cross section with the selected cross section long lens (2d) Various energy storage cycle coalescing engines with increased power generation.
  325. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages and structure and method for accelerating the material with significant coverage ratio vertically downward + Making the whole electrified house primed + Solar surface heater (2) + impact Accelerating the output increasing sphere (2E) provided with the reduction means (2G) + Accelerating gravity acceleration vertically downward + Keeping the heat insulating long lens (2d) and sunlight in the vicinity of the right angle near the vacuum Various energy storage cycle coalescing engines with increased power generation.
  326. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structures and Methods to Accelerate Vertically Downward with Compressed Air Velocity + Putting Battery-Driven Various Automobiles + Solar Floating Solar Heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Increase the width of the long lens (2d) for tightening the split fastener (80B) Various energy storage cycle coalescing engines with increased power generation.
  327. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structures and Methods to Accelerate Vertically Downward with Compressed Air Velocity + Putting Battery-Driven Various Automobiles + Solar Floating Type Solar Heater (2) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Split multiple length lens (2d) tightened with clamp (80B) as a set Various energy storage cycle coalescing engines that have been installed to increase power generation.
  328. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structures and Methods to Accelerate Vertically Downward with Compressed Air Velocity + Putting Battery-Driven Various Automobiles + Solar Floating Type Solar Heater (2) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select energy from existing materials Various lengths of energy as a method of increasing power generation by making long lens (2d) long Conservation cycle coalescence organization.
  329. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structures and Methods to Accelerate Vertically Downward with Compressed Air Velocity + Putting Battery-Driven Various Automobiles + Solar Floating Type Solar Heater (2) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Select pipe length from existing lens cross section long lens (2d) to air tube air (28a) Various energy storage cycle coalescing engines that are used as a method of increasing the amount of power generation.
  330. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structures and Methods to Accelerate Vertically Downward with Compressed Air Velocity + Putting Battery-Driven Various Automobiles + Solar Floating Solar Heater (2) + Accelerate output augmenting sphere (2E) equipped with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Keep heat-insulated long lens (2d) and sunlight near right angle near vacuum Various energy storage cycle coalescing engines that are used to increase power generation.
  331. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Sunlight heater (2) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically + Long lens (2d) for tightening split clamp (80B) ) Various energy storage cycle coalescing engines with increased power generation method.
  332. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Accelerate the output increasing sphere (2E) provided with the solar heater (2) + impact reducing means (2G) + accelerate the gravitational acceleration vertically downward + divide multiple lengths of fasteners (80B) Various energy storage cycle coalescing engines that use a set of lenses (2d) to increase power generation.
  333. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Accelerate the output heating sphere (2E) provided with the solar heater (2) + impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Select from existing materials Generate long lens (2d) as long Various energy storage cycle coalescing engines with increased quantity.
  334. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Sunlight heater (2) + Accelerating output sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically downward + Sunlight from existing lens cross section with selected cross section length lens (2d) Various energy storage cycle coalescing engines using a method for increasing the amount of power generation in the air pipe air (28a).
  335. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant (2A) Heat Insulating Material (2c) Half-Cylinder Outer Box (77B) + Water Surface Floating Type Accelerate the output increasing sphere (2E) provided with the solar heater (2) + impact reducing means (2G) + accelerate the gravitational acceleration vertically downward + insulate long lens (2d) near the vacuum Various energy conservation cycle coalescing engines that maintain the sunlight near right angles and increase power generation.
  336. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Equipment method to make turbine blades around 1/10 + Solar thermal suspension bridge (2b) water surface floating solar heater (2) + impact with joint (80A) Accelerating the output increasing sphere (2E) provided with the reduction means (2G) + Accelerating gravity acceleration vertically downward + Increasing the width of the long lens (2d) for tightening the split fastener (80B) to increase the amount of power generation Various energy conservation cycle coalescing engine as an increase method.
  337. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Equipment method to make turbine blades around 1/10 + Solar thermal suspension bridge (2b) water surface floating solar heater (2) + impact with joint (80A) Accelerate the output increasing sphere (2E) provided with the reducing means (2G) + accelerate the gravitational acceleration vertically downward and divide it, and provide a set of multiple lenses (2d) for fastening the fastener (80B) Various energy storage cycle coalescing engines with increased power generation.
  338. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Equipment method to make turbine blades around 1/10 + Solar thermal suspension bridge (2b) water surface floating solar heater (2) + impact with joint (80A) Accelerating output increasing sphere (2E) provided with reduction means (2G) + Accelerating gravitational acceleration vertically downward + Various energy conservation cycles using a method of increasing power generation by lengthening selected production length lens (2d) from existing materials Combined organization.
  339. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Equipment method to make turbine blades around 1/10 + Solar thermal suspension bridge (2b) water surface floating solar heater (2) + impact with joint (80A) Accelerate the output increasing sphere (2E) provided with the reduction means (2G) + Accelerate gravity acceleration vertically downward + Concentrate sunlight on the air tube air (28a) from the existing lens cross section with the selected cross section long lens (2d) Various energy storage cycle coalescing engines with increased power generation.
  340. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Output Equipment method to make turbine blades around 1/10 + Solar thermal suspension bridge (2b) water surface floating solar heater (2) + impact with joint (80A) Accelerating the output increasing sphere (2E) provided with the reduction means (2G) + Accelerating gravity acceleration vertically downward + Keeping the heat insulating long lens (2d) and sunlight in the vicinity of the right angle near the vacuum Various energy storage cycle coalescing engines with increased power generation.
  341. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically + Long lens for fastening clamp (80B) Various energy storage cycle coalescing engines that increase the width of (2d) and increase the power generation amount.
  342. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing and tightening fastener (80B) Various energy storage cycle coalescing engines that use a set of multiple long lenses (2d) to increase power generation.
  343. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating solar heater (2) + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select production length lens (2d) from existing material is long Various energy storage cycle coalescing engines as a method of increasing power generation.
  344. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-section long lens (2d) from existing lens cross section Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase the amount of concentrated power generation.
  345. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズや太陽熱増大吊橋(2b)水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + long lens to enable vacuuming with fasteners (80B) and solar thermal suspension bridge (2b) water surface Floating solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens for heat insulation in the part close to vacuum (2d) ) And various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  346. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + surface floating type solar heater (2) + impact reduction Accelerating output increasing sphere (2E) provided with means (2G) + Accelerating gravitational acceleration + Accelerating vertically downward + Increasing the width of long lens (2d) for tightening split fastener (80B) to increase power generation Various energy conservation cycle coalescence engine as a method.
  347. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + surface floating type solar heater (2) + impact reduction Accelerate output augmenting sphere (2E) provided with means (2G) + Accelerate gravitational acceleration vertically + Divide and provide multiple sets of lens (2d) tightened with clamp (80B) to generate electricity Various energy storage cycle coalescing engines with increased quantity.
  348. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + surface floating type solar heater (2) + impact reduction Accelerating output increasing sphere (2E) provided with means (2G) + Accelerating gravitational acceleration vertically downward + Combined various energy conservation cycles with a method of increasing power generation by lengthening selected production length lens (2d) from existing materials organ.
  349. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + surface floating type solar heater (2) + impact reduction Accelerate the output increasing sphere (2E) provided with means (2G) + Accelerate gravitational acceleration vertically downward + Concentrated power generation of sunlight into air tube air (28a) with a long section lens (2d) selected from existing lens cross section Various energy storage cycle coalescing engines with increased quantity.
  350. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is installed in multiple stages to accelerate the coverage ratio critical material vertically downward + make the whole electrified house prime + surface floating type solar heater (2) + impact reduction Accelerate the output augmenting sphere (2E) provided with means (2G) + Accelerate gravity acceleration vertically downward + Keep heat-insulated long lens (2d) and sunlight near right angle in the part close to vacuum Various energy storage cycle coalescing engines with increased quantity.
  351. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structure and method for accelerating vertically downward at the compressed air speed + Putting battery-powered vehicles into full swing + Surface-floating solar heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Increase the width of the long lens (2d) tightening the split fastener (80B) to generate electricity Various energy storage cycle coalescing engines with increased quantity.
  352. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structure and method for accelerating vertically downward at the compressed air speed + Putting battery-powered vehicles into full swing + Surface-floating solar heater (2) + Accelerate output augmenting sphere (2E) with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Divide and provide multiple lens (2d) for tightening fastener (80B) as a set Combined with various energy storage cycle engines that have increased power generation.
  353. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structure and method for accelerating vertically downward at the compressed air speed + Putting battery-powered vehicles into full swing + Surface-floating solar heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select from existing materials Select a long lens (2d) to make the power generation amount increase method, and save various energy Cycle coalescence engine.
  354. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structure and method for accelerating vertically downward at the compressed air speed + Putting battery-powered vehicles into full swing + Surface-floating solar heater (2) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select cross-section long lens (2d) from existing lens cross-section to air tube air (28a) Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation.
  355. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+水面浮上型太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) Structure and method for accelerating vertically downward at the compressed air speed + Putting battery-powered vehicles into full swing + Surface-floating solar heater (2) + Accelerate the output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Keep heat-insulated long lens (2d) and sunlight in the vicinity of right angle near the vacuum Combined with various energy storage cycle engines that have increased power generation.
  356. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split fastener (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  357. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration is added vertically downward + Split and tightening tool (80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  358. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select production length from existing materials Various energy storage cycle coalescing engines with a long lens (2d) and a method of increasing power generation.
  359. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Selected cross section from existing lens cross section Various energy storage cycle coalescing engines that use a long lens (2d) to increase sunlight concentration into air tube air (28a).
  360. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + In the part approaching vacuum Various energy storage cycle coalescence engine that uses a heat insulating long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  361. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Compress the heat recovery + Accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + Accelerate the gravitational acceleration vertically + Split clamp (80B) Fastening of the long lens (2d) Various energy conservation cycle coalescing engines with increased width and increased power generation.
  362. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Compress the heat recovery + Accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + Accelerate the gravitational acceleration vertically downward + Divide and tighten the clamp (80B) multiple length lens ( Various energy storage cycle coalescing engines provided as a method for increasing power generation by providing 2d) as a set.
  363. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Compressing heat recovery + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing materials Long production lens (2d) is increased to increase power generation Various energy conservation cycle coalescence engine as a method.
  364. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Compressive heat recovery + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically + Select sunlight from the existing lens cross section with the selected cross-section length lens (2d) Various energy storage cycle coalescing engines with a method of increasing the amount of concentrated power generation in the tube air (28a).
  365. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Compressing heat recovery + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Heat insulation long lens (2d) and sunlight near the vacuum Is an energy conservation cycle coalescence engine that maintains power in the vicinity of a right angle and increases power generation.
  366. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Tightening of split fastener (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the attached long lens (2d).
  367. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressed heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additionally vertically downward + Clamping tool (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by providing a plurality of tightening long lenses (2d) as a set.
  368. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically downward + Select from existing materials Long lens ( Various energy storage cycle coalescing engines with 2d) as a method of increasing power generation.
  369. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically downward + Selected cross-section long lens from existing lens cross section (2d) Various energy storage cycle coalescing engines in which sunlight is converted into air pipe air (28a) in a concentrated power generation amount increasing method.
  370. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Heat insulation in the part close to vacuum Various energy storage cycle coalescing engines that maintain the long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  371. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Compress the heat recovery + Accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + Accelerate the gravitational acceleration vertically + Split clamp (80B) Fastening of the long lens (2d) Various energy conservation cycle coalescing engines with increased width and increased power generation.
  372. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Compress the heat recovery + Accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + Accelerate the gravitational acceleration vertically downward + Divide and tighten the clamp (80B) multiple length lens ( Various energy storage cycle coalescing engines provided as a method for increasing power generation by providing 2d) as a set.
  373. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Compressing heat recovery + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing materials Long production lens (2d) is increased to increase power generation Various energy conservation cycle coalescence engine as a method.
  374. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is provided in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Plural air pipe air (28a) Internal air (28a ) Compressive heat recovery + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically + Select sunlight from the existing lens cross section with the selected cross-section length lens (2d) Various energy storage cycle coalescing engines with a method of increasing the amount of concentrated power generation in the tube air (28a).
  375. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Compressing heat recovery + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Heat insulation long lens (2d) and sunlight near the vacuum Is an energy conservation cycle coalescence engine that maintains power in the vicinity of a right angle and increases power generation.
  376. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressed heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens (2d) for tightening split clamp (80B) ) Various energy storage cycle coalescing engines with increased power generation method.
  377. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) compressing heat recovery + accelerating the output increasing sphere (2E) provided with impact reducing means (2G) + accelerating gravitational acceleration vertically downward + splitting multiple lengths of fastening tool (80B) Various energy storage cycle coalescing engines that use a set of lenses (2d) to increase power generation.
  378. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressive heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select from existing material Generate long lens (2d) as long Various energy storage cycle coalescing engines with increased quantity.
  379. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressive heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select section long lens (2d) from sunlight Various energy storage cycle coalescing engines using a method for increasing the amount of power generation in the air pipe air (28a).
  380. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressive heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Insulating long lens (2d) near the vacuum Various energy conservation cycle coalescing engines that maintain the sunlight near right angles and increase power generation.
  381. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the split fastener (80B) is increased and the power generation amount is increased.
  382. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines that are divided and provided with a plurality of long lenses (2d) tightened with a fastener (80B) as a set to increase power generation.
  383. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescing engines with a method of increasing power generation by selecting a long lens (2d) that can be selected from existing materials.
  384. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy storage cycle coalescence engines that use a method of increasing the amount of concentrated power generation from the existing lens cross section to the air tube air (28a) with the selected cross section long lens (2d).
  385. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additional vertically downward + Various energy conservation cycle coalescing engines that use a heat insulating long lens (2d) and sunlight in the vicinity of a right angle in the vicinity of vacuum to increase power generation.
  386. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) With heat pump (1G) to accelerate heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Split clamp (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  387. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) With heat pump (1G) + accelerating output increasing sphere (2E) with impact reduction means (2G) + accelerating gravitational acceleration vertically downward + splitting and tightening clamp (80B) Various energy storage cycle coalescing engines with a plurality of long lenses (2d) attached as a set to increase power generation.
  388. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heat recovery with compression pump (1G) + Accelerate output sphere (2E) with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Select from existing material Long lens (2d) Various energy storage cycle coalescing engine with a long and large power generation method.
  389. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) With a heat pump (1G) + accelerating the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerating the gravitational acceleration vertically downward + selecting the long lens (2d) ) Various energy conservation cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  390. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) With heat pump (1G) to compress heat recovery + Accelerate output sphere (2E) with shock reduction means (2G) + Accelerate gravity acceleration vertically downward + Insulate long lens close to vacuum (2d) and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase the power generation amount.
  391. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration additionally vertically downward + Tightening Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the attachment (80B) is increased and the power generation amount is increased.
  392. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) is recovered by compression heat recovery with heat pump (1G) + Accelerating output increase sphere (2E) provided with impact reduction means (2G) + Gravity acceleration is accelerated + divided vertically downward Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a clamp (80B).
  393. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) with heat pump (1G) recovering compression heat + Accelerating output increasing sphere (2E) with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Existing materials Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the production long lens (2d) long.
  394. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) with heat pump (1G) recovering compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Existing lens Various energy storage cycle coalescence engines that use a method for increasing the amount of concentrated power generation from sunlight to air pipe air (28a) with a long section lens (2d) selected from the cross section.
  395. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) is recovered by heat pump (1G) by compressing heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Vacuum Various energy conservation cycle coalescence engines that use a heat insulating long lens (2d) and sunlight at a right angle near the approaching part to increase power generation.
  396. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is provided in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Plural air pipe air (28a) Internal air (28a ) With heat pump (1G) to accelerate heat recovery + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Split clamp (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  397. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is provided in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Plural air pipe air (28a) Internal air (28a ) With heat pump (1G) + accelerating output increasing sphere (2E) with impact reduction means (2G) + accelerating gravitational acceleration vertically downward + splitting and tightening clamp (80B) Various energy storage cycle coalescing engines with a plurality of long lenses (2d) attached as a set to increase power generation.
  398. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine is provided in multiple stages to accelerate the coverage ratio critical material vertically downward + Make the whole electrified house prime + Plural air pipe air (28a) Internal air (28a ) Heat recovery with compression pump (1G) + Accelerate output sphere (2E) with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Select from existing material Long lens (2d) Various energy storage cycle coalescing engine with a long and large power generation method.
  399. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) With a heat pump (1G) + accelerating the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerating the gravitational acceleration vertically downward + selecting the long lens (2d) from the cross section of the existing lens ) Various energy conservation cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  400. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) With heat pump (1G) to compress heat recovery + Accelerate output sphere (2E) with shock reduction means (2G) + Accelerate gravity acceleration vertically downward + Insulate long lens close to vacuum (2d) and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase the power generation amount.
  401. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressive heat recovery with heat pump (1G) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Tighten split fastener (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the attached long lens (2d).
  402. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressing heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Dividing and tightening tool (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by providing a plurality of tightening long lenses (2d) as a set.
  403. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressive heat recovery with heat pump (1G) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Select manufacturing long lens from existing material ( Various energy storage cycle coalescing engines with 2d) as a method of increasing power generation.
  404. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressive heat recovery with heat pump (1G) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section length lens from existing lens cross section (2d) Various energy storage cycle coalescing engines in which sunlight is converted into air pipe air (28a) in a concentrated power generation amount increasing method.
  405. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Compressive heat recovery with heat pump (1G) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Heat insulation in the part close to vacuum Various energy storage cycle coalescing engines that maintain the long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  406. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Heat of water (52b) by compression heat recovery device (2C) by compression heat + Acceleration of output increase sphere (2E) provided with impact reduction means (2G) + Gravity acceleration Various energy storage cycle coalescing engines that use a method of increasing the amount of power generation by increasing the width of the long lens (2d) for acceleration + split fastener (80B) tightening vertically downward.
  407. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Heat of water (52b) by compression heat recovery device (2C) by compression heat + Acceleration of output increase sphere (2E) provided with impact reduction means (2G) + Gravity acceleration Additional energy storage cycle coalescing engine with a method of increasing power generation by accelerating + dividing vertically and dividing and providing a set of multiple long lenses (2d) for tightening the fastener (80B).
  408. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Heat of water (52b) by compression heat recovery device (2C) by compression heat + Acceleration of output increase sphere (2E) provided with impact reduction means (2G) + Gravity acceleration Accelerating vertically downward + Select from existing materials Long production lens (2d) is used as a method for increasing the amount of power generation.
  409. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Heat of water (52b) by compression heat recovery device (2C) by compression heat + Acceleration of output increase sphere (2E) provided with impact reduction means (2G) + Gravity acceleration Accelerating vertically downward + Various energy storage cycle coalescence engine using a method of increasing the amount of concentrated power generation in the air tube air (28a) with the long lens (2d) selected from the cross section of the existing lens.
  410. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Heat of water (52b) by compression heat recovery device (2C) by compression heat + Acceleration of output increase sphere (2E) provided with impact reduction means (2G) + Gravity acceleration Accelerating vertically downward + Long-heat-insulated lens (2d) in the part approaching the vacuum and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase power generation.
  411. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + Split tightening Various energy storage cycle coalescing engines that use a method of increasing power generation by increasing the width of the long lens (2d) for tightening the tool (80B).
  412. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration + dividing vertically Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a fastener (80B).
  413. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increase sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + From existing material Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the selected production long lens (2d) long.
  414. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Cross section of existing lens Various energy storage cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long section (2d).
  415. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + approaching vacuum Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation by maintaining the heat insulating long lens (2d) and sunlight in the vicinity of a right angle at the part.
  416. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressed heat recovery unit (2C) heats water (52b) with compression heat + Accelerates output increasing sphere (2E) with impact reduction means (2G) + Adds gravitational acceleration Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating and dividing fastener (80B) tightening vertically downward.
  417. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressed heat recovery unit (2C) heats water (52b) with compression heat + Accelerates output increasing sphere (2E) with impact reduction means (2G) + Adds gravitational acceleration Various energy conservation cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated + divided vertically and tightened with a fastener (80B).
  418. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressed heat recovery unit (2C) heats water (52b) with compression heat + Accelerates output increasing sphere (2E) with impact reduction means (2G) + Adds gravitational acceleration Accelerating vertically downward + Selective long-length lens (2d) made from existing materials Various energy storage cycle coalescing engines with a method of increasing power generation.
  419. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressed heat recovery unit (2C) heats water (52b) with compression heat + Accelerates output increasing sphere (2E) with impact reduction means (2G) + Adds gravitational acceleration Accelerating vertically downward + Various energy storage cycle coalescence engine that uses solar light to air tube air (28a) with a long section (2d) selected from existing lens cross-section to increase concentrated power generation.
  420. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressed heat recovery unit (2C) heats water (52b) with compression heat + Accelerates output increasing sphere (2E) with impact reduction means (2G) + Adds gravitational acceleration Various energy conservation cycle coalescence engines that use a method of increasing power generation by maintaining a long lens (2d) of heat insulation and sunlight in the vicinity of a right angle in a portion close to acceleration + vacuum in the vertically downward direction.
  421. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + Split tightening Various energy storage cycle coalescing engines that use a method of increasing power generation by increasing the width of the long lens (2d) for tightening the tool (80B).
  422. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration + dividing vertically Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a fastener (80B).
  423. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increase sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + From existing material Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the selected production long lens (2d) long.
  424. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Cross section of existing lens Various energy storage cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long section (2d).
  425. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + approaching vacuum Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation by maintaining the heat insulating long lens (2d) and sunlight in the vicinity of a right angle at the part.
  426. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration further downward + splitting Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the fastener (80B) is increased and the power generation amount is increased.
  427. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compression heat recovery unit (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration further downward + splitting Various energy storage cycle coalescing engines provided with a plurality of long lenses (2d) for fastening the fastener (80B) as a set to increase the power generation amount.
  428. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Existing Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the production long lens (2d) long from the material.
  429. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Existing Various energy conservation cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight to air pipe air (28a) with a lens having a long section (2d) selected from the lens section.
  430. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱により圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compression heat recovery device (2C) by compression heat + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration further vertically downward + Vacuum Various energy conservation cycle coalescence engines that use a heat generation long lens (2d) and sunlight in the vicinity of the right angle to maintain a right angle in the vicinity.
  431. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Heated water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating + dividing fastener (80B) tightening downward.
  432. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Heated water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically Various energy storage cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided downward and tightened with a fastener (80B).
  433. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Heated water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically Accelerating downward + Various energy storage cycle coalescing engines with a method of increasing power generation by making the long lens (2d) selected from existing materials longer.
  434. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Heated water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically Accelerating downward + Combined engine with various energy storage cycles using a method of increasing the amount of concentrated power generation in the air tube air (28a) with the lens (2d) selected from the cross section of the existing lens.
  435. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Heated water (52b) with compressed air calorie (28b) of internal air (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically Various energy conservation cycle coalescence engines that use a method of increasing power generation by maintaining the long lens (2d) and sunlight in the vicinity of a right angle near the acceleration + vacuum near the bottom.
  436. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split fastener (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  437. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration additionally vertically downward + Tightening tool (80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  438. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select production length from existing materials Various energy storage cycle coalescing engines with a long lens (2d) and a method of increasing power generation.
  439. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heat water (52b) with compressed air calorie (28b) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section from existing lens cross section Various energy storage cycle coalescing engines that use a long lens (2d) to increase sunlight concentration into air tube air (28a).
  440. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + In the part approaching vacuum Various energy storage cycle coalescence engine that uses a heat insulating long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  441. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Heat the water (52b) with the compressed air calorie (28b) of the air (28a) internal air (28a) + accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + addition of gravitational acceleration downward vertically Various energy storage cycle coalescing engines with a method of increasing the power generation amount by increasing the width of the long lens (2d) for accelerating + dividing fastener (80B).
  442. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Heat the water (52b) with the compressed air calorie (28b) of the air (28a) internal air (28a) + accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + addition of gravitational acceleration downward vertically Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of a plurality of long lenses (2d) for accelerating + dividing and fastening fasteners (80B).
  443. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Heat the water (52b) with the compressed air calorie (28b) of the air (28a) internal air (28a) + accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + addition of gravitational acceleration downward vertically Accelerating + Combined engine of various energy conservation cycles with a long production length lens (2d) selected from existing materials and a method of increasing power generation.
  444. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Heat the water (52b) with the compressed air calorie (28b) of the air (28a) internal air (28a) + accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + addition of gravitational acceleration downward vertically Accelerating + Combined engine of various energy conservation cycles using a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long lens (2d) selected from the cross section of the existing lens.
  445. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Heat the water (52b) with the compressed air calorie (28b) of the air (28a) internal air (28a) + accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + addition of gravitational acceleration downward vertically Various energy conservation cycle coalescing engines with a method of increasing power generation by maintaining heat-insulated long lens (2d) and sunlight in the vicinity of a right angle near the acceleration + vacuum.
  446. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Split fastener (80B) ) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  447. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration additionally vertically downward + Tightening tool (80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  448. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select production length from existing materials Various energy storage cycle coalescing engines with a long lens (2d) and a method of increasing power generation.
  449. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heat water (52b) with compressed air calorie (28b) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section from existing lens cross section Various energy storage cycle coalescing engines that use a long lens (2d) to increase sunlight concentration into air tube air (28a).
  450. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + In the part approaching vacuum Various energy storage cycle coalescence engine that uses a heat insulating long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  451. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air Heating water (52b) with compressed air calorie (28b) of (28a) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically + Split fastener (80B) Various energy storage cycle coalescing engines in which the width of the tightening long lens (2d) is increased and the power generation amount is increased.
  452. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air Heating water (52b) with compressed air calorie (28b) (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration additionally vertically downward and tightening Various energy storage cycle coalescing engines in which a plurality of long lenses (2d) tightened with attachments (80B) are provided as a set to increase power generation.
  453. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air Heating water (52b) with compressed air calorie (28b) of (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration downward + Select from existing materials Various energy storage cycle coalescing engines with a long production length lens (2d) and a method of increasing power generation.
  454. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air Heating water (52b) with compressed air calorie (28b) of (28a) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + From existing lens cross section Various energy storage cycle coalescing engines that use a method of increasing the amount of concentrated power generation with sunlight in the air tube air (28a) with the selected cross-section long lens (2d).
  455. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air Heating water (52b) with compressed air calorie (28b) of (28a) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically + approaching vacuum Various energy conservation cycle coalescence engine that uses a long lens (2d) that is thermally insulated and sunlight in the vicinity of a right angle to increase power generation.
  456. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) Heated water (52b) with compressed air calorie (28b) + Enables liquid oxygen injection fuel injection combustion + Output increasing sphere (2E) provided with impact reduction means (2G) ) + Gravitational acceleration added vertically downward + various energy storage cycle coalescing engines with a method of increasing the power generation amount by increasing the width of the long lens (2d) for tightening the split fastener (80B).
  457. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) Heated water (52b) with compressed air calorie (28b) + Enables liquid oxygen injection fuel injection combustion + Output increasing sphere (2E) provided with impact reduction means (2G) ) + Gravitational acceleration is accelerated + divided vertically and divided into various energy storage cycle coalescing engines in which a plurality of long lenses (2d) tightened with a fastener (80B) are provided as a set to increase power generation.
  458. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) Heated water (52b) with compressed air calorie (28b) + Enables liquid oxygen injection fuel injection combustion + Output increasing sphere (2E) provided with impact reduction means (2G) ) + Accelerate gravity acceleration + Accelerate vertically downward + Various energy conservation cycle coalescing engine with a method of increasing the power generation amount by selecting a long production lens (2d) from existing materials.
  459. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) Heated water (52b) with compressed air calorie (28b) + Enables liquid oxygen injection fuel injection combustion + Output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration + Accelerate vertically downward + Various energy storage cycle coalescing engines using a method of increasing concentrated power generation to air tube air (28a) from the existing lens cross-section with a long lens (2d).
  460. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air pipe air (28a) Internal air (28a) Heated water (52b) with compressed air calorie (28b) + Enables liquid oxygen injection fuel injection combustion + Output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration + Accelerate vertically downward + Combined various energy storage cycle engines that maintain heat insulation long lens (2d) and sunlight near right angle in the part close to vacuum.
  461. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating + dividing fastener (80B) tightening downward.
  462. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy storage cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided downward and tightened with a fastener (80B).
  463. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Accelerating downward + Various energy storage cycle coalescing engines with a method of increasing power generation by making the long lens (2d) selected from existing materials longer.
  464. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Accelerating downward + Combined engine with various energy storage cycles using a method of increasing the amount of concentrated power generation in the air tube air (28a) with the lens (2d) selected from the cross section of the existing lens.
  465. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy conservation cycle coalescence engines that use a method of increasing power generation by maintaining the long lens (2d) and sunlight in the vicinity of a right angle near the acceleration + vacuum near the bottom.
  466. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reduction means (2G) Accelerating + Gravitational acceleration added Accelerating vertically downward + Various energy storage cycle coalescing engines using the method of increasing power generation by increasing the width of the long lens (2d) for tightening the split fastener (80B).
  467. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reduction means (2G) Accelerating + Accelerating gravitational acceleration + Vertically accelerating + splitting and combining multiple long-lens lenses (2d) tightened with a fastener (80B) as a set, and various energy storage cycle coalescing engines using a method for increasing power generation.
  468. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reduction means (2G) Accelerating + Accelerating gravity acceleration Accelerating vertically downward + Various energy conservation cycle coalescing engines with a method of increasing power generation by making the selected production length lens (2d) long from existing materials.
  469. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reduction means (2G) Accelerate + Gravity acceleration added vertically downward + Various energy storage cycle coalescence engine that uses concentrated lens power generation method to increase sunlight generation into air tube air (28a) from the existing lens cross section with a selected cross section long lens (2d).
  470. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + output increasing sphere (2E) provided with impact reduction means (2G) Accelerating + Accelerating gravitational acceleration + Accelerating vertically downward + Various energy conservation cycle coalescing engines that maintain heat insulation long lens (2d) and sunlight in the vicinity of a right angle near the vacuum and increase power generation.
  471. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating + dividing fastener (80B) tightening downward.
  472. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy storage cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided downward and tightened with a fastener (80B).
  473. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Accelerating downward + Various energy storage cycle coalescing engines with a method of increasing power generation by making the long lens (2d) selected from existing materials longer.
  474. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Accelerating downward + Combined engine with various energy storage cycles using a method of increasing the amount of concentrated power generation in the air tube air (28a) with the lens (2d) selected from the cross section of the existing lens.
  475. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + additional gravity acceleration vertical Various energy conservation cycle coalescence engines that use a method of increasing power generation by maintaining the long lens (2d) and sunlight in the vicinity of a right angle near the acceleration + vacuum near the bottom.
  476. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + gravity acceleration Additional energy storage cycle coalescing engine with a method of increasing power generation by increasing the width of the long lens (2d) for accelerating + dividing fastener (80B) tightening vertically downward.
  477. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + gravity acceleration Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided vertically below and tightened with a fastener (80B).
  478. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + gravity acceleration Accelerated vertically below + Combined engine with various energy storage cycles using a method of increasing power generation by selecting a long lens (2d), which is selected from existing materials.
  479. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + gravity acceleration Additional energy storage cycle coalescence engine that accelerates vertically downward + existing lens cross section and selects cross section long lens (2d) to increase solar energy into air tube air (28a).
  480. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + gravity acceleration Additional energy storage cycle coalescing engine with a method of increasing power generation by maintaining heat-insulated long lens (2d) and sunlight in the vicinity of a right angle in the portion near acceleration + vacuum in the vertical direction.
  481. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Compressive calorie increases vaporization explosion force to the maximum + Accelerates the output increase sphere (2E) with impact reduction means (2G) + Accelerates gravitational acceleration vertically downward + Split Various energy storage cycle coalescing engines in which the width of the long lens (2d) for tightening the fastener (80B) is increased and the power generation amount is increased.
  482. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Compressive calorie increases vaporization explosion force to the maximum + Accelerates the output increase sphere (2E) with impact reduction means (2G) + Accelerates gravitational acceleration vertically downward + Split Various energy storage cycle coalescing engines provided with a plurality of long lenses (2d) for fastening the fastener (80B) as a set to increase the power generation amount.
  483. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Compressive calorie increases vaporization explosive force to the maximum + Accelerates the output increasing sphere (2E) with impact reduction means (2G) + Accelerates gravitational acceleration vertically + Existing Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the production long lens (2d) long from the material.
  484. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Compressive calorie increases vaporization explosive force to the maximum + Accelerates the output increasing sphere (2E) with impact reduction means (2G) + Accelerates gravitational acceleration vertically + Existing Various energy conservation cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight to air pipe air (28a) with a lens having a long section (2d) selected from the lens section.
  485. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Multiple Sides Air tube air (28a) Internal air (28a) Increase in vaporization and explosion force to the maximum by the amount of compression heat + Accelerate output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration additionally vertically downward + Vacuum Various energy conservation cycle coalescence engines that use a heat generation long lens (2d) and sunlight in the vicinity of the right angle to maintain a right angle in the vicinity.
  486. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Length of split clamp (80B) tightening Various energy storage cycle coalescing engines with increased power generation by increasing the width of the lens (2d).
  487. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate the gravitational acceleration vertically + Divide and tighten the clamp (80B) Various energy storage cycle coalescing engines that use a plurality of long lenses (2d) as a set to increase power generation.
  488. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Maximum increase in vaporization explosive force with compression heat amount + Accelerate output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select manufacturing long lens (2d) from existing material Various energy storage cycle coalescing engine that is a long and large power generation method.
  489. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section length lens from existing lens cross section (2d) Various energy storage cycle coalescing engines that use sunlight as a method of increasing the amount of power generation in air tube air (28a).
  490. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravity acceleration power generation output generation equipment method that makes turbine blades around 1/10 + long lens (2d) that is long with joint (80A) multiple air pipe air (28a) internal air (28a) ) Maximum increase in vaporization explosive force by the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Insulate long lens (close to vacuum) 2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  491. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressive calorie increases vaporization explosion force to the maximum + Accelerates output sphere (2E) with impact reduction means (2G) + Accelerates gravitational acceleration vertically + Split tightening Various energy storage cycle coalescing engines that use a method of increasing power generation by increasing the width of the long lens (2d) for tightening the tool (80B).
  492. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Increases vaporization explosion force to the maximum with the amount of compression heat + Accelerates the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerates gravitational acceleration vertically + divided Various energy storage cycle coalescing engines with a method of increasing power generation by providing a set of multiple long lenses (2d) for tightening a fastener (80B).
  493. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressive calorie increases maximum vaporization explosive force + Accelerates output increase sphere (2E) with impact reduction means (2G) + Accelerates gravitational acceleration vertically downward + From existing materials Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by making the selected production long lens (2d) long.
  494. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Increase in vaporization explosion force to the maximum by the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Cross section of existing lens Various energy storage cycle coalescence engines that use a method of increasing the amount of concentrated power generation from sunlight into air tube air (28a) with a long section (2d).
  495. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate specific critical materials vertically and vertically + Long lens (2d) that allows vacuuming with fasteners (80B) Air (28a) Internal air (28a) Compressive calorie increases maximum vaporization explosive force + Accelerates output increasing sphere (2E) provided with impact reduction means (2G) + Gravitational acceleration added vertically downward + Closed to vacuum Various energy conservation cycle coalescing engines with a method of increasing the amount of power generation by maintaining the heat insulating long lens (2d) and sunlight in the vicinity of a right angle at the part.
  496. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Length of split clamp (80B) tightening Various energy storage cycle coalescing engines with increased power generation by increasing the width of the lens (2d).
  497. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate the gravitational acceleration vertically + Divide and tighten the clamp (80B) Various energy storage cycle coalescing engines that use a plurality of long lenses (2d) as a set to increase power generation.
  498. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Maximum increase in vaporization explosive force with compression heat amount + Accelerate output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select manufacturing long lens (2d) from existing material Various energy storage cycle coalescing engine that is a long and large power generation method.
  499. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section length lens from existing lens cross section (2d) Various energy storage cycle coalescing engines that use sunlight as a method of increasing the amount of power generation in air tube air (28a).
  500. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravitational Acceleration Power Generation Turbine Structures and Methods for Accelerating Coverage Ratio Critical Substances Vertically Downward + Fully Electrified House Prime + Multiple Side-by-side Air Tube Air (28a) Internal Air (28a ) Maximum increase in vaporization explosive force by the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Insulate long lens (close to vacuum) 2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  501. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Maximum increase in vaporization explosive force by the amount of compressive heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Split clamp (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  502. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Increase in vaporization explosive force to the maximum with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + Accelerate the gravitational acceleration vertically downward + Divide and clamp (80B) Various energy storage cycle coalescing engines that use a set of tightening multiple long lenses (2d) as a set to increase power generation.
  503. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Increase in vaporization explosive force to the maximum with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with the impact reducing means (2G) + Accelerate gravitational acceleration vertically downward + Select from existing materials Long lens (2d ) Is an energy storage cycle coalescence engine with a method of increasing power generation.
  504. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Maximum increase in vaporization explosive force by compression heat amount + Accelerate output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select long lens from existing lens cross section ( 2d) Various energy storage cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  505. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を圧縮空気速度で垂直下方に加速する構造や方法+蓄電池駆動各種自動車類全盛にする+複数併設型空気管空気(28a)内部空気(28a)圧縮熱量で気化爆発力最大に増大+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Output Increase Sphere (2E) Structure and method for accelerating vertically downward with compressed air speed + Battery-powered various automobiles primed + Plural air pipe air (28a) Internal air (28a) Maximum increase in vaporization explosive force with the amount of compression heat + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Length of heat insulation near the vacuum Various energy storage cycle coalescing engines that maintain the lens (2d) and sunlight in the vicinity of a right angle and increase the power generation amount.
  506. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided output increasing sphere (2E) + Accelerate gravitational acceleration vertically + Various energy as a method for increasing power generation by increasing the width of the long lens (2d) for tightening the split fastener (80B) Conservation cycle coalescence organization.
  507. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided output sphere (2E) + Accelerate the gravitational acceleration vertically downward + Divide and provide a set of multiple long lenses (2d) for fastening the fastener (80B) to increase the power generation amount Various energy conservation cycle coalescence engine.
  508. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerating the provided power increasing sphere (2E) + Accelerating gravitational acceleration vertically downward + Various energy storage cycle coalescing engines using a method of increasing the power generation amount by making the selected production length lens (2d) long from existing materials.
  509. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided power increasing sphere (2E) + Accelerate gravity acceleration vertically downward + Select a long section lens (2d) from the existing lens cross section to increase the amount of concentrated power generation to the air tube air (28a) Various energy conservation cycle coalescence engine.
  510. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided output sphere (2E) + Accelerate the gravitational acceleration vertically downward + Keep the heat-insulated long lens (2d) and sunlight in the vicinity of the right angle near the vacuum to increase the amount of power generation Various energy conservation cycle coalescence engine.
  511. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided output increasing sphere (2E) + Accelerate gravitational acceleration vertically + Various energy as a method for increasing power generation by increasing the width of the long lens (2d) for tightening the split fastener (80B) Conservation cycle coalescence organization.
  512. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided output sphere (2E) + Accelerate the gravitational acceleration vertically downward + Divide and provide a set of multiple long lenses (2d) for fastening the fastener (80B) to increase the power generation amount Various energy conservation cycle coalescence engine.
  513. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerating the provided power increasing sphere (2E) + Accelerating gravitational acceleration vertically downward + Various energy storage cycle coalescing engines using a method of increasing the power generation amount by making the selected production length lens (2d) long from existing materials.
  514. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided power increasing sphere (2E) + Accelerate gravity acceleration vertically downward + Select a long section lens (2d) from the existing lens cross section to increase the amount of concentrated power generation to the air tube air (28a) Various energy conservation cycle coalescence engine.
  515. 理論最良エンジン空気力太陽光重力加速度発電出力増大球(2E)を真空で垂直下方に吸引加速する構成や方法+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Output Increase Sphere (2E) A structure or method for sucking and accelerating vertically downward in vacuum + Solar thermal increase suspension bridge (2b) Solar heater (2) + Impact reduction means (2G) Accelerate the provided output sphere (2E) + Accelerate the gravitational acceleration vertically downward + Keep the heat-insulated long lens (2d) and sunlight in the vicinity of the right angle near the vacuum to increase the amount of power generation Various energy conservation cycle coalescence engine.
  516. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Increase the width of the long lens (2d) for tightening the split fastener (80B) Various energy storage cycle coalescing engines with increased power generation.
  517. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Split multiple length lens (2d) tightened with clamp (80B) as a set Various energy storage cycle coalescing engines that have been installed to increase power generation.
  518. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select energy from existing materials Various lengths of energy as a method of increasing power generation by making long lens (2d) long Conservation cycle coalescence organization.
  519. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravity acceleration vertically downward + Select pipe length from existing lens cross section long lens (2d) to air tube air (28a) Various energy storage cycle coalescing engines that are used as a method of increasing the amount of power generation.
  520. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) + Accelerate output augmenting sphere (2E) equipped with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Keep heat-insulated long lens (2d) and sunlight near right angle near vacuum Various energy storage cycle coalescing engines that are used to increase power generation.
  521. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Air (28a) compression heat recovery + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Long lens for split clamp (80B) tightening ( Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of 2d).
  522. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Air (28a) is recovered by heat with a heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Split fastener (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  523. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat the water (52b) with the compression heat recovery unit (2C) + accelerate the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerate the gravitational acceleration vertically + divided fasteners (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the tightening long lens (2d).
  524. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Multi-Vessel Battery Driven Vessels + Air Tube Air (28a) Internal Air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Tightening of split fastener (80B) Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the attached long lens (2d).
  525. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Various energy storage cycle coalescing engines with a method of increasing the amount of power generation by increasing the width of the long lens (2d) for accelerating + split fastener (80B).
  526. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Recover air (28a) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically further + Divide and tighten multiple fasteners (80B) Various energy storage cycle coalescing engines with a long lens (2d) as a set to increase power generation.
  527. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Compress air (28a) with heat pump (1G) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Split fastener ( 80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  528. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heating the water (52b) with the compression heat recovery unit (2C) + accelerating the output increasing sphere (2E) provided with the impact reduction means (2G) + accelerating the gravitational acceleration additionally vertically downward + 80B) Various energy storage cycle coalescing engines in which a plurality of tightened long lenses (2d) are provided as a set to increase power generation.
  529. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Multi-Vessel Battery Driven Vessels + Air Tube Air (28a) Internal Air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing and tightening tool (80B ) Various energy storage cycle coalescing engines with a method of increasing power generation by providing a plurality of tightening long lenses (2d) as a set.
  530. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Various energy storage cycle coalescing engines that use a method of increasing power generation by providing a set of multiple long lenses (2d) that are accelerated and divided and tightened with a fastener (80B).
  531. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Air (28a) is recovered by heat of compression + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Select from existing material Long lens (2d) is made long Various energy storage cycle coalescing engines with increased power generation.
  532. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Air (28a) is recovered by compressing heat with a heat pump (1G) + Accelerating the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select from existing materials Various energy storage cycle coalescing engines in which (2d) is long and the power generation amount is increased.
  533. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat water (52b) with compression heat recovery unit (2C) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select production length lens from existing material Various energy storage cycle coalescing engines in which (2d) is long and the power generation amount is increased.
  534. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Multi-Vessel Battery Driven Vessels + Air Tube Air (28a) Internal Air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select manufacturing long lens from existing material ( Various energy storage cycle coalescing engines with 2d) as a method of increasing power generation.
  535. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Accelerating + Combined engine of various energy storage cycles with a method of increasing power generation by making the long lens (2d) selected from existing materials long.
  536. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Compress air for recovering air (28a) + Accelerate output sphere (2E) provided with impact reducing means (2G) + Accelerate gravitational acceleration vertically + Select lens from the cross section of the existing lens Various energy storage cycle coalescing engine that uses light as air tube air (28a) to increase concentrated power generation.
  537. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Air (28a) compressed heat recovery with heat pump (1G) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Selected cross section length from existing lens cross section Various energy conservation cycle coalescing engines that use a lens (2d) to increase the amount of concentrated power generation from sunlight into air tube air (28a).
  538. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heat water (52b) with compression heat recovery unit (2C) + Accelerate output sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically + Select cross section length from existing lens cross section Various energy conservation cycle coalescing engines that use a lens (2d) to increase the amount of concentrated power generation from sunlight into air tube air (28a).
  539. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Multi-Vessel Battery Driven Vessels + Air Tube Air (28a) Internal Air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Select cross-sectional length lens from existing lens cross section (2d) Various energy storage cycle coalescing engines in which sunlight is converted into air pipe air (28a) in a concentrated power generation amount increasing method.
  540. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Accelerating + Combined engine with various energy storage cycles using a method of increasing the amount of concentrated power generation in the air tube air (28a) by using a lens (2d) with a long section (2d) from the cross section of the existing lens.
  541. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Air (28a) is recovered by heat of compression + Accelerating the output increasing sphere (2E) provided with the impact reducing means (2G) + Accelerating the gravitational acceleration vertically + Long lens (2d) for heat insulation at the part close to the vacuum And various energy conservation cycle coalescence engines that maintain solar power near right angles and increase power generation.
  542. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Air (28a) is compressed with heat recovery by heat pump (1G) + Accelerating output increase sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Insulation at the part approaching vacuum Long energy lens (2d) and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase power generation.
  543. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heating water (52b) with compression heat recovery unit (2C) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Heat insulation in the part close to vacuum Long energy lens (2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle and increase power generation.
  544. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Multi-Vessel Battery Driven Vessels + Air Tube Air (28a) Internal Air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Heat insulation in the part close to vacuum Various energy storage cycle coalescing engines that maintain the long lens (2d) and sunlight in the vicinity of a right angle to increase power generation.
  545. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Accelerating + Combined engine with various energy conservation cycles that uses a heat-insulating long lens (2d) and sunlight in the vicinity of a right angle in the part close to vacuum to increase power generation.
  546. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Various energy storage cycle coalescence engines that use air (28a) as a power generation method that accelerates the output increasing sphere (2E) provided with compression heat recovery + impact reduction means (2G) + accelerates gravitational acceleration vertically downward.
  547. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+長レンズ(2d)内空気管空気(28a)内部空気(28a)を熱ポンプ(1G)で圧縮熱回収+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine structure and method for accelerating the coated mercury vertically downwards + accelerating various battery-powered vessels + long lens (2d) air tube air (28a) inside Various types of energy storage using air (28a) with heat pump (1G), generating heat by compressing heat + accelerating output increasing sphere (2E) provided with impact reduction means (2G) + accelerating gravitational acceleration vertically downward Cycle coalescence engine.
  548. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)を圧縮圧縮熱回収器(2C)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Making Storage Battery-Driven Vessels Prime + Air Tube Air (28a) Internal Air (28a) Compressed Heating water (52b) with compression heat recovery unit (2C) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Power generation method for accelerating gravitational acceleration vertically downward Cycle coalescence engine.
  549. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+空気管空気(28a)内部空気(28a)熱量の圧縮空気熱量(28b)で水(52b)を加熱+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically + Multi-Vessel Battery Driven Vessels + Air Tube Air (28a) Internal Air (28a) Heating water (52b) with compressed air calorie (28b) + Accelerating output augmenting sphere (2E) provided with impact reduction means (2G) + Additional energy storage cycle as a power generation method for accelerating gravitational acceleration vertically downward Combined organization.
  550. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆水銀を垂直下方に加速する構造や方法+蓄電池駆動各種船舶類全盛にする+太陽熱増大吊橋(2b)太陽光加熱器(2)圧縮空気熱量(28b)で水(52b)を加熱+液体酸素圧入燃料噴射燃焼を可能にする+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速する発電方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Mercury Vertically Down + Accelerating Storage Battery Driven Various Ships + Solar Thermal Suspension Bridge (2b) Solar Heater (2) Heating water (52b) with compressed air calorie (28b) + enabling liquid oxygen injection fuel injection combustion + accelerating output increasing sphere (2E) with impact reduction means (2G) + adding gravity acceleration vertically downward Various energy conservation cycle coalescing engines that have been accelerated to generate electricity.
  551. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Lifting Pump (1H) Increasing Head with Increased Ball Lifting Device (2F) + Solar Thermal Increase Suspension Bridge (2b) Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically + Long lens for split clamp (80B) tightening ( Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of 2d).
  552. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Lifting Pump (1H) Increasing Head with Increased Ball Lifting Device (2F) + Solar Thermal Increase Suspension Bridge (2b) Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravity acceleration vertically downward + Dividing multiple fasteners (80B) Various energy storage cycle coalescing engines with a long lens (2d) as a set to increase power generation.
  553. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Lifting Pump (1H) Increasing Head with Increased Ball Lifting Device (2F) + Solar Thermal Increase Suspension Bridge (2b) Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Select from existing material Long manufacturing lens (2d) Various energy storage cycle coalescing engines with increased power generation.
  554. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Lifting Pump (1H) Increasing Head with Increased Ball Lifting Device (2F) + Solar Thermal Increase Suspension Bridge (2b) Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross-section long lens (2d) from existing lens section Various energy storage cycle coalescing engine that uses light as air tube air (28a) to increase concentrated power generation.
  555. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて鋼球を垂直下方に加速する構造や方法+揚水ポンプ(1H)増大球上昇装置(2F)で落差増大+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Power Generation Turbine Structures and Methods for Accelerating Steel Balls Vertically Down + Lifting Pump (1H) Increasing Head with Increased Ball Lifting Device (2F) + Solar Thermal Increase Suspension Bridge (2b) Equivalent solar heater (2) + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens (2d) for heat insulation in the part close to vacuum And various energy conservation cycle coalescence engines that maintain solar power near right angles and increase power generation.
  556. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Solar Thermal Suspension Suspension Bridge (2b) Solar heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Split fastener (80B) tightening Various energy storage cycle coalescing engines with a method of increasing power generation by increasing the width of the long lens (2d).
  557. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Solar Thermal Suspension Suspension Bridge (2b) Solar heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing and tightening clamp (80B) Various energy storage cycle coalescing engines with a plurality of long lenses (2d) attached as a set to increase power generation.
  558. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Solar Thermal Suspension Suspension Bridge (2b) Solar heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select from existing materials Long lens (2d) Various energy storage cycle coalescing engine with a long and large power generation method.
  559. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Solar Thermal Suspension Suspension Bridge (2b) Solar heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Selecting long lens (2d) from existing lens cross section ) Various energy conservation cycle coalescence engines that use sunlight as air tube air (28a) to increase concentrated power generation.
  560. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆鋼球を垂直下方に加速する構造や方法+耐熱材(2A)断熱材(2c)半筒外箱(77B)+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine Structures and Methods for Accelerating Coated Steel Balls Vertically Down + Heat Resistant Material (2A) Heat Insulation Material (2c) Half-Cylinder Outer Box (77B) + Solar Thermal Suspension Suspension Bridge (2b) Solar heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically + Long lens for heat insulation in the part close to vacuum (2d) and various energy conservation cycle coalescence engines that maintain sunlight in the vicinity of a right angle and increase the power generation amount.
  561. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) such as a solar bridge (2b) that is long with a joint (80A) + impact reduction means Accelerating output increasing sphere (2E) provided with (2G) + Accelerating gravity acceleration vertically downward + Increasing the width of long lens (2d) for tightening split fastener (80B) to increase power generation amount Various energy conservation cycle coalescing engines.
  562. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) such as a solar bridge (2b) that is long with a joint (80A) + impact reduction means Accelerate the output increasing sphere (2E) provided with (2G) + Accelerate gravity acceleration vertically downward + Divide and provide a set of multiple long lenses (2d) for fastening the fastener (80B) to generate power Various energy conservation cycle coalescing engine as an increase method.
  563. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) such as a solar bridge (2b) that is long with a joint (80A) + impact reduction means Accelerating the power increasing sphere (2E) provided with (2G) + Accelerating gravity acceleration vertically downward + Various energy conservation cycle coalescing engines using a method of increasing the power generation by making the long lens (2d) selected from existing materials long .
  564. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) such as a solar bridge (2b) that is long with a joint (80A) + impact reduction means Accelerate the output increasing sphere (2E) provided with (2G) + Accelerate gravity acceleration vertically downward + Concentrated power generation from sunlight to air tube air (28a) with a cross-section long lens (2d) from existing lens cross section Various energy conservation cycle coalescing engine as an increase method.
  565. 理論最良エンジン空気力太陽光重力加速度発電出力発生タービン翼を1/10前後にする設備方法+継手(80A)で長大とする太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical best engine aerodynamic solar gravitational acceleration power generation output equipment method to make turbine blades around 1/10 + solar heat increase suspension bridge (2b) such as a solar bridge (2b) that is long with a joint (80A) + impact reduction means Accelerate the output increasing sphere (2E) provided with (2G) + Accelerate gravitational acceleration vertically + Keep heat-insulated long lens (2d) and sunlight near right angle in the part close to vacuum Various energy conservation cycle coalescing engine as an increase method.
  566. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downwards) 2b) Solar power heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically + Length of split fastener (80B) tightening Various energy storage cycle coalescing engines with increased power generation by increasing the width of the lens (2d).
  567. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downwards) 2b) Solar power heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reduction means (2G) + Accelerating gravitational acceleration vertically downward + Dividing and tightening clamp (80B) Various energy storage cycle coalescing engines that use a plurality of long lenses (2d) as a set to increase power generation.
  568. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downwards) 2b) Solar heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravity acceleration vertically downward + Select manufacturing long lens (2d) from existing material Various energy storage cycle coalescing engine that is a long and large power generation method.
  569. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically downward + Select cross section long lens from existing lens cross section (2d) Various energy storage cycle coalescing engines that use sunlight as a method of increasing the amount of power generation in air tube air (28a).
  570. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて比重大物質を垂直下方に加速する構造や方法+締付具(80B)で真空可能にする長レンズ(2d)と太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine (2d) and a solar heat-enhanced suspension bridge (2d) and a solar heat-enhanced suspension bridge (multi-stage structure and method for accelerating specific critical substances vertically downward + vacuuming with fasteners (80B)) 2b) Solar power heater (2), etc. + Accelerating output increasing sphere (2E) provided with impact reducing means (2G) + Accelerating gravitational acceleration vertically + Long lens for heat insulation in the part close to vacuum ( 2d) and various energy conservation cycle coalescing engines that maintain sunlight in the vicinity of a right angle to increase power generation.
  571. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割締付具(80B)締付の長レンズ(2d)の幅を増大して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified housing primed + Solar heat increasing suspension bridge (2b) solar heater (2 ) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Add gravitational acceleration vertically downward + Increase the width of the long lens (2d) for fastening the split fastener (80B) Combined with various energy storage cycle engines that have increased power generation.
  572. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+分割して締付具(80B)締付の複数長レンズ(2d)をセットで設けて発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified housing primed + Solar heat increasing suspension bridge (2b) solar heater (2 ) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically and split and set multiple length lens (2d) tightened with clamp (80B) Various energy storage cycle coalescing engines that were installed in the plant and used as a method for increasing power generation.
  573. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存材料から選択製造長レンズ(2d)を長大として発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified housing primed + Solar heat increasing suspension bridge (2b) solar heater (2 ) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select from existing materials Various lengthening method of production length lens (2d) is used to increase power generation Energy conservation cycle coalescence engine.
  574. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+既存レンズ断面から選択断面長レンズ(2d)で太陽光を空気管空気(28a)に集中発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified housing primed + Solar heat increasing suspension bridge (2b) solar heater (2 ) + Accelerate the output increasing sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Select the long lens (2d) from the cross section of the existing lens to convert sunlight into air tube air (28a) ) Various energy storage cycle coalescing engines that use the method of increasing the amount of concentrated power generation.
  575. 理論最良エンジン空気力太陽光重力加速度発電タービンを多段に設けて被覆比重大物質を垂直下方に加速する構造や方法+全面電化住宅全盛にする+太陽熱増大吊橋(2b)等太陽光加熱器(2)+衝撃低減手段(2G)を設けた出力増大球(2E)を加速する+重力加速度を追加垂直下方に加速+真空に近付けた部分で断熱の長レンズ(2d)と太陽光を直角近傍で維持して発電量増大方法とした各種エネルギ保存サイクル合体機関。   Theoretical Best Engine Aerodynamic Solar Gravity Acceleration Turbine with multiple stages to accelerate the coverage ratio critical material vertically and vertically + Fully electrified housing primed + Solar heat increasing suspension bridge (2b) solar heater (2 ) + Accelerate output augmenting sphere (2E) provided with impact reduction means (2G) + Accelerate gravitational acceleration vertically downward + Insulate long lens (2d) and sunlight near right angle near vacuum Various energy storage cycle coalescing engines that maintain and increase power generation.