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An air, fuel, and inert fluid or liquid water mixture is injected into a resonance chamber forming micro-packets. The air and fuel mixture in the micro-packets form micro-explosions in a combustion chamber where acoustic and electromagnetic energy are absorbed by the inert fluid instead of thermal e

An air, fuel, and inert fluid or liquid water mixture is injected into a resonance chamber forming micro-packets. The air and fuel mixture in the micro-packets form micro-explosions in a combustion chamber where acoustic and electromagnetic energy are absorbed by the inert fluid instead of thermal energy. A standing wave is created in the central resonance chamber by the micro-explosions. Interfering waves are in phase increasing energy in the air, fuel and water mixture. Acoustic energy is transferred from the hot combustion gases to the colder inert fluid or water. A thermal equilibrium is reached without substantial energy transfer from the hot body to the cold body. Efficient combustion is achieved with reduced carbon emissions. The heat generated from the combustion may be used to produce work by any conventional device, such as a steam engine or turbine or generate heat for a building.

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1. A thermo-acoustic reactor comprising: a micro-packet and stationary wave generator coupled having an input nozzle providing air, fuel, and an inert fluid and a resonance chamber;a passage formed in said micro-packet and stationary wave generator between the input nozzle and the resonance chamber;

1. A thermo-acoustic reactor comprising: a micro-packet and stationary wave generator coupled having an input nozzle providing air, fuel, and an inert fluid and a resonance chamber;a passage formed in said micro-packet and stationary wave generator between the input nozzle and the resonance chamber;a spark plug adjacent said passage;a combustion chamber adjacent said spark plug;an adjustable combustion nozzle placed adjacent said combustion chamber, said adjustable combustion nozzle having a convergent portion and a straight portion; anda central resonance chamber placed adjacent said adjustable combustion nozzle within said combustion chamber having a bottom,whereby the input nozzle introduces the air, fuel and inert fluid into said micro-packet and stationary wave generator forming micro-packets and micro-explosions in the combustion chamber forming pressure and acoustic waves transferred to the inert fluid. 2. A thermo-acoustic reactor as in claim 1 further comprising: a piston placed within the resonance chamber of said micro-packet and stationary wave generator. 3. A thermo-acoustic reactor as in claim 1 further comprising: an acoustic damper chamber coupled to said micro-packet and stationary wave generator. 4. A thermo-acoustic reactor as in claim 1 wherein: the inert fluid is water. 5. A thermo-acoustic reactor comprising: a convergent to straight nozzle providing air-fuel and water;a micro-packet and stationary wave generator coupled to said convergent to straight nozzle;wherein said micro-packet and stationary wave generator generates an air-fuel and water micro-packet;wherein said micro-packet and stationary wave generator comprises a housing receiving acoustic waves from micro-explosions;wherein said micro-packet and stationary wave generator comprises a resonance chamber generating stationary waves;wherein said micro-packet and stationary wave generator and the resonance chamber are heated by heat transfer from the micro-explosions of the micro-packet of air-fuel-water mixture;a combustion chamber having a bottom;an adjustable combustion chamber convergent to straight nozzle placed in said combustion chamber opposing the bottom;a spark plug coupled to said combustion chamber;wherein the air-fuel in the micro-packet is ignited by said sparkplug causing the micro-explosion and generating acoustic waves in the combustion chamber;a central resonance chamber placed in said combustion chamber forming a nodal point at a bottom of said central resonance chamber;wherein said central resonance chamber generates stationary waves and water molecules and combustion molecules are resonated;wherein said central resonance chamber has a gradient temperature and thermal oscillations are generated;a smaller diameter extension attached to one end of said central resonance chamber to balance the resonance chamber and to exhaust waves filtered by said central resonance chamber;an infrared jacket wrapped around said combustion chamber, whereby infrared radiation is blocked;a vacuum chamber placed around the thermo-acoustic reactor, whereby the transfer of acoustic and thermal energy is blocked; andan exhaust port placed at a distance from the bottom of said combustion chamber. 6. A method of generating thermo-acoustic energy comprising the steps of: injecting an air, fuel, and liquid water mixture into a resonance chamber;expelling micro-packets of the air, fuel, and liquid water mixture from the resonance chamber;exploding the micro-packets of air, fuel, and liquid water mixture in an adjustable volume portion of a combustion chamber generating heat and acoustic energy; andreceiving the heat and acoustic energy in a central resonance chamber wherein standing waves are formed,whereby acoustic and electromagnetic energy is transferred to the water increasing its temperature. 7. A method of generating acoustic and electromagnetic energy from an exothermic reaction comprising the steps of: injecting an air, fuel, and inert fluid mixture into a resonance chamber;generating cavitation bubbles in the inert fluid in the resonance chamber,forming micro-packets of the air, fuel, and inert fluid mixture forming a cold body;igniting the air and fuel in the micro-packets generating combustion gases and thermal and acoustic energy, whereby a hot body is formed by the combustion gases;compressing and relaxing the inert fluid;expelling the combustion gases through a nozzle to a central resonance chamber; andgenerating a standing wave and thermal oscillation within the central resonance chamber,whereby atoms and molecules of the combustion gases and inert fluid are exposed to compression and relaxation and acoustic energy rather than thermal energy is transferred from the hot body to the cold body increasing the temperature of the cold body and thermal equilibrium of the hot and cold body is reached by conversion of acoustic energy to thermal energy without a substantial drop in temperature of the hot body. 8. A method of generating acoustic and electromagnetic energy from an exothermic reaction as in claim 7 wherein: the inert fluid is liquid water. 9. A method of generating acoustic and electromagnetic energy from an exothermic reaction as in claim 7 wherein the step of generating cavitation bubbles comprises the steps of: compressing and relaxing the air, fuel, and liquid water mixture with micro-explosions. 10. A method of generating acoustic and electromagnetic energy from an exothermic reaction as in claim 7 wherein the step of forming micro-packets comprises the steps of: increasing pressure in the resonance chamber by acoustic and thermal energy transfer;overflowing a volume of air, fuel, and liquid water mixture form the resonance chamber expelling the micro-packet; andrefilling the resonance chamber with the air, fuel, and liquid water mixture,whereby micro-packets are formed.