| 摘要 |
Method for increasing the gas dynamics and pollutant gas elimination by additive interactions on elemental particles and electric charges with optimisation of the reactive increase of molecular and atomic transition probability in engines having continuous internal combustion (ISOBARIC PROCESSES) and other combustion plants for the conversion of chemical energy of solid, liquid and gaseous substances. The microelectronically controlled additive reactor method proceeds either directly in burners which give off power in the form of shaft power or jet power or in secondarily coupled exhaust air reactors as a hybrid emission treatment method, in which case, for complete transformation of pollutant gas into substances identical with those in nature, the reduction of the multiplicity of unintegrated exhaust air treatment methods is to be made possible in connection with combustion plants and their differing efficiency. An additive hybrid apparatus principally comprises the multiple-stage reactor, designed for harmonic forces, ultrasonic excitation, electrodynamic, electromechanical and microelectronic components, the system parts of which each cause a defined synergistic increase of the gas dynamics and pollutant gas elimination action by energy bundling in the coupling of additive mechanical + electrical heat equivalence, with elimination of the chemical energy potential difference by positive entropy maximisation without ... Original abstract incomplete.
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