rexresearch.comGyorgy
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Nano-Carbon Plasma Power Generator
Nano-Carbon Plasma Power Generator
US20140126679
Renewable Energy Production Process with a Device Featuring Resonant Nano-Dust Plasma, a Cavity Resonator and an Acoustic Resonator
[ PDF ]
Abstract
Renewable Energy Production Process with a Device Featuring Resonant Nano-Dust Plasma, a Cavity Resonator and an Acoustic Resonator
[ PDF ]
Abstract
The invention is a renewable energy production
process with resonant nano-dust plasma, with the application
of a cavity resonator and an acoustic resonator. During the
process the acoustic resonator is placed inside the cavity
resonator, and create a series of acoustic resonances with a
complex plasma made of sub-micron sized carbon dust, hydrogen
isotopes and other gases between 10 Pa and 500 kPa at about
2.000° C., thus creating oscillations and thus plasmon
polaritons on the surface of carbon dust particles oscillating
between 10 kHz-5 GHz and in the terahertz range, which in turn
produces heat or electric energy, or creates a series of
nuclear transmutations. The invention is an embodiment
producing renewable heat, formed by a cavity resonator (30)
excited by electromagnetic fields, and an acoustic resonator
(10). In the acoustic resonator (10) operated with a number of
acoustic resonances, there are nano-sized dust particles (1).
The electromagnetic cavity resonator (30) is cylindrical,
spherical or rectangular with mirror-like internal walls (31),
inside of which the cylindrical or spherical acoustic
resonator (10) suitably made of heat resistant and
electrically insulating material is mounted.
Abstract
The subject of the invention is a process for heat production with nuclear interactions. During the process the gas is pumped through a stack of nanoparticles in a device featuring an internal and an external chamber via an inlet and an outlet opening, and the process is initiated by heating the device. Further, the subject of the invention is a device accomplishing said process. The device has an interconnected internal chamber, and surrounding said chamber there is an external chamber having at least one inlet and one exit opening. There are nanoparticles in the internal chamber. There is an impermeable wall between the two said chambers. The internal chamber is separated from the exit opening by a heat resistant, porous ceramic wall. There is a heating element on the internal side wall.