Plasma power generation for hydrogen production

In the art investigation materials of charged particles and electromagnetic waves interactions in plasma setup Magnetic V dipole developing by authors are presented. It was experimentally distinguished that current increasing in specially formed electromagnetic resulting field arises as result of parametric resonance and phase transformations electric energy, kinetic energy of charged particles and magnetic energy. Current loop is formed, where start bifilar current of heteropolar charged particles. It leads also to current increasing with each plasmoid rotation cycle around system center of mass. Process is stabled in phase of electromagnetic energy irradiation. The energy can be used on load like electricity. In experimental setup launches was obtained power increase on 42% from power supply by non-resonant mode and on 142% by resonance mode.

Method and the setup were successfully applied for destruction of crystal lattice of minerals, industrial wastes with separation of useful components and metal extraction. Method of plasma resonant electrolysis was developed, and experiments for sedimentation of gold containing pulp carried out. Possibility of gaseous hydrogen producing with application of high frequency plasma resonant electrolysis was experimentally indicated. The process can be built in the MVD setup.

1. Kolesnik V. G., Urusova E. V., Basova E. S. Current Amplification in Plasma under Resonant Interaction of Electromagnetic Waves and Charged Particles / Collection of Proceedings of the International Conference «Fundamental and Applied Problems of Physics». – Tashkent, October 21-22, 2013. – Pр. 12-14.

2. Kolesnik V. G., Urusova E. V., Basova E. S., Kim Yu. S., Urusov M. V., Sim S. V., Urusov E. V., Kim D. B. Method for Generating Compensated Charge Energy. Patent of the Republic of Uzbekistan № IAP 06510 dated 05.20.2021, priority dated 11.02.2017.

3. Charles Slickter. Fundamentals of Magnetic Resonance Theory / Translation, second edition, ed. G. V. Skrotsky // M.: Mir Publishing House. – 1981. – P. 447.

4. Gilbert T. L. A phenomenological theory of damping in ferromagnetic materials // IEEE Trans. on Magn. – 2004. – V. 40, No. 6. – Р. 3443.

5. Kolesnik V. G., Urusova E. V. et al. Obtaining ultrafine SiO2 powder // Advanced Materials. – Moscow, Russia. – 2011. – No. 12. – Pр. 504-509.

6. Kolesnik V. G., Urusova E. V. Device for complex opening and modification of the structure of raw materials with metal elements. Patent of the Republic of Uzbekistan № IAP 02287 from 24.01.2003

7. Kolesnik V. G., Urusova E. V., Basova E. S., Kim Y. S., Abu Shakra M. B. Sim S. V., Kim D. B. Method for obtaining silicon and titanium by generating electromagnetic interactions between SiO2 and FeTiO3 particles and magnetic waves. European Patent № 2698196 from 20.11.2014, in 10 countries: Germany, GB, Belgium, Switzerland, Liechtenstein, France, Italy, Netherlands, Sweden, Turkey; Patent of the Russian Federation № 2561081 from 28.07.2015; Patent of Ukraine № 107875 from 25.02.2015; Patent of South Korea № 10-1622750 from 13.05.2016; Patent of China № 1934636 from 27.01.2016; Patent of the Republic of Uzbekistan № IAP 05421 from 06.06.2017.

8. Kolesnik V. G., Urusova E. V. Method for extracting zinc, gold and platinum from steelmaking sludge. Patent of the Republic of Uzbekistan № IDP 05384 from 31.10.2002.

9. Kravchenko A. V., Kublanovsky V. S., Pivovarov A. A., Pustovoytenko V. P. Low-temperature plasma electrolysis. Theory and practice / Monograph. 229 p. // Dnepropetrovsk: OOO «Accent PP». – 2012. – Pр. 11-17.