RU2018139798A - HYDRAULIC STABILIZED FUEL, METHOD OF ITS PRODUCTION AND HEAT AND ENERGY EXCHANGE REACTOR - Google Patents

Claims (27)

1. Hydrostabilized fuel (hereinafter - GTS), consisting of: - fragments of high molecular weight hydrocarbon compounds, obtained by breaking intramolecular bonds of hydrocarbon fuel in the process of hydrodynamic cavitation and at least partially connected with the radicals H ⁺ and OH ^- water molecules, dissociated in the process of the mentioned hydrodynamic cavitation; - in this case, water molecules that are not dissociated during the mentioned hydrodynamic cavitation are homogenized in the form of water droplets around which solvation shells are formed from the above fragments of high molecular weight hydrocarbon compounds. 2. The GTS according to claim 1, wherein said water droplets have sizes in the range of 1-10 microns. 3. The GTS according to claim 2, wherein said water droplets have sizes in the range of 1-5 microns. 4. The method of obtaining the GTS according to claim 1, which consists in the fact that: - provide a mixture of hydrocarbon fuel and water in a predetermined proportion; - carry out hydrodynamic cavitation of the said mixture, during which: fragments of high molecular weight hydrocarbon compounds and radicals of both H ⁺ and OH ^- dissociated water molecules are simultaneously obtained; provide at least partial connection of the above fragments of high molecular weight hydrocarbon compounds and radicals H ⁺ and OH ^- ; provide homogenization of non-dissociated water molecules in the form of water droplets with the formation around them of solvation shells from the above fragments of high molecular weight hydrocarbon compounds. 5. The method according to p. 4, in which in said mixture said predetermined proportion of water with respect to hydrocarbon fuel is from 1 to 30%. 6. The method according to p. 4, in which the aforementioned hydrodynamic cavitation is carried out by: - feeding said mixture of hydrocarbon fuel with water into a heat and energy exchange reactor in the form of at least two spatially separated streams under atmospheric pressure; - swirls of all the mentioned flows in one direction; - collisions of all swirling flows into a common flow with its simultaneous rarefaction; - acceleration of the total flow to provide pressure below atmospheric. 7. The method according to p. 6, in which the pressure at said supply of the mixture is at least 3 times higher than the pressure in said accelerated vortex flow. 8. A heat and energy exchange reactor for implementing the method according to claim 4, comprising: - at least two vortex tubes with tangential inlets for supplying to each of them the said mixture of hydrocarbon fuel with water to form in each of these vortex tubes a separate swirl flow with a common swirl direction; - a common chamber formed on the final section of all of the mentioned vortex tubes due to their intersection along the generators and designed to ensure collision of the aforementioned individual vortex flows and rarefaction of the resulting total flow; - displacers, each of which is installed in the corresponding vortex tube and made so that the ratio of the cross-sectional area of the said vortex tube and the cross-sectional area of the said displacer is constantly decreasing as it moves in the direction of flow of the corresponding flow; - a confuser installed at the outlet of said common chamber. 9. The reactor according to claim 8, in which each said displacer is made with recesses extending in the longitudinal direction and designed to increase turbulence in the corresponding swirl flow. 10. The reactor according to claim 8, containing the five mentioned vortex tubes, four of which are made of the same diameter around the fifth vortex tube of larger diameter.