Abstract:
The invention relates to an electrolysis system. Said system can be utilized in a nuclear fusion process, on roof of a ferromagnetic aircraft in preferred embodiment. 
     Said electrolysis system will utilize electric energy produced by said aircraft at no cost. Said energy will be provided to an array of electrodes to electrolyze water or seawater to produce protons and electrons, and with B-11 isotope ions, vaporized out of source on board craft, a fusion spherical plasma can be produced on roof of said aircraft, for a nuclear fusion reaction. Stored energy produced by electrolysis system, can also be used for other purposes. 
     Said fusion spherical plasma is produced at essentially no cost, other than cost of electrolysis system and aircraft. 
     Three aircraft will be utilized in preferred embodiment, all three craft utilizing an electrolysis system, though only one craft, the ferromagnetic craft alone, producing the B-11 isotope ion.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is a division of application Ser. No. 11/728,080 filed Mar. 23, 2007, by present inventor, now abandoned, which was a continuation in part of Ser. No. 11/137,643, filed May 25, 2005 by present inventor, now abandoned, which was a continuation in part of Ser. No. 10/841,702, filed 2004, May 6, by present inventor, now abandoned, which claims the priority to provisional patent application with Ser. No. 60/468,598, filed 2003, May 6, by the present inventor. 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    Field of Invention—Electrolysis System 
         [0003]    This invention relates to an electrolysis system to produce B-11 isotope ions, and H-1 atoms for a nuclear fusion reaction process. 
       SUMMARY OF THE INVENTION 
       [0004]    In the present invention, an electrolysis system will produce the fuels required for a B-11 isotope ion nuclear fusion reaction. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0005]      FIG. 5  is a cross section side view showing an electrolysis system. 
           [0006]      FIG. 12D  is a top plan view of the array of containment barrels and electrodes for electrolysis, and also showing the inner wall and floor for the lower deck. 
           [0007]      FIG. 12E  is a perspective view from the side of a cutaway view of an array of containment barrels for electrolysis procedure by electrode, and an electrolysis system with an ion acceleration system for exiting particles for formation of fusion spherical plasma. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0008]    Also within electric system  20 , is electrolysis system and electrodes  188   a ,  188   b,    188   c,  and  188   d,    FIG. 12D . 
         [0009]    An array of ferromagnetic cores within electrolysis system will increase in magnetic intensity due to electrolysis electrodes producing orbiting electrons and particles. During a fusion process, the requirement for energized particles to be placed into mini-Larmor orbits around said ferromagnetic cores within the electrolysis system, will require, after initial formation of orbiting mini-Larmor particle fields, that the particles, primarily protons, electrons and B-11 isotope ions, have to be maintained in orbit around the ferromagnetic cores, increasing magnetic intensity of cores, and particles, as well. 
         [0010]    At the onset of the fusion process, the cores will have increased in magnetic intensity to permit formation of the mini-Larmor orbits that will persist after the charged particles exit from roof of aircraft. The orbiting particle miniature funnels, will decompose, and the spiraling, exiting particles will coalesce into a spherical plasma, on roof of the aircraft. 
         [0011]    Said electromagnetic systems will be accompanied by plasma systems operating concurrently, said plasma systems include: The plasma produced by internal electrolysis system  FIG. 12E  producing ions and also electrons. 
       END OF DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0012]    Beginning of the Operation of the Process Portion of the Patent The following is a description of the preferred embodiment for operation of process portion. 
         [0013]    A brine solution will be used in vaporization process involving seawater. A boric acid solution will be used in vaporization process using borax to obtain the B-11 isotope ion for said nuclear fusion reaction. 
         [0014]    By means of an on-board electrolysis system  FIGS. 12D and 12E , a boron B-11 isotope fusion spherical plasma can be formed on roof of the smaller ferromagnetic aircraft. 
         [0015]    Referring to  FIGS. 12D and 12E , depicted are elements of the fusion process utilizing apparatus for an electrolysis system. Said apparatus includes barrel shaped containers for boron B-11 isotope ions  144 ,  FIG. 12D . Said barrel  144  of B-11 isotope ions is connected to tubular column  111   g.    
         [0016]    Laminated glass is preferred embodiment for tubular columns. The B-11 isotope ion tubular column  111   g,    FIG. 12E , is connected at one end to ferromagnetic cored column within a larger B-11 ion tubular column  112   g,    FIG. 12E . Said ferromagnetic column is connected at the other end to exit electrode  158 ,  FIG. 12E . Said electrode also called roof electrode. 
         [0017]    Said B-11 isotope ion will exit roof electrode  158 ,  FIG. 12E , at insulated electrode  158 , having been placed into mini-Larmor gyro orbits around said ferromagnetic cored column prior to exiting electrode. 
         [0018]    Said particle has been energized while rotating around said ferromagnetic column, and this has not diminished the magnetism of said ferromagnetic column, it has increased the magnetism of the cored column, as well. 
         [0019]    Barrel  144 ,  FIGS. 12D and 12E , alone contains the fusion fuel boron B-11 isotope ion. Said isotope ion can be vaporized out of source prior to electrolysis procedure, or the B-11 isotope ion can be vaporized out of source on board said aircraft. The source being a brine solution from seawater, containing boron in the seawater or boric acid solution from borax from tincal from deposits in California or other parts of the world. 
         [0020]    The remaining fuel source for the fusion reaction will be electrolyzed out of water or seawater, most likely on board said aircraft. The remaining fuel source will be for the H-1 atom; protons and electrons, and with the B-11 isotope ion, forming the fuel elements for the fusion process. 
         [0021]    Said electrolysis system is best seen in  FIG. 12E . The referenced containment barrels for B-11 fuels for the fusion process, are best seen in  FIG. 12D , barrel  142   a,    142   b,    142   c  and  144 . Though, said barrels are also shown in  FIG. 12E . 
         [0022]    The maximum current to decompose said fuel solutions completely, to resulting particles desired, being protons, electrons, and the B-11 isotope ion, will be accomplished by two separate procedures, vaporization and electrolysis, can be accomplished on board the aircraft. Water for electrolysis is stored in barrel shaped containers. Platinum electrode is preferred material for electrolysis. Said electrolysis apparatus has what appears to be two arms, columns, on each side of individual barrels, except for said B-11 isotope ion column, which has an individual arm, column, projecting straight upward. The three barrels  142   a,    142   b  and  142   c,    FIG. 12D , contain water, H2O. Said barrels of water will be electrolyzed by electrodes in  FIG. 12D . The B-11 isotope ion will be vaporized out of source, a boron source. Either boric acid from borax from tincal, or boron from a seawater source, a brine from seawater. Oppositely charged particles will exit each barrel, positive on one side, negative on opposite side. Though not the same side on all barrels. The B-11 isotope ion column will extend straight upward. 
         [0023]    Sources for boron B-11 isotope ion includes seawater or borax. Borax is a compound found in nature as tincal. Tincal is available in millions of tons, over 200 million in California, a half billion in Turkey. It is also found in Tibet and many other countries of the world to include Russia. For the radiation free and direct conversion to electricity fusion reaction, boron B-11 isotope ion is required, uniquely. The hydrogen atom, H-1, is also required (H+plus e−). The H-1 atom can be obtained from the electrolysis of water. Said tubular columns are also called tubes. 
         [0024]    No fusion reaction is radiation free, the B-11 fusion reaction is conventionally referred to as a radiation free reaction. There is no significant radiation produced, or coaling required, using the fuels boron B-11 isotope and regular hydrogen. Energetic charged particles will be produced and stored within vortices. 
         [0025]    Barrel  142   a,    FIG. 12D and 12E , contains a solution of H2O, water, for electrolysis by electrode. Said barrel is connected on one side to tubular column  111   a.  Said column is connected at the other end to ferromagnetic cored column within a column  112   a.  Said ferromagnetic column  112   a  is connected at the other end to exit electrode  154 ,  FIG. 12E . On the other side of said barrel  142   a,  said barrel is connected to tubular column  111   b.  Said column  111   b  is connected at the other end to ferromagnetic cored column within column  112   b.  Said ferromagnetic column is connected at the other end to exit electrode  160 ,  FIG. 12E . 
         [0026]    Barrel  142   b  containing water for electrolysis by electrode  188 ,  FIG. 12D , is best seen in  FIGS. 12D and 12E . In  FIG. 12E , on one side of barrel  142   b,  said barrel is connected to tubular column  111   c.  Said column is connected at the other end to ferromagnetic cored column  112   c.  Said ferromagnetic column is connected at the other end to exit electrode  152 ,  FIG. 12E . Barrel  142   b , containing water, is shown in  FIGS. 12D and 12E , on the other side of barrel  142   b,  said barrel is connected to tubular column  111   d . Said column is connected at the other end of column  111   d  to ferromagnetic cored column within a larger column  112   d.  Said ferromagnetic cored column is connected at the other end to exit electrode  164 ,  FIG. 12E . 
         [0027]    Barrel  142   c,  containing water for electrolysis by electrode  188 , is shown in  FIGS. 12D , and  12 E. On one side of barrel  142   c,  said barrel is connected to tubular column  111   e.  Said column  111   e,  is connected at the other end to ferromagnetic cored column within a larger column  112   e.  Said ferromagnetic cored column is connected at the other end to exit electrode  156 ,  FIG. 12E . Said barrel  142   c  containing water, is shown in  FIGS. 12D and 12E . Oh the the other side of barrel  142   c,  said barrel is connected to tubular column  111   f.  Said column  111   f  is connected at the other end to ferromagnetic cored column  112   f.  Said ferromagnetic column is connected at the other end to exit electrode  162 ,  FIG. 12E . 
         [0028]    The 11 in B-11 isotope ion is the neutrons, and, five protons, the correct designation for this isotope would be  11 boron. Conventionally, it is called B-11 isotope, or B-11. The hydrogen atom is one proton and one electron. It is referred to as H or H−1. The ion H+, a proton, is also the hydrogen atom, H−1, without an electron. The terms B-11, H−1, and H+ will be utilized. 
         [0029]    Referring to  FIG. 5 , a cross section side view is shown. A barrel shaped container of prepared B-11 isotope ion  144  is depicted in  FIG. 5 . Said barrel shaped container is attached at one end to B-11 isotope ion tubular column  11   g , and at the other end of column  111   g,  said column is attached to a ferromagnetic cored column within a larger tubular column  112   g.  Preferred embodiment for the bottom tubular column  111   g , is laminated, translucent shock and fracture resistant glass. For upper ferromagnetic column  112   g,  preferred embodiment for glass, is the same fracture and shock resistant, translucent laminated glass. Said column  112   g , is connected at the higher end to exit electrode  158 . The barrel  144 , contains isotope ion solution, said solution is a seawater brine, or boric acid, or other B-11 isotope containing solution. Said electrolysis system is best seen in  FIGS. 12D and 12E . 
         [0030]    Referring to  FIG. 12D , shown is a top view of barrels of water  142   a,    142   b,  and  142   c,  also shown is a barrel shaped container of solution for B-11 isotope ion evaporation process in barrel  144 ,  FIG. 12D . Shown within containers for electrolysis and vaporization process, are electrodes  188   a,    188   b,    188   c,  and  188   d,    FIG. 12D . Shown in the middle of said array of barrel shaped containers, is central shaft  41 ′,  FIG. 12D  and  FIG. 5 . The bottom deck, octogonal shaped interior wall structure  8 ′,  FIG. 12D , is best seen in  FIG. 5 . The shape is octogonal pieces in a general beehive configuration, the bottom half of a beehive. The top half of said beehive configured interior, would be the upper one half of aircraft, the upper half of a beehive. 
         [0031]    Said shape formed from octogonal pieces, was found by Buckminster Fuller from patterns found in nature, specifically, a beehive, and is the strongest structural frame shape known. 
         [0032]    Referring to  FIG. 12E , said electrolysis system,  FIGS. 12D and 12E , is shown. Depicted in  FIG. 12E , is a view of said containers  142   a,    142   b,    142   c,  and  144 . Said containers attached to indicated columns in  FIG. 12E , provides a complete view of said electrolysis system for said large and small aircraft. Said electrolysis system includes electrode system  FIG. 12E , ferromagnetic cored columns within larger tubular columns, small columns, and electrode apertures  152 ,  154 ,  156 ,  158 ,  160 ,  162 , and  164 . Vaporization nozzles  940 ,  941 , and  942 , are depicted below barrel  144 ,  FIG. 12E , for exhaust gases from vaporization process. 
         [0033]    Said column  111   g  is attached at the other end to a ferromagnetic cored column within a larger tubular column  112   g.  Preferred embodiment for said column is translucent laminated glass. Said glass is fracture and shock resistant, in preferred embodiment. Said column  112   g  is connected at the higher end to exit electrode  158 ,  FIG. 12E . The remaining barrels depicted in  FIG. 12E  utilize water, H2O, as fuel far electrolysis. Barrel  144 , alone, utilizes boron B-11 isotope ion, previously vaporized out of source, the preferred embodiment. Said source being seawater or borax from tincal. Other sources are available as well. Barrel shaped container is preferred embodiment for barrels. Electrode  188   d  is used with barrel  144 ,  FIG. 12E . 
         [0034]    The bottom of column  111   a ,  FIG. 12E , is connected to barrel  142  for electrolysis by electrode  188   a,    FIG. 12D . The other end of column  111   a , is connected to ferromagnetic cored column within a larger tubular column  112   a.  Said column  112   a  is connected at the other end to exit electrode  154 . Tubular column  111   b  is connected to said barrel  142   a,    FIG. 12E , on the other side of said barrel. Tubular column  111   b  is connected at the other end to ferromagnetic cored column, within a larger tubular column  112   b . Said ferromagnetic cored column  112   b,  is connected at the other end to exit electrode  160 ,  FIG. 12E . The particle emanating from electrode aperture  160  is a negative particle, an electron. Said column utilizes electrolysis electrode  188   a,    FIG. 12E . 
         [0035]    The bottom of tubular column  111   c ,  FIG. 12E , is connected to barrel  142   b  for electrolysis by electrode  188   b,    FIG. 12E . The other end of said column  111   c  is connected to ferromagnetic cored column, within a larger tubular column  112   c.  Said ferromagnetic cored column  112   c  is connected at a higher end to exit electrode  152 ,  FIG. 12E . The particle emanating from said electrode opening, is a negative particle, an electron. On the other side of said barrel  142   b,  column  111   d  is connected to said barrel. The other end of said column  111   d  is connected to ferromagnetic cored column, within a larger tubular column  112   d.  Said ferromagnetic column is connected at a higher end to exit electrode  164 ,  FIG. 12E . The particle emanating from said electrode is a positive particle, a positive proton, column  111   d  is connected to barrel  142   b  for electrolysis by electrode  188   b,    FIG. 12D . 
         [0036]    The bottom of column  111   e  is connected to barrel  142   c,    FIG. 12E , for electrolysis by electrode  188   c,    FIG. 12D . The other end of said column is connected to ferromagnetic cored column, within a larger tubular column  112   e.  Said ferromagnetic column  112   e,  is connected at a higher end to exit electrode  156 ,  FIG. 12E . The particle emanating from electrode  156  is a positive particle, a positive proton. On the other side of said barrel  142   c,    FIG. 12E , tubular column  111   f  is connected to said barrel  142   c.  The other end of said column  111   f  is connected to ferromagnetic cored column within a larger tubular column  112   f.  Said ferromagnetic cored column, within a larger tubular column  112   f.  Said ferromagnetic cored column  112   f,  is connected at the other end to exit electrode  162 ,  FIG. 12E . The particle emanating from said electrode  162  is a negative particle, an electron.