Patent Number: 
Section: claims

1. A spherical fusion reactor, comprising:a spherical solid target formed of a material that is disposed to provide an impact surface for fusion reactions of ions impacting the outer surface of this target and,a spherical shell of insulating material enclosing a space coaxially centered upon the centrally located target electrode and,an electrically insulated stalk suspending said spherical target fixedly and concentrically within said spherical shell and,a rarefied fusion reactive gas contained within spherical shell and,an insulating and cooling medium within which the spherical shell is suspended and,a thermally and electrically insulated enclosure whose partial radius is concentrically centered on spherical target and spherical shell containing said insulating and cooling medium and,a radiation absorbing and cooling medium within which said thermally and electrically insulated enclosure is suspended and,a heat absorbent container for containing said radiation absorbing and cooling medium and;a high voltage, high frequency alternating current, AC, power supply and,electrical interconnections for connecting said high voltage, high frequency AC power supply between the spherical solid target and earth ground. 2. The spherical fusion reactor of claim 1 wherein the spherical solid target is a titanium sphere which provides an impact surface for fusion reactions. 3. The spherical fusion reactor of claim 1 wherein the spherical solid target is composed of a material capable of permitting and surviving nuclear reactions. 4. The spherical fusion reactor of claim 1 wherein the enclosed space is defined as a space between the central spherical target and the inner surface of the enclosing spherical electrically insulated envelope. 5. The spherical fusion reactor of claim 4 wherein the defined space provides a location for the generation of an alternating electric field. 6. The spherical fusion reactor of claim 5 wherein the alternating electric field provides for the ionization of gases contained therein. 7. The spherical fusion reactor of claim 5 wherein the alternating electric field provides for the alternately radial outward acceleration and the alternately radial inward acceleration of ionized gases contained therein. 8. The spherical fusion reactor of claim 7 wherein the radial inward acceleration of ionized gases provides for ions impacting the spherical target, for the impact of ions with one another, and for such impacts to occur at fusion reactive velocities. 9. The spherical fusion reactor of claim 7 wherein the radial outward acceleration of ionized gases provides for a period of time during operation in which gas distribution allows for gas exchange. 10. The spherical fusion reactor of claim 1 wherein the fusion reactive gas is composed of the following gases: fusion reactive isotopes of Hydrogen or Helium, singularly or combination. 11. The spherical fusion reactor of claim 1 wherein the spherical shell of insulating material provides for the following: a sealed space containing gas at a predetermined pressure, an insulating surface providing a location for the stopping of the outward movement of electrons, a location of a equipotential of electric charge accumulation, and the development of a spherically symmetrical electric field. 12. The spherical fusion reactor of claim 1 wherein the fusion reactive gas is at a predetermined pressure from about 0.0001 to about 0.1 Torr. 13. The spherical fusion reactor of claim 1 wherein the insulating and cooling medium separates and distances RF, radio frequency, ground potential from locations: within the reactor chamber, along the inner surface of the reactor chamber, along the outer surface of the reactor chamber, and to places external to the thermally and electrically insulated enclosure. 14. The spherical fusion reactor of claim 13 wherein the separation and distancing of RF ground potential provides for: a symmetrically developed field within the reactor, an electric field of evenly developed intensity radially outward from the target to the ground plane, the prevention of internal arcing, and the reduction of capacitive reactance loading of the power supply. 15. The spherical fusion reactor of claim 1 wherein the high voltage, high frequency AC potential provided by the power supply is at a predetermined voltage from 100,000 volts AC RMS, root mean square to 500,000 volts AC RMS. 16. The spherical fusion reactor of claim 1 wherein the high voltage, high frequency AC potential provided by the power supply is at a predetermined frequency from 20,000 Hertz to 100,000 Hertz. 17. The spherical fusion reactor of claim 1 wherein the thermally and electrically insulated enclosure provides for the electrical isolation of RF ground potential to a location external to the space enclosed by said thermally and electrically insulated enclosure. 18. The spherical fusion reactor of claim 1 wherein the thermally and electrically insulated enclosure provides for: the outward passage of particulate and waveform radiations, and the restriction of the inward passage of thermal energy from the surrounding radiation absorbing and cooling medium. 19. The spherical fusion reactor of claim 1 wherein the absorbing and cooling medium provides for the absorption of emitted radiations released by the fusion reactor. 20. The spherical fusion reactor of claim 19 wherein the absorption of emitted radiations released by the reactor provides for: the harnessing of said radiations to do work, the shielding of the external environment of the reactor from radiations, and the cooling of the contained reactor and it's associated internal components.