Patent Number: 060375175
Section: claims

1. An apparatus for treating waste materials, the apparatus comprising: (a) a molten metal reactor including a reaction chamber charged with a reactant metal, and further including a heating arrangement for placing the reactant metal in a molten state;  (b) a waste material input structure through which waste material may be introduced into the reaction chamber to contact the molten reactant metal;  (c) field generating means for generating a unidirectional electromagnetic field through the molten reactant metal and through a first target area, the electromagnetic field directing beta particles toward the first target area; and  (d) a first radiation absorbing module positioned in the first target area, the first radiation absorbing module including a radiation absorbing material.  (a) a field generating coil; and  (b) a voltage supply for directing a field generating electrical current through the field generating coil.  (a) cooling means for cooling the field generating coil; and  (b) a protective material encasing the field generating coil and protecting the coil from the reactant metal.  (a) the field generating coil is made from a tubular conductor; and  (b) the cooling means comprises a cooling fluid supply and a pump for directing cooling fluid from the cooling fluid supply through the tubular conductor.  (a) a waste material submerging arrangement for submerging the waste material in the molten reactant metal.  (a) a plurality of layers of tungsten, each layer of tungsten being separated from each adjacent layer of tungsten by a layer of lead;  (b) a spacing arrangement for maintaining the spacing between the layers of tungsten; and  (c) a protective material encasing the tungsten and lead layers to protect the tungsten and lead from the reactant metal.  (a) a positioning structure for positioning the first radiation absorbing module in the reaction chamber and for selectively withdrawing the first radiation absorbing module from the reaction chamber.  (a) a second radiation absorbing module positioned in the electromagnetic field at an end of the electromagnetic field opposite to an end in which the first radiation absorbing module is positioned.  (a) a plurality of layers of tungsten, each layer of tungsten being separated from each adjacent layer of tungsten by a layer of lead;  (b) a spacing arrangement for maintaining the spacing between the layers of tungsten; and  (c) a protective material encasing the tungsten and lead layers to protect the tungsten and lead from the reactant metal.  (a) placing a reactant metal in a molten state and substantially isolating the molten reactant metal from oxygen;  (b) producing a unidirectional electromagnetic field through the molten reactant metal and through a first target area, the electromagnetic field directing beta particles toward the first target area;  (c) introducing the waste material into the molten reactant metal;  (d) circulating the molten reactant metal to direct constituents of the waste material into the area of the molten reactant metal traversed by the electromagnetic field; and  (e) intercepting the electromagnetic field in the first target area with a radiation absorbing material.  (a) directing a field generating current through an electrically conductive coil made from a tubular material and positioned in the molten reactant metal, the coil being encased in a protective coating material which protects the coil from the molten reactant metal;  (b) cooling the coil by directing a coolant fluid through the tubular coil material.  (a) intercepting the electromagnetic field with a plurality of layers of tungsten and lead, each layer of tungsten being separated from each adjacent layer of tungsten by a layer of lead.  (a) intercepting the electromagnetic field with a radiation absorbing material in a second target area traversed by the electromagnetic field. 2. The apparatus of claim 1 wherein the field generating means comprises: 3. The apparatus of claim 2 wherein the field generating current comprises a pulsed current. 4. The apparatus of claim 2 wherein the field generating coil is adapted to be positioned within the molten reactant metal and further comprising: 5. The apparatus of claim 4 wherein: 6. The apparatus of claim 1 wherein the reactant metal comprises an alloy including aluminum and further including at least one additional metal chosen from a group consisting of cadmium, palladium, tungsten, lead, dysprosium, and europium. 7. The apparatus of claim 1 further comprising: 8. The apparatus of claim 1 wherein the first target area comprises an area in which the electromagnetic field strength is substantially greatest. 9. The apparatus of claim 1 wherein the first radiation absorbing module comprises: 10. The apparatus of claim 1 further comprising: 11. The apparatus of claim 1 further comprising: 12. The apparatus of claim 11 wherein the second radiation absorbing module comprises: 13. A method for treating waste materials, the method comprising the steps of: 14. The method of claim 13 wherein the step of producing the unidirectional electromagnetic field includes: 15. The method of claim 13 wherein the step of intercepting the electromagnetic field with a radiation absorbing material includes: 16. The method of claim 13 wherein the first target area is located within the reactant metal bath and further comprising the step of protecting the radiation absorbing material from the reactant metal with a protective coating material. 17. The method of claim 13 further comprising the step of: