Galvanic anode and method of corrosion protection

The invention claimed is: 1. A galvanic anode comprising: an anode body comprising at least one helical coil comprising a sacrificial metal and a longitudinal axis; at least one elongated electrical conductor electrically connected to at least one said helical coil, wherein said at least one elongated electrical conductor is helically wound around at least a portion of said longitudinal axis of said at least one helical coil, wherein said at least one elongated electrical conductor provides multiple connection points to said anode body; and an encasement material surrounding at least a portion of said at least one helical coil and optionally a portion of said at least one elongated electrical conductor. 2. The galvanic anode of claim 1 , wherein said sacrificial metal is more electrochemically active than steel. 3. The galvanic anode of claim 2 , wherein said sacrificial metal comprises magnesium, zinc, aluminum, and/or alloys thereof. 4. The galvanic anode of claim 1 , wherein said sacrificial metal comprises an electromotive metal or metal alloy. 5. The galvanic anode of claim 1 , further comprising a shielding adjacent the outer surface of said at least one helical coil. 6. A galvanic anode comprising: an anode body comprising a helical coil comprising a first sacrificial metal and a longitudinal axis; a second sacrificial metal, said second sacrificial metal is less electrochemically active than said first sacrificial metal, wherein said first sacrificial metal and said second sacrificial metal are more electrochemically active than steel; at least one elongated electrical conductor electrically connected to at least one of said first and second sacrificial metals, wherein said at least one elongated electrical conductor is helically wound around at least a portion of said longitudinal axis of said helical coil, wherein said at least one elongated electrical conductor provides multiple connection points to said anode body; and an encasement material surrounding at least a portion of said first and second sacrificial metals. 7. The galvanic anode of claim 6 , wherein said second sacrificial metal comprises a second helical coil having a longitudinal axis. 8. The galvanic anode of claim 7 , wherein said helical coil is interleaved with said second helical coil. 9. The galvanic anode of claim 8 , wherein said at least one elongated electrical conductor is helically wound around at least a portion of said longitudinal axis of said second helical coil. 10. The galvanic anode of claim 8 , further comprising a shielding adjacent the outer surfaces of the interleaved helical coils. 11. The galvanic anode of claim 6 , wherein said second sacrificial metal comprises a solid mass having a longitudinal axis positioned in adjacent contact with the outer surface of said helical coil. 12. The galvanic anode of claim 11 , wherein said electrical connector is wound around at least a portion of the longitudinal axis of said helical coil and said solid mass to secure said solid mass to said helical coil. 13. The galvanic anode of claim 6 , wherein said first sacrificial metal comprises magnesium or a magnesium alloy. 14. The galvanic anode of claim 6 , wherein said second sacrificial metal comprises zinc or a zinc alloy. 15. The galvanic anode of claim 6 , wherein said first sacrificial metal comprises magnesium or a magnesium alloy and said second sacrificial metal comprises zinc or a zinc alloy. 16. The galvanic anode of claim 12 , wherein said first sacrificial metal is interleaved with said second sacrificial metal, further comprising a shielding adjacent the outer surfaces of the interleaved first sacrificial metal and second sacrificial metal. 17. A system for reducing the corrosion of steel reinforcement in a concrete structure comprising: an anode body comprising a first helical coil having a longitudinal axis, said helical coil comprising a sacrificial metal more electrochemically active than steel; at least one elongated electrical conductor electrically connecting said anode to a reinforcing steel element, wherein said at least one elongated electrical conductor provides multiple connection points to said anode body; an encasement material surrounding at least a portion of said sacrificial metal; and wherein said at least one elongated electrical conductor is helically wound around at least a portion of said first helical coil. 18. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 17 , wherein said first sacrificial metal comprises magnesium, zinc and/or alloys thereof. 19. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 17 , wherein said encasement material is a porous mortar. 20. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 17 , further comprising a second helical coil comprising a second sacrificial metal, said second sacrificial metal is less electrochemically active than said first sacrificial metal, wherein said second sacrificial metal is more electrochemically active than steel. 21. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 20 , wherein said first helical coil is interleaved with said second helical coil. 22. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 21 , wherein said at least one elongated electrical conductor is helically wound around at least a portion of said longitudinal axis of said first and second helical coils. 23. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 22 , further comprising an insulating spacer adjacent the outer surfaces of the interleaved helical coils. 24. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 17 , further comprising a solid mass of a second sacrificial metal, said second sacrificial metal is less electrochemically active than said first sacrificial metal, wherein said first sacrificial metal and said second sacrificial metal are more electrochemically active than steel. 25. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 24 , wherein said first sacrificial metal comprises magnesium or a magnesium alloy. 26. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 24 , wherein said second sacrificial metal comprises zinc or a zinc alloy. 27. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 24 , wherein said first sacrificial metal comprises magnesium or a magnesium alloy and said second sacrificial metal comprises zinc or a zinc alloy. 28. The system for reducing the corrosion of steel reinforcement in a concrete structure of claim 27 , further comprising an insulating spacer adjacent the outer surface of the solid mass of said second sacrificial metal. 29. A method for reducing the corrosion of steel reinforcement in a concrete structure comprising: electrically connecting the galvanic anode of claim 1 to the steel reinforcement in a steel reinforced concrete structure. 30. The method for reducing the corrosion of steel reinforcement in a concrete structure of claim 29 , further comprising: inserting said galvanic ano