Inductive data transmission system for drill pipe

The invention claimed is: 1. An inductively coupled drill pipe, comprising: a drill pipe comprising a pin end comprising threads, a first annular loadable shoulder posterior and adjacent to the pin end threads circumscribing the pin end, the annular loadable shoulder comprising an annular hardened groove comprising side and bottom groove walls within the first annular loadable shoulder coaxial with the shoulder; the annular hardened groove walls having a hardness as measured on a Rockwell C scale between 0.05% and 5.0% greater than the annular loadable shoulder proximate the groove; a magnetically conductive electrically insulating (MCEI) U-shaped annular channel comprising a generally soft magnetic material sintered from a powder composition disposed within the walls of the hardened annular groove; an electrically conductive wire coil disposed within the U-shaped annular channel comprising a transmission end and a ground end; the powder composition comprising iron and manganese particles having an average particle diameter and average particle distribution within the powder that reduces signal attenuation to less than fifty percent of a transmitted signal across inductively coupled MCEI U-shaped annular channels, and the transmission end and the ground end of the wire coil pass through enclosed orifices within the bottom wall of the MCEI U-shaped annular channel, the ground end being attached to the bottom wall of the annular hardened groove, and the transmission end passing through an opening in the bottom wall of the annular hardened groove and the annular shoulder and is connected to a cable running the length of the drill pipe to a wire coil within a similarly configured U-shaped annular channel within a similarly hardened annular groove in a box end second annular loadable shoulder posterior and adjacent to box threads at the opposite end of the drill pipe. 2. The inductively coupled drill pipe of claim 1 , wherein the first and second annular loadable shoulders further comprise loadable annular adapters mounted on the drill pipe. 3. The inductively coupled drill pipe of claim 2 , wherein the loadable annular adapters mounted on the drill pipe each comprise a hardened annular groove comprising a wall surface Rockwell hardness greater than the Rockwell hardness of the annular adapter adjacent to the annular groove wall surface. 4. The inductively coupled drill pipe of claim 1 , wherein the U-shaped annular channel comprises a plurality of U-shaped channel segments. 5. The inductively coupled drill pipe of claim 4 , wherein at least one U-shaped channel segment comprises two or more enclosed orifices. 6. The inductively coupled drill pipe of claim 4 , wherein one end of the wire coil passes through the enclosed orifice of the U-shaped channel segment to ground while the other end passes through another enclosed orifice to the cable. 7. The inductively coupled drill pipe of claim 4 , wherein the U-shaped channel segments provide a gap free U-shaped annular channel. 8. The inductively coupled drill pipe of claim 1 , wherein the powder composition comprises one or more of oxygen and transition metals on the Periodic Table or a combination thereof. 9. The inductively coupled drill pipe of claim 1 , wherein the powder composition comprises one or more of magnesium, calcium, beryllium, or a combination thereof. 10. The inductively coupled drill pipe of claim 1 , wherein the powder composition comprising iron and manganese particles has an average particle diameter of between 350 μm and 1250 μm. 11. The inductively coupled drill pipe of claim 1 , wherein the powder composition comprising iron and manganese particles has an average particle diameter of between 600 nm and 900 nm. 12. The inductively coupled drill pipe of claim 1 , wherein the average iron and manganese particle distribution within the powder composition is about between 8:2 and 2:8, respectively. 13. The inductively coupled drill pipe of claim 1 , further comprising a wall region of the annular hardened groove comprises a Rockwell hardness greater than the Rockwell hardness of the annular loadable shoulder adjacent the wall region. 14. The inductively coupled drill pipe of claim 1 , wherein the annular hardened groove further comprises an annular insert mounted within the annular shoulder comprising a Rockwell hardness greater than the Rockwell hardness of the annular shoulder adjacent the insert. 15. The inductively coupled drill pipe of claim 1 , wherein the annular hardened groove comprises deformed wall surfaces. 16. The inductively coupled drill pipe of claim 15 , wherein the annular hardened groove comprises a hardened region extending from the deformed wall surfaces into the annular shoulder a distance of about between 0.001 mm to about 3 mm. 17. The inductively coupled drill pipe of claim 15 , wherein the deformed wall surfaces of the hardened annular groove comprise indentations. 18. The inductively coupled drill pipe of claim 15 , wherein the deformed wall surfaces of the hardened annular groove comprise indentations produced by means of peening, shot peening, hammer peening, laser peening, ultra-sonic peening, grit peening, glass peening, or a combination thereof. 19. The inductively coupled drill pipe of claim 1 , wherein at least one enclosed orifice provides a means for locating the U-shaped annular channel within the hardened groove. 20. The inductively coupled drill pipe of claim 1 , wherein at least one enclosed orifice provides a means for securing the U-shaped annular channel within the hardened groove.