Climate responsive transmission lines

The invention claimed is: 1. An electrical power transmission line conductor comprising: at least one electrical conductor configured for transmission of high voltage alternating current electrical power; at least one strengthening structure bundled with the electrical conductor to provide physical support to the electrical conductor; and at least one magnetocaloric structure comprising magnetocaloric material, the at least one magnetocaloric structure being included in a bundle with the electrical conductor and strengthening structure, the magnetocaloric structure being arranged within the bundle to be located within a changing magnetic field generated by transmission of high voltage alternating current electrical power via the at least one conductor to thereby cause the magnetocaloric material composition to exhibit a magnetocaloric effect to regulate the operating temperature of the electrical power transmission line conductor. 2. An electrical power transmission line conductor as claimed in claim 1 wherein the magnetocaloric effect operates to regulate the operating temperature of the electrical power transmission line conductor to maintain operating temperature above a range where icing occurs. 3. An electrical power transmission line conductor as claimed in claim 2 wherein one or more magnetocaloric structures include magnetocaloric material configured to exhibit magnetocaloric effects to cause warming of the electrical power transmission line conductor at temperatures below an icing threshold temperature. 4. An electrical power transmission line conductor as claimed in claim 3 wherein the magnetocaloric material has a material composition including any one or more of: La 0.7 (Ca 1-x Ag x ) 0.3 MnO 3 , La 0.7 Ca 0.3 MnO 3 , LaMnO 3 , MnCoGe, MnAs, Mn 1-x Fe x As MnCoGe, LaFe 11.6 Si 1.4 , La(FeSi) 13 , La 0.8 Nd 0.2 Fe 11.5 Si 1.5 , Ni 43 Mn 46 Sn 11 , (Mn 1-x Ni x ) 3 Sn 2 , and RMnO 3 . 5. An electrical power transmission line conductor as claimed in claim 4 wherein the magnetocaloric material composition is tuned to exhibit the magnetocaloric effect below the icing threshold temperature by doping using any one or more of Ag, Co, Cu, B, H or Gd. 6. An electrical power transmission line conductor as claimed in claim 3 wherein the icing threshold temperature is a temperature selected from a range of 5° C. to 0° C. 7. An electrical power transmission line conductor as claimed in claim 3 wherein the magnetocaloric material configured to exhibit magnetocaloric effects to cause warming of the electrical power transmission line conductor to regulate the operating temperature to within a range of 5° C. to 0° C. in ambient temperatures in the range of 5° C. to −50° C. 8. An electrical power transmission line conductor as claimed in claim 1 wherein the magnetocaloric effect operates to regulate the operating temperature of the electrical power transmission line conductor to maintain operating temperature below a high temperature threshold. 9. An electrical power transmission line conductor as claimed in claim 8 wherein one or more magnetocaloric structures include magnetocaloric material configured to exhibit magnetocaloric effects to cause cooling of the electrical power transmission line conductor at temperatures above an high-heat threshold temperature. 10. An electrical power transmission line conductor as claimed in claim 9 wherein the magnetocaloric material comprises any one or more of: Zn doped Fe 3 O 4 ; Ni 0.50 Mn 0.50-x Sn x. Ni 0.50 Mn 0.50-x In x and Ni 0.50 Mn 0.50-x Sb x alloys; and LaCrO 3 . 11. An electrical power transmission line conductor as claimed in claim 9 wherein the magnetocaloric material composition is tuned to exhibit the magnetocaloric effect above the high-heat threshold temperature by doping using any one or more of gold (Ag), cobalt (Co), copper (Cu), boron (B), hydrogen (H) or gadolinium (Gd). 12. An electrical power transmission line conductor as claimed in claim 9 wherein the high-heat threshold temperature is a temperature selected from within the range of 40° C. to 100° C. 13. An electrical power transmission line conductor as claimed in claim 9 wherein the magnetocaloric material configured to exhibit magnetocaloric effects to cause cooling of the electrical power transmission line conductor to regulate the operating temperature to within a range of 40° C. to 100° C. in ambient temperatures in the range of 30° C. to 60° C. 14. An electrical power transmission line conductor as claimed in claim 1 wherein the magnetocaloric effect operates to regulate the operating temperature of the electrical power transmission line conductor to maintain operating temperature within a target operating range. 15. An electrical power transmission line conductor as claimed in claim 14 wherein one or more magnetocaloric structures include magnetocaloric material configured to exhibit magnetocaloric effects to cause warming of the electrical power transmission line conductor at temperatures below an icing threshold temperature. 16. An electrical power transmission line conductor as claimed in claim 1 wherein the magnetocaloric material composition for each magnetocaloric structure is tuned to exhibit the magnetocaloric effect within a target temperature range. 17. An electrical power transmission line conductor as claimed in claim 1 wherein each magnetocaloric structure is configured as an elongate wire comprising the magnetocaloric material, the wire being incorporated into the bundle with the electrical conductor and strengthening structure. 18. An electrical power transmission line conductor as claimed in claim 17 wherein each magnetocaloric structure is formed using a power-in-tube method for forming the elongate wire comprising the magnetocaloric material. 19. A method of electrical power transmission line conductor design comprising the steps of: determining an anticipated operating temperature range for the electrical power transmission line conductor, and selecting at least one of a low temperature threshold and a high temperature threshold; selecting one or more magnetocaloric materials exhibiting magnetocaloric effects around the selected low temperature threshold or high temperature threshold; and determining an arrangement for at least one electrical conductor, at least one strengthening structure and one or more magnetocaloric structures within a conductor bundle, the position of the magnetocaloric structures being selected to ensure the position magnetocaloric structures will coincide with the changing magnetic field generated by alternating current electrical power transmission via conductors in the bundle. 20. A method as claimed in claim 19 wherein the step of selecting one or more magnetocaloric materials includes a step of tuning temperature for exhibition of the magnetocaloric effect to coincide with the selected low temperature threshold or high temperature threshold.