Current distribution and thermal regulation in inductive power transfer coupling structures

The invention claimed is: 1. A magnetic structure for a magnetic flux coupling apparatus, the structure comprising: a plurality of pieces of magnetically permeable material arranged along a first dimension, each piece being separated from a neighbouring piece by a gap defining a separation distance; a conductor magnetically associated with the magnetically permeable material, wherein the separation distance is selected to prevent partial saturation of a selected region of the structure, wherein the selected region is adjacent to the conductor, or a plurality of turns of the conductor, and wherein the conductor comprises a multifilar winding comprising one or more turns wherein each filar crosses the other filars at a crossing point such that the inductance of each filar is substantially the same, and the crossing point is located in between the lengths of permeable material. 2. A magnetic structure for a magnetic flux coupling apparatus, the structure comprising: a plurality of pieces of magnetically permeable material arranged along a first dimension, each piece being separated from a neighbouring piece by a gap defining a separation distance, wherein the separation distance is selected to prevent partial saturation of a selected region of the structure, and wherein the separation distance provides an overall lower relative permeability for the structure relative to the relative permeability of the magnetically permeable material. 3. A magnetic structure for a magnetic flux coupling apparatus, the structure comprising: a plurality of pieces of magnetically permeable material arranged along a first dimension, each piece being separated from a neighbouring piece by a gap defining a separation distance, wherein the separation distance is selected to prevent partial saturation of a selected region of the structure, and wherein the pieces of magnetically permeable material may move relative to each other in a direction transverse to the first dimension. 4. The magnetic structure as claimed in claim 1 wherein the plurality of pieces of magnetically permeable material comprises a length of permeable material, and the magnetic structure comprises a plurality of lengths of permeable material. 5. The magnetic structure as claimed in claim 4 wherein the lengths are arranged in parallel to form a plane. 6. The magnetic structure as claimed in claim 5 wherein a heat transfer means is provided between the lengths. 7. The magnetic structure as claimed in claim 3 , wherein a heat transfer means is provided between the plurality of pieces of magnetically permeable material, and wherein the heat transfer means comprises a heat pipe. 8. The magnetic structure as claimed in claim 2 wherein the gap comprises a low permeability material having a lower relative permeability than the magnetically permeable material. 9. The magnetic structure as claimed in claim 8 wherein the separation distance and the low permeability material are selected to prevent partial saturation of the selected region. 10. The magnetic structure as claimed in claim 2 , further comprising a conductor magnetically associated with the ferrite. 11. The magnetic structure as claimed in claim 10 wherein the selected region is adjacent to the conductor, or a plurality of turns of the conductor. 12. The magnetic structure as claimed in claim 11 , wherein the conductor, or a plurality of turns of the conductor, is arranged substantially transverse to the first dimension at the selected region. 13. The magnetic structure as claimed in claim 1 , wherein the conductor is wound to provide two poles, and the gap is positioned to provide high or maximum relative permeability between the poles. 14. The magnetic structure as claimed in claim 11 wherein the conductor comprises a mulitfilar winding comprising one or more turns wherein each filar crosses the other filars at a crossing point such that the inductance of each filar is substantially the same, and the crossing point is located in between the lengths of permeable material. 15. A magnetic flux coupling apparatus comprising a mulitfilar winding having one or more turns, wherein the filars are physically arranged relative to each other, wherein each filar crosses the other filars at a crossing point such that the inductance of each filar is substantially the same. 16. The apparatus as claimed in claim 15 further including a magnetically permeable material magnetically associated with the multifilar winding. 17. The apparatus as claimed in claim 16 wherein the crossing point is located dependent on a characteristic of the permeable material. 18. The apparatus as claimed in claim 16 wherein the characteristic comprises a gap or recess in the permeable material. 19. A magnetic structure for a magnetic flux coupling apparatus, the structure comprising: a plurality of lengths of magnetically permeable material arranged substantially in parallel, wherein the lengths are separated from neighbouring lengths by a gap defining a separation distance, and wherein a means for heat transfer is provided between at least two of the lengths, wherein the magnetic structure is part of a vehicle wireless charging system, wherein the separation distance is selected to prevent partial saturation of a selected region of the structure, and wherein the separation distance provides an overall lower relative permeability for the structure relative to the relative permeability of the magnetically permeable material. 20. The magnetic structure as claimed in claim 2 further comprising a conductor magnetically associated with the magnetically permeable material, wherein the conductor is located only on one side of the magnetically permeable material. 21. The magnetic structure as claimed in claim 2 wherein the overall lower relative permeability is in the range of 50-2000. 22. The magnetic structure as claimed in claim 2 wherein the overall lower relative permeability is in the range of 50-500. 23. The apparatus as claimed in claim 15 wherein a mean area circumscribed by the filars of the multifilar winding is substantially equal. 24. The apparatus as claimed in claim 15 wherein there are M number of one or more turns, and wherein the filars of the multifilar winding crosses the other filars of the multifilar winding M, or M−1, or M+1 times per turn. 25. The magnetic structure as claimed in claim 2 wherein the plurality of pieces are ferrite pieces, and there are a plurality of gaps that separate neighbouring pieces of the plurality of pieces, and wherein the plurality of gaps reduce the overall permeability of the magnetic structure by 88 to 96 percent from an ideal all-ferrite strip structure.