Pipe body cathodic protection

The invention claimed is: 1. A flexible pipe for subsea transportation of production fluids, comprising: a fluid retaining layer; an outer sheath; and at least one tensile armour layer comprising a plurality of helically wound monofilament armour wires of a first material, each having a non-circular cross section with an aspect ratio of greater than 1:2 disposed between the fluid retaining layer and the outer sheath; wherein the tensile armour layer further comprises at least one helically wound elongate anode element substantially having a cross-section aspect ratio of 1:1 and comprising a further material, interposed between armour wires, the anode element cross section having an area that is 50% or less of a corresponding area of said non-circular cross section. 2. The flexible pipe as claimed in claim 1 wherein said further material is more electrically reactive than said first material and is optionally circular, or square, or hexagonal, or I-shaped in cross-section. 3. The flexible pipe as claimed in claim 1 , further comprising: said a further material is more reactive to a corrosive environment of a seawater holding pipe annulus region in the flexible pipe than said first material of the armour wires. 4. The flexible pipe as claimed in claim 1 , further comprising: said a further material of each anode element is at least partially dissolvable in seawater. 5. The flexible pipe as claimed in claim 1 wherein each anode element extends a whole length along the flexible pipe between end fittings that terminate respective ends of the flexible pipe. 6. The flexible pipe as claimed in claim 1 wherein each anode element is a galvanic anode. 7. The flexible pipe as claimed in claim 1 wherein each anode element comprises at least one elongate strand of said a further material. 8. The flexible pipe as claimed in claim 7 , further comprising: each anode element comprises a monofilament wire or a wire-strand comprising a plurality of elongate filaments of said a further material and optionally the wire-strand anode elements thickness in a radial direction is between 110% and 135% of the thickness of the tensile armour wires in the same tensile armour layer. 9. The flexible pipe as claimed in claim 1 , further comprising: each anode element comprises an elongate core, comprising a still further material, that extends along a whole length of the anode element and optionally said still further material of the core has a strength greater than a strength of said further material. 10. The flexible pipe as claimed in claim 1 , further comprising: each anode element comprises a perforated casing, comprising a still further material, that extends along a whole length of the anode element and optionally said still further material of the perforated casing has as strength greater than a strength of said further material. 11. The flexible pipe as claimed in claim 1 , further comprising: the tensile armour layer comprises a plurality of elongate anode elements. 12. The flexible pipe as claimed in claim 11 , further comprising: the plurality of elongate anode elements are spaced apart circumferentially in the tensile armour layer. 13. The flexible pipe as claimed in claim 12 , further comprising: the elongate anode elements are evenly distributed circumferentially in the tensile armour later. 14. The flexible pipe as claimed in claim 1 , further comprising: a thickness of each monofilament anode element in a radial direction, is less than a corresponding thickness of each of the tensile armour wires in a common tensile armour layer and optionally said a thickness is about 95% to 98% of said a corresponding thickness. 15. The flexible pipe as claimed in claim 1 , further comprising: at least one tape layer on a radially inner and/or radially outer surface of the tensile armour layer, comprising at least one helically wound electrically conductive tape element. 16. The flexible pipe as claimed in claim 15 , further comprising: the tape layer comprises said at least one helically wound electrically conductive tape element and at least one electrically insulating tape element with windings of the electrically insulating tape element being interposed between windings of the electrically conductive tape element. 17. The flexible pipe as claimed in claim 16 , further comprising: the tensile armour layer comprises a radially inner tensile armour layer of the flexible pipe and the tape layer is interposed between the tensile armour layer and a pressure armour layer disposed radially outside of the fluid retaining layer. 18. A method of manufacturing flexible pipe body, comprising the steps of: providing a fluid retaining layer; providing at least one tensile armour layer by helically winding tensile armour wires of a first material, each having a cross section with an aspect ratio of greater than 1:2, over an underlying layer; simultaneously helically winding at least one elongate anode element substantially having a cross-section aspect ratio of 1:1 that has an area that is 50% or less than a corresponding area of said anode element cross section, and comprising a further material different to said first material, with the armour wires whereby said at least one anode element is interposed between adjacent armour wires; and providing an outer sheath. 19. The method as claimed in claim 18 , further comprising: helically winding a plurality of discrete elongate anode elements in a circumferentially spaced apart relationship with the armour wires in the tensile armour layer.