Wind turbine rotor blade spar cap with equipotential bonding

The invention claimed is: 1. A wind turbine rotor blade spar cap, the spar cap having a length and comprising: a stack comprising a plurality of layers of conductive material and at least one intermediate layer, wherein the layers of conductive material each have a length along the length of the spar cap in a first direction, wherein the intermediate layer is arranged between adjacent layers of the conductive material, wherein the intermediate layer includes a fibre fabric material having: a first edge (E) extending in the first direction, a conductive portion (C) having conductive fibres oriented in the first direction, a first border portion (B) between the first edge (E) and the conductive portion (C), the first border portion having a plurality of non-conductive fibres oriented in the first direction and no conductive fibres oriented in the first direction, and cross fibres oriented to cross the conductive fibres and the non-conductive fibres, and wherein the intermediate layer is bonded with the adjacent layers of the conductive material and is electrically coupled to the adjacent layers of conductive material so as to equipotentially bond the adjacent layers of the conductive material via the conductive portion (C) of the intermediate layer. 2. The wind turbine rotor blade spar cap of claim 1 , wherein the first border portion has a width perpendicular to the first direction, the width of the first border portion being at least 5 millimetres. 3. The wind turbine rotor blade spar cap of claim 1 , wherein the conductive fibres are carbon fibres. 4. The wind turbine rotor blade spar cap of claim 1 , wherein all conductive fibres of the fibre fabric material are oriented in the first direction. 5. The wind turbine rotor blade spar cap of claim 1 , wherein the non-conductive fibres are glass fibres. 6. The wind turbine rotor blade spar cap of claim 1 , wherein the cross fibres are non-conductive cross fibres, optionally wherein the non-conductive cross fibres are glass fibres. 7. The wind turbine rotor blade spar cap of claim 1 , wherein the cross fibres are oriented perpendicular to the first direction. 8. The wind turbine rotor blade spar cap of claim 1 , wherein the conductive material comprises pultruded fibrous composite material, preferably carbon fibre reinforced plastic. 9. The wind turbine rotor blade spar cap of claim 1 , further comprising alternating layers of the conductive material and the intermediate layer. 10. The wind turbine rotor blade spar cap of claim 1 , wherein the fibre fabric material further comprises a second edge oriented in the first direction, the second edge being opposite the first edge, and a second border portion between the second edge and the conductive portion, the second border portion having a plurality of non-conductive fibres oriented in the first direction and no conductive fibres oriented in the first direction. 11. The wind turbine rotor blade spar cap of claim 10 , wherein the second border portion has a width perpendicular to the first direction, the width of the second border portion being at least 5 millimetres. 12. The wind turbine rotor blade spar cap of claim 1 , wherein the fibre fabric material is woven or stitched. 13. A wind turbine rotor blade including at least one wind turbine rotor blade spar cap according to claim 1 . 14. A method of manufacturing a wind turbine rotor blade spar cap, comprising: providing a plurality of layers of conductive material, each layer having a length along a length of the spar cap in a first direction; placing an intermediate layer between adjacent layers of the conductive material so as to form a stack, the intermediate layer including a fibre fabric material having: a first edge extending in the first direction; a conductive portion having conductive fibres oriented in the first direction, a first border portion between the first edge and the conductive portion, the first border portion having a plurality of non-conductive fibres oriented in the first direction and no conductive fibres oriented in the first direction; and cross fibres oriented to cross the conductive fibres and the non-conductive fibres; electrically coupling the intermediate layer to the adjacent layers of conductive material so as to equipotentially bond the adjacent layers of the conductive material via the conductive portion of the intermediate layer; and curing the stack to mechanically bond the intermediate layer to the adjacent layers of the conductive material.