Lightning current transfer arrangement of a wind turbine

The invention claimed is: 1. A lightning current transfer arrangement for providing electrical contact between first and second parts of a wind turbine that are rotatable relative to each other, the lightning current transfer arrangement comprising: a current transfer unit electrically coupled to the first part, and an electrically conductive slideway electrically coupled to the second part, and rotatable relative to the current transfer unit, the current transfer unit comprising a slider elastically biased towards the slideway, wherein the slider comprises: a slide piece forming a first current path between the first and second parts through contact with the slideway, the slide piece formed of a conductive plastic material and configured to conduct electrostatic charge between the first and second parts, and a metal electrode rigidly coupled with the slide piece and configured to form a second current path between the first and second parts through the slideway, wherein the metal electrode forms the second current path when a voltage drop through the slide piece exceeds a predetermined maximum voltage drop. 2. The lightning current transfer arrangement according to claim 1 , wherein the conductive plastic material comprises at least one conductive additive. 3. The lightning current transfer arrangement according to claim 2 , wherein the at least one conductive additive is at least one of carbon black, graphite, metal flakes, metal fibers, particles or fibers coated with metal, conductively coated minerals, conductively coated ceramics, and pulverised anthracite. 4. The lightning current transfer arrangement according to claim 1 , wherein the conductive plastic material comprises one of an isolating matrix and a conductive matrix. 5. The lightning current transfer arrangement according to claim 1 , wherein the conducting plastic material exhibits an electric conductivity from about 10 −6 siemens per meter (S/m) to about 10 5 S/m. 6. The lightning current transfer arrangement according to claim 1 , wherein the metal electrode is arranged to also contact the slideway. 7. The lightning current transfer arrangement according to claim 6 , wherein the slide piece and the metal electrode each comprise a respective sliding surface, wherein the sliding surfaces of the slide piece and the metal electrode are co-planar. 8. The lightning current transfer arrangement according to claim 7 , wherein the sliding surface of the metal electrode is circumscribed by the sliding surface of the slide piece. 9. The lightning current transfer arrangement according to claim 1 , wherein the metal electrode is arranged to move over the slideway at a distance, thereby forming a spark gap to the slideway. 10. The lightning current transfer arrangement according to claim 9 , wherein the slide piece comprises a sliding surface, wherein the metal electrode is recessed from the sliding surface of the slide piece by a recess distance, and wherein the slide piece follows the slideway during movement thereby maintaining the distance between the metal electrode and the slideway at about the recess distance. 11. The lightning current transfer arrangement according to claim 9 , wherein the slide piece and the metal electrode are electrically connected in parallel, wherein the second current path is formed in parallel to the first current path upon occurrence of a spark bridging the spark gap. 12. The lightning current transfer arrangement according to claim 11 , wherein the slide piece provides an electric resistance in the first current path from about 10 kiloohms (kΩ) to about 10 megaohms (MΩ). 13. The lightning current transfer arrangement according to claim 1 , further comprising: a second slideway electrically coupled to the first part, the current transfer unit further comprising a second slider providing electrical contact to the second slideway, the second slider comprising a slide piece contacting the second slideway and an electrode oriented towards the second slideway. 14. The lightning current transfer arrangement according to claim 13 , wherein the wind turbine comprises at least one rotor blade and a nacelle, and wherein the lightning current transfer arrangement is arranged between the rotor blade and the nacelle, and enables charges to be discharged from the rotor blade to ground via the nacelle. 15. A wind turbine, comprising: a first part and a second part being rotatable relative to each other; and at least one lightning current transfer arrangement arranged to provide electrical contact between the first and second parts, wherein the lightning current transfer arrangement comprises: a current transfer unit electrically coupled to the first part, and an electrically conductive slideway electrically coupled to the second part, and rotatable relative to the current transfer unit, the current transfer unit comprising a slider elastically biased towards the slideway, wherein the slider comprises: a slide piece forming a first current path between the first and second parts through contact with the slideway, the slide piece formed of a conductive plastic material and configured to conduct electrostatic charge between the first and second parts, and a metal electrode rigidly coupled with the slide piece and configured to form a second current path between the first and second parts through the slideway, wherein the metal electrode forms the second current path when a voltage drop through the slide piece exceeds a predetermined maximum voltage drop. 16. The wind turbine of claim 15 , wherein the slide piece comprises a sliding surface and contacts the slideway at the sliding surface, wherein the metal electrode is recessed from the sliding surface of the slide piece by a recess distance, and wherein the predetermined maximum voltage drop is based on the recess distance. 17. A lightning current transfer arrangement for providing electrical contact between first and second parts of a wind turbine that are rotatable relative to each other, the lightning current transfer arrangement comprising: a current transfer unit electrically coupled to the first part, and an electrically conductive slideway electrically coupled to the second part, and rotatable relative to the current transfer unit, the current transfer unit comprising a slider elastically biased towards the slideway, wherein the slider comprises: a slide piece forming a first current path between the first and second parts through contact with the slideway and configured to conduct charge of an electrostatic discharge between the first and second parts when the electrostatic discharge results in a voltage drop through the slide piece that is less than a predetermined maximum voltage drop, and a metal electrode rigidly coupled with the slide piece and forming a second current path through the slideway, thereby conducting the charge of the electrostatic discharge between the first and second parts, when the voltage drop exceeds the predetermined maximum voltage drop of the slide piece. 18. The lightning current transfer arrangement of claim 17 , wherein the slide piece comprises a sliding surface and contacts the slideway at the sliding surface, wherein the metal electrode is recessed from the sliding surface of the slide piece by a recess distance, and wherein the predetermined maximum voltage drop is based on the recess distance. 19. The lightning current transfer arrangement of claim 17 , wherein the slide piece is further configured to limit an amount of current flowing th