Lightning protection covering

The invention claimed is: 1. A covering system for protecting a surface of a composite article from lightning strikes, wherein the surface includes at least one grounding connection, the covering system comprising: an underlayment comprising one or more sheets of material configured to be affixed to the composite article over a region of the surface adjacent the at least one grounding connection, the underlayment configured to include at least one layer of conductive material along said region of the surface; and an overlaminate comprising one or more sheets of perforated dielectric material configured to be affixed to the composite article over the at least one layer of conductive material; wherein the at least one layer of conductive material comprises a lower conductive layer, the underlayment further comprising a middle dielectric layer formed from electrically insulating material and an upper conductive layer formed from electrically conductive material. 2. The covering system of claim 1 , wherein the middle dielectric layer is sandwiched between the upper and lower conductive layers and adhesively bonded thereto. 3. The covering system of claim 1 , wherein the underlayment comprises a prefabricated sheet that includes the lower conductive layer, the middle dielectric layer, and the upper conductive layer, the prefabricated sheet being configured to be affixed to the surface of the article as a unit. 4. The covering system of claim 1 , wherein the one or more sheets of perforated dielectric material comprises a dielectric web defining a plurality of perforations, the dielectric web being configured to cause each lightning strike to separate into discrete streamers that pass into the underlayment through respective ones of the perforations. 5. The covering system of claim 1 , wherein at least about 10% of the total area of the perforated dielectric material is removed by perforations. 6. The covering system of claim 1 , wherein each of the one or more sheets of perforated dielectric material has a thickness, a length, a width, and a plurality of perforations through the thickness, the perforations being distributed along the length and the width of the sheet of perforated dielectric material. 7. The covering system of claim 6 , wherein each of the one or more sheets of perforated dielectric material comprises web which defines the perforations. 8. The covering system of claim 6 , wherein the perforations are regularly spaced along the length and the width of the overlaminate. 9. The covering system of claim 1 , wherein the underlayment comprises at least one contiguous layer of conductive material spanning across perforations of the perforated dielectric material. 10. A covering system for protecting a surface of a composite article from lightning strikes, wherein the surface includes at least one grounding connection, the covering system comprising: an underlayment comprising one or more sheets of material configured to be affixed to the composite article over a region of the surface adjacent the at least one grounding connection, the underlayment configured to include at least one layer of conductive material along said region of the surface; and an overlaminate comprising one or more sheets of perforated dielectric material configured to be affixed to the composite article over the at least one layer of conductive material; wherein the underlayment has a perimeter edge margin and the overlaminate has a perimeter edge margin, the perimeter edge margin of the overlaminate being configured to overhang the perimeter edge margin of the underlayment. 11. The covering system of claim 10 , further comprising caulk configured to be applied atop the overlaminate to seal the perimeter edge margin of the underlayment and the perimeter edge margin of the overlaminate. 12. A wind turbine blade assembly comprising: a wind turbine blade including at least one grounding connection exposed along a blade surface of the wind turbine blade; an underlayment affixed to the wind turbine blade over a portion of the blade surface adjacent the at least one grounding connection, the underlayment comprising a layer of conductive material; and an overlaminate affixed to the blade surface over the underlayment, the overlaminate comprising a layer of dielectric material having a plurality of perforations distributed along the layer through which electrical current of one or more lightning strikes is passable to the underlayment. 13. The wind turbine blade assembly of claim 12 , wherein the underlayment comprises a perimeter edge margin spaced from the grounding connection and the overlaminate comprises a perimeter edge margin spaced from the grounding connection. 14. The wind turbine blade assembly of claim 13 , further comprising caulk sealing the perimeter edge margin of the underlayment and the perimeter edge margin of the overlaminate. 15. The wind turbine blade assembly of claim 14 , wherein the perimeter edge margin of the overlaminate overhangs the perimeter edge margin of the underlayment. 16. The wind turbine blade assembly of claim 13 , wherein the perimeter edge margin of the overlaminate overhangs the perimeter edge margin of the underlayment. 17. The wind turbine blade assembly of claim 12 , wherein the underlayment comprises a lower conductive layer, the underlayment further comprising a middle dielectric layer formed from electrically insulating material and an upper conductive layer formed from electrically conductive material. 18. The wind turbine blade assembly of claim 12 , wherein the layer of dielectric material is configured to cause a lightning strike to separate into discrete streamers that pass into the underlayment through respective ones of the perforations. 19. The wind turbine blade assembly of claim 12 , wherein at least about 20% of the total area of the perforated dielectric material is removed by the perforations. 20. The wind turbine blade assembly of claim 12 , wherein the underlayment and the overlaminate comprise a notch cut larger than the grounding connection, said notch positioned adjacent to the grounding connection and not in contact with the grounding connection. 21. A method of protecting a composite article from lightning strikes, wherein the composite article comprises a surface and a grounding connection exposed along the surface, the method comprising: forming an underlayment on the composite article over a portion of the surface adjacent the grounding connection, the underlayment comprising at least one layer of conductive material; forming an overlaminate on the composite article over the at least one layer of conductive material the overlaminate comprising a dielectric web defining a plurality of perforations distributed along the dielectric web, the electrical current of one or more lightning strikes being passable through the perforations to the underlayment; wherein forming the underlayment comprises cutting one or more sheets of prefabricated sheet to size and joining the cut sheets to the surface of the composite article, each prefabricated sheet having a lower conductive layer, a middle dielectric layer, and an upper conductive layer. 22. A method of protecting a composite article from lightning strikes, wherein the composite article comprises a surface and a grounding connection exposed along the surface, the method comprising: forming an underlayment on the composite article over a portion of the surface adjacent the grounding connection, the u