Wind turbine blade assembly

The invention claimed is: 1. A wind turbine blade assembly comprising: first and second blade sections connected together, each blade section having a shell defining an aerodynamic profile and each section comprising lightning protection components; a substantially enclosed interior region that is external to the second blade section and defined in part by the shell of the first blade section and in part by the shell of the second blade section; a first connector located in the interior region, the first connector being attached to the first blade section and electrically connected to the lightning protection components of the first blade section, the first connector defining a contact surface; a second connector located in the interior region, the second connector being attached to the second blade section and electrically connected to the lightning protection components of the second blade section, the second connector defining a contact surface opposed to and in physical contact with the contact surface of the first connector; and a first fastener extending through the shell of the first blade section into the interior region, the first fastener having a threaded shank that extends at least partially through the first and second connectors, wherein the first fastener clamps the contact surfaces of the first and second connectors together to form a torqued connection between the first and second connectors. 2. The wind turbine blade assembly of claim 1 , wherein the first blade section is a tip extension and the second blade section is a wind turbine blade adapted to receive the tip extension, or wherein the first and second blade sections are respective modules of a modular wind turbine blade. 3. The wind turbine blade assembly of claim 1 , wherein the first connector is attached to an inner surface of the shell of the first blade section and/or the second connector is attached to an end face of the second blade section or the second connector is attached to an inner surface of the shell of the second blade section. 4. The wind turbine blade assembly of claim 1 , wherein one of the first or second connectors comprises a through bore having a diameter that is oversized in comparison to a diameter of the shank of the first fastener and wherein the shank extends through the through bore and into mating engagement with the other connector. 5. The wind turbine blade of claim 1 , wherein a second fastener extends through the shell of the first blade section and at least partially through the first and second connectors, the first and second fasteners extending through opposite sides of the shell of the first blade section. 6. The wind turbine blade assembly of claim 1 , wherein the first and second connectors are shaped as wedges. 7. The wind turbine blade assembly of claim 1 , wherein the second connector is configured to bend or flex upon sliding contact with the first connector to cause the contact surface of the second connector to become flush with the contact surface of the first connector. 8. The wind turbine blade assembly of claim 1 , wherein the first blade section includes a metallic layer at or near an outer surface of its shell, and wherein the first fastener electrically connects the metallic layer to the first and second connectors. 9. The wind turbine blade assembly of claim 8 , wherein the second blade section includes a metallic layer at or near an outer surface of its shell and a further fastener extends through the shell of the second blade section to electrically connect the metallic layer of the second blade section with the second connector such that the first and second connectors electrically connect the respective metallic layers of the first and second blade sections. 10. The wind turbine blade assembly of claim 1 , wherein the contact surfaces of the first and second connectors are mutually parallel planar surfaces. 11. The wind turbine blade assembly of claim 1 , wherein the first fastener is a metal bolt. 12. A method of forming a blind connection between lightning protection components of a first blade section and lightning protection components of a second blade section when connecting the first and second blade sections together, the method comprising: providing a first blade section having a shell defining an aerodynamic profile, the first blade section comprising a first connector electrically connected to the lightning protection components of the first blade section, the first connector defining a contact surface; providing a second blade section having a shell defining an aerodynamic profile, the second blade section comprising a second connector electrically connected to the lightning protection components of the second blade section, the second connector defining a contact surface; arranging the first and second blade sections together such that the respective shells of the first and second blade sections define a substantially enclosed region that is external to the second blade section and defined in part by the shell of the first blade section and in part by the shell of the second blade section in which the first and second connectors are located with their respective contact surfaces mutually opposed and in physical contact; inserting a fastener through the shell of the first blade section such that a threaded shank of the fastener extends into the interior region and extends at least partially through the first and second connectors; and turning the fastener from outside the shell of the first blade section to create a clamping force between the contact surfaces of the first and second connectors thereby establishing a torqued connection between the first and second connectors. 13. The method of claim 12 , wherein the step of arranging the first and second blade sections together causes the first connector to slide into position relative to the second connector. 14. The method of claim 13 , wherein sliding contact between the contact surfaces of the connectors causes the second connector to bend or flex such that the contact surface of the first connector becomes flush with the contact surface of the second connector. 15. The method of claim 12 , wherein the connectors are wedge shaped and taper in thickness in opposite directions, such that sliding contact between the connectors causes intimate contact between the respective contact surfaces.