Method of manufacturing a wind turbine blade using pre-fabricated stacks of reinforcing material

The invention claimed is: 1. A method of manufacturing a wind turbine blade, comprising: cutting a plurality of plies of reinforcing material to form a stack; joining the plurality of plies of reinforcing material to one another along a common edge to from a spine; leaving the edge of the plurality of plies of reinforcing material opposite the spine unjoined to form an open end of the stack, and so that the plies in the stack are free to slide across one another; and laying the stack in a wind turbine blade mould. 2. The method of claim 1 , comprising: refraining from adding seams to the stack that extend fully or partially between the sides of the stack between the spine and the open end. 3. The method of claim 1 , wherein the lengths of the plies are cut to give the stack a chamfer or wedge-shape at its open end. 4. The method of claim 1 comprising attaching a hem to the edge of the stack forming a spine, wherein the hem allows the stack to be handled. 5. The method of claim 4 , comprising installing attachment members in the hem for engaging with one or more support members. 6. A method of manufacturing a wind turbine blade using a mould surface defining the profile of one half of the shell of the wind turbine blade in the blade chord direction from the blade trailing edge to the blade leading edge, and a mould root section corresponding to a root section of the wind turbine blade; a) receiving a plurality of stacks of reinforcing material for installation in the wind turbine blade mould, wherein each stack includes a plurality of plies of reinforcing material joined to one another along a common edge to form a spine while the opposite edge of the stack is unjoined so that the plies in the stack are free to slide across one another, and each stack has a length such that when laid in the wind turbine blade mould the stack extends along the mould surface of the blade mould from either the trailing or leading edge to a point on the mould surface between the trailing or leading edge; b) laying a first stack of reinforcing material in the mould so that the spine of the first stack is positioned at the either the trailing or leading edge of the mould and so that the stack extends to a point on the mould surface between the trailing and leading edge; and c) laying a second stack of reinforcing material in the mould so that the spine of the second stack is positioned at the other of the trailing or leading edges and so that the stack extends to a point on the mould surface between the trailing and leading edge and meets the first stack. 7. The method of claim 6 , wherein step b) comprises: suspending the first stack of reinforcing material above the mould so that its spine is upwards and so that the edge of the stack opposite the spine hangs downwards; after the suspending step, lowering the first stack towards the mould surface so that the edge of the stack opposite the spine makes contact with the mould surface first; continuing to lower the first stack into the mould, keeping contact between the mould surface and the first stack, until the first stack is in position; and wherein step c) comprises: suspending the second stack of reinforcing material above the wind turbine blade mould so that its spine is upwards, and so that the edge opposite the spine hangs downwards; after the suspending step, lowering the second stack towards the mould surface so that the edge of the stack opposite the spine makes contact with the mould surface first; continuing to lower the second stack into the mould, keeping contact between the mould surface and the second stack, until the second stack is in position. 8. The method of claim 6 , wherein step b) comprises: suspending the first stack of reinforcing material above the root section of the wind turbine blade mould so that its spine is upwards, and so that the edge of the stack opposite the spine hangs downwards over a point of the mould surface intermediate the trailing and leading edge; after the suspending step, lowering the first stack towards the mould surface so that the edge of the stack opposite the spine makes contact with the mould wall surface; lowering the spine of the stack towards one of the trailing or leading edges of the mould, until the first stack is in position; and wherein step c) comprises: suspending the second stack of reinforcing material above the root section of the wind turbine blade mould so that its spine is upwards, and so that the edge of the stack opposite the spine hangs downwards over a point of the mould surface intermediate the trailing and leading edge; after the suspending step, lowering the second stack towards the mould surface so that the edge of the stack opposite the spine makes contact with the mould surface first, or with the stack already in place; lowering the spine of the second stack towards the other of the trailing or leading edges of the mould, until the second stack is in position against the first. 9. The method of claim 8 comprising: after the edge of the first stack opposite the spine makes contact with the mould surface, placing an anchor on the edge of the first stack opposite the spine for the subsequent step of lowering the spine of the first stack; and after the edge of the second stack opposite the spine makes contact with the mould surface, or with the stack already in place, placing an anchor on the edge of the second stack opposite the spine for the subsequent step of lowering the spine of the second stack. 10. The method of claim 7 , wherein the suspending steps comprise suspending the first and/or the second stacks vertically above the mould. 11. The method of claim 10 , wherein the suspending steps comprise pausing with the first and the second sheets suspended vertically above the mould. 12. The method of claim 6 , wherein the edge of the stack opposite the spine is wedge-shaped or chamfered, so that when the first and the second stacks are in position in the mould the chamfered edge of the first stack lies across the chamfered edge of the second stack. 13. The method of claim 6 , wherein the reinforcing material comprises one or more of a glass fibre material, a carbon fibre, an aramid fibre, a polyester fibre material or a combination of these. 14. The method of claim 6 , comprising laying stacks of reinforcing material in the root section of a wind turbine blade to cover a region of the mould from the blade root bearing to a point at which the spar caps begin. 15. The method of claim 14 , wherein the side of the stacks of reinforcing material adjacent the point at which the spar caps begin is chamfered or wedge-shaped so that once installed the thickness of the stack decreases in the span-wise direction of the blade.