Method of manufacturing a shell of a wind turbine blade

The invention claimed is: 1. A method for manufacturing a shell ( 36 and 38 ), the method comprising: laying one or more layers of fibers, on a surface of a mould ( 9 ) to form at least a portion of a shell half structure ( 36 and 38 ); positioning a first panel ( 11 ) defined with noise reduction members ( 11 a ) adjacent the one or more layers of fibers on the surface of the mould ( 9 ); fusing a peel ply ( 15 ) on a first region (A); following the fusing of the peel ply ( 15 ) on the first region (A), infusing resin through the one or more layers of fibers and the first panel ( 11 ), and subsequently curing the same to obtain the shell half structure ( 36 or 38 ), wherein the first panel ( 11 ) with noise reduction members ( 11 a ) adheres to the shell half structure ( 36 and 38 ) upon curing the infused resin; and adjoining a second panel ( 13 ) with the first panel ( 11 ), wherein the second panel ( 13 ) is defined with projections ( 13 a ) complementing a profile of the noise reduction members ( 11 a ). 2. The method according to claim 1 , wherein the shell half structure ( 36 or 38 ) is defined with a leading edge ( 18 ) and a trailing edge ( 20 ), wherein the first panel ( 11 ) is adjoined adjacent to the at least one of the leading edge ( 18 ) and the trailing edge ( 20 ). 3. The method according to claim 2 , wherein the first panel ( 11 ) is adjoined adjacent to the trailing edge ( 20 ) of the shell half structure ( 36 or 38 ). 4. The method according to claim 1 , wherein the first panel ( 11 ) is defined by a first end ( 11 b ) and a second end ( 11 c ) with the first end ( 11 b ) defined with the noise reduction members ( 11 a ). 5. The method according to claim 4 , wherein the second end ( 11 c ) of the first panel ( 11 ) is positioned between the one or more layers of fibers forming a trailing edge ( 20 ) of the shell half structure ( 36 or 38 ). 6. The method according to claim 4 , wherein an end of the second panel ( 13 ) defined with projections ( 13 a ) is adjoined to the first end ( 11 b ) of the first panel ( 11 ). 7. The method according to claim 1 , wherein the second panel ( 13 ) is made of a silicone material. 8. The method according to claim 1 , further comprising peeling off the peel ply ( 15 ) from the first region (A) after the resin is infused and cured from the one or more layers of fibers and the first panel ( 11 ). 9. The method according to claim 8 , wherein the second panel ( 13 ) is separated from the first panel ( 11 ) along with the peel ply ( 15 ) when the peel ply ( 15 ) is separated from the first region (A). 10. A wind turbine blade ( 10 ) comprising a shell half structure ( 36 and 38 ) and a first panel ( 11 ) defined with noise reduction members ( 11 a ) adhered to the shell half structure ( 36 and 38 ) through the resin infusion process as claimed in claim 1 . 11. The method according to claim 1 , wherein the projections ( 13 a ) defined in the second panel ( 13 ) mate with the noise reduction members ( 11 a ) of the first panel ( 11 ) defining the first region (A). 12. A method of manufacturing a wind turbine blade ( 10 ) having a profiled contour including a pressure side and a suction side, and a leading edge ( 18 ) and a trailing edge ( 20 ) with a chord having a chord length extending therebetween, the wind turbine blade ( 10 ) extending in a spanwise direction between a root end and a tip end, the method comprises: laying one or more layers of fibers, on a surface of a mould ( 9 ) to form a first shell half structure ( 36 ) and a second shell half structure ( 38 ) separately; joining a first panel ( 11 ) defined with noise reduction members ( 11 a ) to at least one of a leading edge ( 18 ) and a trailing edge ( 20 ) of the at least one of first shell half structure ( 36 ) and the second shell half structure ( 38 ); fusing a peel ply ( 15 ) on a first region (A); following the fusing of the peel ply ( 15 ) on the first region (A), infusing resin through the one or more layers of fibers and the first panel ( 11 ), and subsequently curing the same to obtain one of the first shell half structure or the second shell half structure ( 36 or 38 ), wherein the first panel ( 11 ) with noise reduction members ( 11 a ) adheres to the one of the first shell half structure or the second shell half structure ( 36 and 38 ) upon curing the infused resin; adjoining a second panel ( 13 ) with the first panel ( 11 ), wherein the second panel ( 13 ) is defined with projections ( 13 a ) complementing the profile of the noise reduction members ( 11 a ), wherein the projections ( 13 a ) defined in the second panel ( 13 ) mate with the noise reduction members ( 11 a ) of the first panel 11 defining the first region (A); and joining the first shell half structure ( 36 ) with the second shell half structure ( 38 ) to obtain the wind turbine blade ( 10 ). 13. The method according to claim 12 , wherein the first panel ( 11 ) is defined by a first end ( 11 b ) and a second end ( 11 c ) with the first end ( 11 b ) defined with the noise reduction members ( 11 a ) and the second end ( 11 c ) positioned between the one or more layers of fibers forming the trailing edge ( 20 ) of the one of the first shell half structure or the second shell half structure ( 36 or 38 ). 14. The method according to claim 12 , wherein the second panel ( 13 ) is made of a silicone material. 15. The method according to claim 12 , further comprising peeling off the peel ply ( 15 ) from the first region (A) after the resin is infused and cured from the one or more layers of fibers and the first panel ( 11 ). 16. The method according to claim 15 , wherein the second panel ( 13 ) is separated from the first panel ( 11 ) along with the peel ply ( 15 ) when the peel ply ( 15 ) is separated from the first region (A). 17. The method according to claim 12 , wherein the first panel ( 11 ) defined with the noise reduction members ( 11 a ) is joined to the trailing edge ( 20 ) of the at least one of the first shell half structure ( 36 ) and the second shell half structure ( 38 ).