Method and apparatus for manufacturing a wind turbine blade component with uniform temperature curing

The invention claimed is: 1. A molding apparatus for manufacturing a wind turbine blade component having a component length, the molding apparatus comprising: a main mold body including a shape defining surface configured to receive composite material forming the blade component, the main mold body being divided in series along the component length into a plurality of mold body zones, each mold body zone including a heat reservoir configured to heat the blade component at that mold body zone, and the plurality of mold body zones being thermally isolated from one another by partitions; a flexible bladder configured to overlay the blade component on the shape defining surface and conform to a shape of the blade component, the flexible bladder receiving a heated liquid for heating the blade component; and a controller operatively coupled to the main mold body for independently controlling the temperature of the blade component at each mold body zone. 2. The molding apparatus according to claim 1 , further comprising: a first plurality of temperature sensors operatively coupled to the controller and thermally coupled to the plurality of mold body zones for sensing the temperature of each mold body zone and communicating these temperatures to the controller. 3. The molding apparatus according to claim 1 , wherein each of the heat reservoirs in the mold body zones includes a vessel for receiving a heated fluid, and the apparatus further comprises: a fluid pump for pumping the heated fluid to each of the vessels of the heat reservoirs; and a flow control valve associated with each of the mold body zones and operatively coupled to the controller, the flow control valves operated by the controller to adjust a flow rate of the heated fluid received in the corresponding vessels from the fluid pump. 4. The molding apparatus according to claim 1 , wherein the flexible bladder is divided along the component length into a plurality of bladder zones. 5. The molding apparatus according to claim 4 , wherein each of the plurality of bladder zones is positioned at a common location along the component length with a corresponding one of the plurality of mold body zones. 6. The molding apparatus according to claim 4 , further comprising: a second plurality of temperature sensors operatively coupled to the controller and thermally coupled to the plurality of bladder zones for sensing the temperature of each bladder zone and communicating these temperatures to the controller. 7. The molding apparatus according to claim 4 , further comprising: a liquid pump for pumping the heated liquid to each of the bladder zones; and a flow control valve associated with each of the bladder zones and operatively coupled to the controller, the flow control valves operated by the controller to adjust a flow rate of the heated liquid received in the corresponding bladder zone from the liquid pump. 8. The molding apparatus according to claim 1 , wherein each of the heat reservoirs in the mold body zones includes an electric heating device for heating the blade component, and wherein the flexible bladder includes a unitary bladder receiving heating liquid, the unitary bladder transferring heat energy from the heating liquid and each of the electric heating devices along the component length. 9. A method for manufacturing a wind turbine blade component having a component length, the method comprising: laying composite material onto a shape defining surface of a main mold body that is divided in series along the component length into a plurality of mold body zones, wherein the plurality of mold body zones are thermally isolated from one another by partitions; positioning a flexible bladder to overlay and conform to the composite material on the shape defining surface; curing the composite material by supplying heated liquid to the flexible bladder and by supplying heat energy from heat reservoirs located in each of the mold body zones; and controlling the temperature of the composite material at each of the mold body zones independently. 10. The method according to claim 9 , further comprising: sensing the temperature of each heat reservoir; and controlling the heat energy supplied to each heat reservoir to maintain a generally uniform temperature across each of the mold body zones. 11. The method according to claim 9 , wherein the flexible bladder is divided in series along the component length into a plurality of bladder zones, and curing the composite material further comprises: supplying heated liquid to each of the plurality of bladder zones independently. 12. The method according to claim 9 , wherein each of the heat reservoirs in the mold body zones includes an electric heating device for heating the blade component, the flexible bladder includes a unitary bladder receiving heating oil, and the method further comprises: transferring heat energy from the heating oil and each of the electric heating devices along the component length through the unitary bladder.