Method of de-icing a wind turbine blade

What is claimed is: 1. A method of de-icing a wind turbine blade, the method comprising: generating heated air using heating means provided in a root portion of the blade; and circulating the heated air around an interior of the blade through at least a portion of two more longitudinal blade cavities defined within the blade, the circulating including: channeling the heated air from an outlet of the heating means at least part way through a first longitudinal blade cavity, wherein the first longitudinal blade cavity is a trailing edge cavity defined between one or more longitudinal webs and a trailing edge of the blade, towards a tip end of the blade; at a position along a length of the blade, diverting a first portion of the heated air from the trailing edge cavity into a central cavity and diverting a second portion of the heated air from the trailing edge cavity into a leading edge cavity; and channeling the diverted air at least part way through the leading edge cavity and the central cavity back to an inlet of the heating means, wherein the heated air is circulated through the trailing edge cavity, the central cavity defined between longitudinal webs extending through the interior of the blade, and the leading edge cavity defined between one or more longitudinal webs and the leading edge of the blade. 2. A method according to claim 1 further comprising: at a position along the length of the blade, diverting the first portion of the heated air out of the central cavity into the leading edge cavity; and channeling the diverted first portion of the heated air back to the one or more inlets of the heating means in combination with the second portion of heated air in the leading edge cavity. 3. A method according to claim 1 wherein the heated air is diverted from the trailing edge cavity into the central cavity and the leading edge cavity in a tip portion of the blade. 4. A method according to claim 3 comprising diverting the first portion of the heated air out of the central cavity into the leading edge cavity at least one quarter of the way along the length of the blade from the tip end. 5. A method according to claim 1 wherein the heated air is circulated through the interior of the blade using one or more fans provided within the heating means. 6. A method according to claim 1 further comprising: monitoring a temperature at the blade; and controlling the heating means to adjust the temperature of the heated air generated depending on the temperature at the blade. 7. A method according to claim 1 further comprising: monitoring an air flow within the blade; and controlling the heating means depending on the air flow within the blade. 8. A method according to claim 6 comprising controlling at least one of: a power supplied to the heating means and a flow rate of air through the heating means. 9. A method according to claim 1 further comprising: monitoring the blade using one or more sensors to detect a presence of ice on a blade surface; and activating the circulation of heated air upon detection of ice on the blade surface. 10. A method according to claim 1 further comprising: monitoring a power curve of the wind turbine to detect a change in the power curve as a result of a presence of ice on the blade surface; and activating the circulation of heated air upon detection of ice on the blade surface. 11. A wind turbine including one or more wind turbine blades, each blade comprising: an outer shell; one or more longitudinal webs provided within the outer shell and extending longitudinally through an interior of the blade, wherein the one or more longitudinal webs define a cavity structure within the interior of the blade including: a longitudinal leading edge cavity defined between a leading edge of the blade and one or more longitudinal webs, a longitudinal trailing edge cavity defined between a trailing edge of the blade and one or more longitudinal webs, and a central cavity defined between a pair of longitudinal webs and positioned between the leading edge cavity and the trailing edge cavity; a partition within the central cavity at a position along a length of the central cavity and one or more openings within the longitudinal webs to provide a flow pathway between the central cavity and the leading edge cavity, wherein the one or more openings are provided at one or more locations between the partition and a tip end of the blade; and heating means provided in a root portion of the blade, the heating means comprising: one or more air inlets for receiving air channeled through the leading edge cavity; one or more heaters for heating air entering through the one or more air inlets; one or more air outlets for channeling heated air into the trailing edge cavity of the blade; and means for circulating the heated air from the one or more air outlets around the interior of the blade and back to the one or more inlets, wherein the heating means are adapted to circulate heated air through the trailing edge cavity, the leading edge cavity and the central cavity. 12. A wind turbine according to claim 11 wherein each blade further comprises means for diverting the heated air from one of the longitudinal leading edge cavity and the longitudinal trailing edge cavity into at least one of the other longitudinal cavities. 13. A wind turbine according to claim 12 wherein each blade comprises diverting means provided between at least two of the longitudinal blade cavities, in the tip portion of the blade. 14. A wind turbine according to claim 13 wherein the diverting means provided in the tip portion of the blade comprises a partition extending from the tip end of the blade. 15. A wind turbine according claim 12 wherein each blade comprises diverting means provided at an intermediate position between the root portion of the blade and the tip end of the blade. 16. A wind turbine according to claim 11 wherein the heating means of each blade is provided within the central cavity of the blade. 17. A wind turbine according to claim 11 wherein each blade further comprises means for isolating the longitudinal cavities from each other at the root portion of the blade. 18. A wind turbine according to claim 11 wherein each blade comprises an inner spar extending through the interior of the blade, the spar including a pair of webs defining the central cavity inside the inner spar. 19. A wind turbine according to claim 11 wherein insulation material is provided within the trailing edge cavity defined inside the blade, along at least a part of the length of the blade. 20. A wind turbine according to claim 11 wherein insulation material is provided within the central cavity of each blade, along at least a part of the length of the blade. 21. A wind turbine blade according to claim 11 wherein each blade further comprises one or more air ducts for channeling the heated air into or out of the heating means. 22. A wind turbine according to claim 11 wherein each blade further comprises control means for controlling the heating means within that blade. 23. A wind turbine according to claim 22 wherein each blade further comprises one or more temperature sensors for monitoring the temperature at the blade and providing an output to the control means within that blade, wherein the control means is adapted to operatively control the associated heating means based on the output received from the temperature sensors. 24. A wind tu