Wind turbine blade, wind turbine rotor, wind turbine power generating apparatus, and method of mounting vortex generator

The invention claimed is: 1. A wind turbine blade, comprising: a blade body; and a vortex generator mounted to a surface of the blade body, wherein the vortex generator includes a plurality of fin sets, each fin set including a plurality of fins disposed so as to protrude from the surface of the blade body at different positions from one another in a blade spanwise direction, and wherein the plurality of fin sets is positioned so that, in a planar development view of the surface of the blade body, an angle θ formed by a center axis of a blade root of the blade body with a line connecting two of the fin sets which are adjacent in the blade spanwise direction increases toward the blade root, at least in a part of a region of the blade body between a position of the blade root and a maximum chord-length position of the blade body in the blade spanwise direction. 2. The wind turbine blade according to claim 1 , wherein the plurality of fin sets is positioned so that the angle θ satisfies, in at least a part of the region between the position of the blade root and the maximum chord-length position, an expression: 3 ⁢ ° ≦ θ ≦ d 2 ⁢ λμ 2 ⁢ R × 180 π ⁡ [ ° ] where d is an outer diameter of the blade body at the position of the blade root, λ is a design tip speed ratio of a wind turbine to which the wind turbine blade is mounted, R is a distance between a rotational center of a wind turbine rotor including the wind turbine blade and a tip of the blade body, r is a distance between the rotational center and the fin set which is disposed closer to the blade root of the two adjacent fin sets, and μ is a dimensionless radial position being a ratio (r/R) of r to R. 3. The wind turbine blade according to claim 2 , wherein the plurality of fin sets is positioned so that the angle θ satisfies an expression θ≤(0.0034/μ 2 )×(180/π) [°]. 4. The wind turbine blade according to claim 2 , wherein the plurality of fin sets is positioned so that the angle θ satisfies an expression θ≥(0.0021/μ 2 )×(180/π) [°]. 5. The wind turbine blade according to claim 1 , wherein the plurality of fin sets is positioned so that the angle θ increases toward the blade root, in a range where μ satisfies an expression 0.10≤μ≤0.15, where R is a distance between a rotational center of a wind turbine rotor including the wind turbine blade and a tip of the blade body, r is a distance between the rotational center and the fin set which is disposed closer to the blade root of the two adjacent fin sets, and μ is a dimensionless radial position being a ratio (r/R) of r to R. 6. The wind turbine blade according to claim 1 , wherein the plurality of fins is positioned so that the angle θ increases toward the blade root, at least in a region in the blade spanwise direction in which a blade thickness ratio (t/c) satisfies an expression 70%≤(t/c)≤85%, the blade thickness ratio (t/c) being a ratio of a blade thickness t of the blade body to a chord length c of the blade body. 7. The wind turbine blade according to claim 1 , wherein each of the plurality of fin sets comprises a VG unit including: a platform portion fixed to the surface of the blade body; and one or two of the fins erected on the platform portion. 8. The wind turbine blade according to claim 1 , wherein the vortex generator is disposed, on a suction surface of the blade body, in a turbulence region of a wind flow along the suction surface. 9. A wind turbine rotor, comprising: the wind turbine blade according to claim 1 ; and a hub to which the wind turbine blade is mounted. 10. A wind turbine power generating apparatus comprising the wind turbine rotor according to claim 9 . 11. A method of mounting a vortex generator to a surface of a wind turbine blade, the vortex generator comprising a plurality of fin sets each of which includes a plurality of fins, the method comprising: a step of mounting the plurality of fin sets to the wind turbine blade so that the plurality of fins protrude from the surface of the wind turbine blade at positions different from one another in a blade spanwise direction, and, in a planar development view of the surface of the wind turbine blade, an angle θ formed by a center axis of a blade root of the wind turbine blade with a line connecting two of the plurality of fin sets which are adjacent in the blade spanwise direction increases toward the blade root, at least in a part of a region of the wind turbine blade between a position of the blade root and a maximum chord-length position of the wind turbine blade in the blade spanwise direction. 12. The method of mounting a vortex generator according to claim 11 , wherein the mounting step includes positioning the plurality of fin sets so that the angle θ satisfies, in at least a part of the region between the position of the blade root and the maximum chord-length position, an expression: 3 ⁢ ° ≦ θ ≦ d 2 ⁢ λμ 2 ⁢ R × 180 π ⁡ [ ° ] where d is an outer diameter of the wind turbine blade at the position of the blade root, λ is a design tip speed ratio of a wind turbine to which the wind turbine blade is mounted, R is a distance between a rotational center of a wind turbine rotor including the wind turbine blade and a tip of the wind turbine blade, r is a distance between the rotational center and the fin set which is disposed closer to the blade root of the two adjacent fin sets, and μ is a dimensionless radial position being a ratio (r/R) of r to R. 13. The method of mounting a vortex generator according to claim 12 , wherein the mounting step includes positioning the plurality of fin sets so that the angle θ satisfies an expression θ≤(0.0034/μ 2 )×(180/π) [°]. 14. The method of mounting a vortex generator according to claim 12 , wherein the mounting step includes positioning the plurality of fin sets so that the angle θ satisfies an expression θ≥(0.0021/μ 2 )×(180/π) [°]. 15. The method of mounting a vortex generator according to claim 11 , wherein the mounting step includes positioning the plurality of fin sets so that the angle θ increases