Wind turbine blade with noise reducing micro boundary layer energizers

The invention claimed is: 1. A wind turbine blade assembly, the blade assembly comprising: a rotor blade having exterior surfaces defining a pressure side, a suction side, a leading edge and a trailing edge, the pressure side, the suction side, the leading edge and the trailing edge extending between a blade tip and a blade root, the rotor blade defining a span and a chord; and a plurality of micro boundary layer energizers comprising at least one of vanes, grooves, dents, dimples, wall segments and wheeler-type vortex generators positioned on a surface of the pressure side of the rotor blade in an outboard area of the rotor between 0%-50% of a spanwise dimension measured from the blade tip, exclusive of an inboard portion of the blade, downstream a distance from a stagnation region, and upstream of a separation bubble when present, to affect pressure side flow in a normal operating range, the plurality of micro boundary layer energizers extending one of above or below a neutral plane of the rotor blade, wherein x/c is the ratio of a distance of an upstream most point of each of the micro boundary layer energizers from the leading edge along a chord axis “x” to a total length “c” of the chord and wherein x/c is between ˜20-55% for each micro boundary layer energizer of the plurality of micro boundary layer energizers, and wherein the pressure side of the rotor blade is exclusive of additional micro boundary layer energizers positioned downstream from an onset of the separation bubble, and wherein the plurality of micro boundary layer energizers are shaped and positioned chordwise to add longitudinal vortices oriented chordwise and delay separation of a boundary layer on the pressure side at a low angle of attack. 2. The wind turbine blade assembly as claimed in claim 1 , wherein the longitudinal vortices increase a vertical momentum exchange in the boundary layer. 3. The wind turbine blade assembly as claimed in claim 1 , wherein the plurality of micro boundary layer energizers are positioned upstream of a turbulent boundary layer separation. 4. The wind turbine blade assembly as claimed in claim 1 , wherein the plurality of micro boundary layer energizers are positioned downstream of a point of minimum pressure (C P -min). 5. The wind turbine blade assembly as claimed in claim 1 , wherein the plurality of micro boundary layer energizers are positioned upstream of a point of minimum pressure (C P -min). 6. The wind turbine blade assembly as claimed in claim 1 , wherein each of the plurality of micro boundary layer energizers is wedge-shaped, defining a wind face, a plurality of side faces and a slip joint and, wherein the wind face and the plurality of side faces meet downstream at an apex. 7. The wind turbine blade assembly as claimed in claim 1 , wherein each of the plurality of micro boundary layer energizers defines a wedge ramp having an apex height “h” above the neutral plane and a length “L” along the neutral plane, wherein a ratio of h to L is between 1:5 to 1:20, wherein δ is equal to a thickness of the boundary layer, determined at an AoA (angle of attack)/condition when a turbulent separation bubble SB has begun to form, and wherein a relative height h/δ(delta) is between 0.2 and 0.7. 8. The wind turbine blade assembly as claimed in claim 1 , wherein the plurality of micro boundary layer energizers are spaced in a spanwise direction, having a spacing “S” between adjacent energizers in a range of approximately 8-20 times a height “h” of the plurality of micro boundary layer energizers. 9. The wind turbine blade assembly as claimed in claim 1 , wherein a spanwise spacing between adjacent micro boundary layer energizers of the plurality of micro boundary layer energizers is between 300 mm measured from a downstream most point of each of the adjacent micro boundary layer energizers. 10. The wind turbine blade assembly as claimed in claim 1 , wherein a height “h” of each of the plurality of micro boundary layer energizers extends between 1-15 mm above the neutral plane of the rotor blade. 11. The wind turbine blade assembly as claimed in claim 1 , wherein each of the plurality of micro boundary layer energizers includes a plurality of vane-type components configured as one of a co-rotating micro-boundary layer energizer or a counter-rotating micro boundary layer energizer. 12. The wind turbine blade assembly as claimed in claim 1 , wherein each of the plurality of micro boundary layer energizers is a wheeler-type micro boundary layer energizer configured as, a wishbone-shaped micro boundary layer energizer or a doublet-shaped micro boundary layer energizer. 13. The wind turbine blade assembly as claimed in claim 1 , wherein the plurality of micro boundary layer energizers are static and fixed relative to the rotor blade surface at an operational position extending one of above or below the neutral plane of the rotor blade. 14. The wind turbine blade assembly as claimed in claim 1 , wherein the plurality of micro boundary layer energizers are dynamic and actuated from a retracted position to an operational position extending above the neutral plane of the rotor blade. 15. A wind turbine, the wind turbine comprising a plurality of rotor blade assemblies, at least one of the plurality of rotor blade assemblies comprising: a rotor blade comprising a suction side surface and a pressure side surface, and defining a span and a chord; a plurality of micro boundary layer energizers comprising at least one of vanes, grooves, dents, dimples, wall segments and wheeler-type vortex generators formed on the pressure side surface in an outboard area of the rotor between 0%-50% of a spanwise dimension measured from the blade tip, exclusive to an inboard portion of the blade, downstream a distance from a stagnation region, and upstream of a separation bubble when present, to affect pressure side flow in a normal operating range, the plurality of micro boundary layer energizers extending one of above or below a neutral plane of the rotor blade in an operational position of the plurality of micro boundary layer energizers, wherein x/c is the ratio of a distance of an upstream most point of each of the micro boundary layer energizers from the leading edge along a chord axis “x” to a total length “c” of the chord and wherein x/c is between ˜20-55% for each micro boundary layer energizer, and wherein the pressure side of the rotor blade is exclusive of additional micro boundary layer energizers positioned downstream from an onset of the separation bubble, and wherein the plurality of micro boundary layer energizers are shaped and positioned to add chordwise oriented longitudinal vortices into a boundary layer to increase vertical momentum exchange in the boundary layer and delay separation of the boundary layer at a low angle of attack. 16. The wind turbine as claimed in claim 15 , wherein the plurality of micro boundary layer energizers are positioned downstream of a point of minimum pressure (C P -min). 17. The wind turbine as claimed in claim 15 , wherein the plurality of micro boundary layer energizers comprise wedge-shaped elements extending one of above or below a neutral plane of the rotor blade and wherein an apex of each of the wedge-shaped elements is directed toward a trailing edge of the rotor blade. 18. The wind turbine as claimed in claim 15 , wherein the plurality of micro boundary layer energizers are one of, dynamic and actuated from a retracted position to the operational extending above the neutral plane of the pressure side of the rotor blade, and static, fixedl