This invention relates generally to blade structure and more particularly to blade structures that offer stiffness and structural strength, and to uses of such blades. Such blades are particularly suitable for (but are not limited to use in) wind turbine configurations.
Contemporary blades are made from fiberglass/epoxy composite material using monolithic, un-stiffened geometry. As a result, blades have thick, heavy, skins. If substantial care is not taken in processing, thick section laminates can be subject to porosity and delamination problems.
One aspect of the present invention therefore provides a blade for a rotor. The blade has integral stiffeners with at least one of unidirectional caps configured to carry blade bending loads in axial tension or webs to carry transverse shear resulting from blade bending.
In another aspect, the present invention provides a wind turbine having a generator, a hub, and at least one blade having integral stiffeners. The integral stiffeners include at least one of unidirectional caps configured to carry blade bending loads in axial tension or webs to carry transverse shear resulting from blade bending.
It will be seen that many configurations of the present invention can reduce blade weight at tops of towers while giving the designer several ways to adjust the strength and stiffness of blades to achieve improved structural performance.
In some configurations of the present invention, integrally stiffened skin construction is used to replace prior art monolithic skin construction for wind turbine blades. Blade stiffness and structural strength are improved by geometry changes that are compatible with laminated composite material processing/fabrication. Improved structural efficiency results in reduced blade weight and material usage. When these blade configurations are used on wind turbines, a lighter weight hub results as does a lower tower weight at the top of the tower, both of which reduce structural requirements for the tower. Also provided in some configurations is a more robust, damage tolerant, attachment coupling for joining the blade to a hub.
Thus, and referring to
In some configurations and referring to
Also in some configurations, blade 10 includes stiffeners 14 and also a cap 16. In some of these configurations, stiffener 14 height, cap 16 thickness, and/or cap 16 material is/are selected to provide a predetermined strength, stiffness, or both. Cap 16 material can be a material selected from high, medium, or low modulus carbon/epoxy. Unidirectional carbon/epoxy caps 16 in some configurations are provided configured to carry blade bending loads in axial tension, and balsa wood webs 18 are provided in some configurations to carry transverse shear resulting from blade 10 bending. For example, and referring to
Blade 10 configurations of the present invention are not limited to particular applications. By way of example only, however, and referring again to
It will thus be appreciated that many configurations of the present invention reduce blade weight, and are particularly useful in reducing blade weight in wind turbines at tops of towers. Many configurations of the present invention also give designers a plurality of ways to adjust the strength and stiffness of blades to achieve improved structural performance.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.