Wind turbines are of 2 main types, horizontal-axis and vertical-axis wind turbines [HAWT and VAWT]. Sufficient engineering examples and international standards are unavailable for guiding stackable-VAWT (SVAWT) design. Therefore, in accordance with relevant IEC-61400 standards, a clamping apparatus was developed to test composite blades in test platforms, and engineering software CAD/CAE was used to support the design and experimental stages. Using CAD/CAE also shortened the design cycle effectively and made simulation analysis more reliable. Moreover, the failure modes and test results of SVAWT blades under distinct manufacturing conditions were examined to verify the proposed experimental setup and manufacturing techniques. Static and fatigue tests were performed on SVAWT blades to understand the structural strength of the blades and identify the blades that could withstand maximal pressure and the failure mode in static experiments. Thus, the stress concentration was improved to avoid fatigue failure establishing that the blades can withstand the maximal wind speed listed as an acceptance criterion. This study establishes that the fatigue-life equation developed using the fatigue theory can predict the life of SVAWT blades effectively. Information on technology developed here can be provided on request.