SBIR-STTR Award

Accurate knowledge of the aerodynamic loading associated with stores leaving cargo/weapons bays on military aircraft is critical in ensuring reliable safe-separation. Wind tunnel testing is a valuable design tool that allows for the prediction of the trajectory of small stores during separation. However, due to the small size of the wind tunnel models, extremely small balance systems are needed to resolve the forces and moments acting on the stores. Unfortunately, current balance systems are not available at the scale required to fit inside such a small test article. Ahmic Aerospace and our assembled team propose an innovative new approach to small balance technology. Semiconductor gages will be used for their favorable robustness, large signal output, and extremely small size compared to traditional transducer methods. In Phase I, a small-scale four-component balance system will be designed, manufactured, and instrumented as a test platform for the semiconductor measurement technology. Acceptance testing, NIST calibrations, laboratory demonstrations, and supersonic wind tunnel tests will be conducted to demonstrate the feasibility of the semiconductor gages, establish measurement accuracy, and guide future program efforts. Lastly, a small-scale six-component balance system capable of meeting all SBIR requirements will be designed and simulated in preparation for Phase II.

The primary objective of the SBIR research program is to develop small balance technologies having the capability to accurately measure forces and moments on extremely small weapon store systems. The small size of the balance disqualifies the use of traditional metal-foil strain gages due to manufacturing size and resolution limitations. Ahmic's proposed innovative approach is focused on the successful implementation and demonstration of advanced semiconductor gages. In Phase II, a custom semiconductor strain gage will be designed and manufactured specifically for small balance applications. The gage will improve upon the performance and accuracy of commercially available semiconductor and foil strain gages. Advanced FEA and topology optimization techniques will be implemented to guide the balance design process. Over the program, two iterations of six-component balance will be designed, manufactured, instrumented, and calibrated. The balances will undergo an extensive experimental campaign in relevant subsonic and supersonic flow environments including a large-scale facility. Test data will be validated with other balance results and companion flow simulations. The balance will be shown to meet all SBIR performance standards. The program will conclude with a commercial six-component balance, calibration report, and support documentation being delivered to AEDC.