SBIR-STTR Award

Thin-ply prepregs offer significant improvements in weight reduction, stiffness and overall mechanical properties over traditional composite laminates. Thin plies (<0.05 mm/layer) suppress or delay crack initiation in loaded composite structures thereby allowing for manufacturing of lighter, stiffer and more durable composite products. Recent thin-ply prepreg materials, consisting of toughened epoxy, cyanate ester and bismaleimide (BMI) resins, have been developed specifically for out-of-autoclave (OOA) manufacturing that answers the growing need of aerospace, space and other industries for processing large composite structures at reduced costs. Touchstone Research Laboratory, Ltd, proposes to manufacture a self-heated composite tool for thin-ply prepreg OOA processing. A high in-plane heat spreader material will be utilized to reduce temperature gradients on the tool surface thus improving cure heat rates and temperature uniformity, which are critical for long span and large surface area composite structures. Touchstone and Clemson University propose to manufacture thin ply composites from unidirectional prepreg tapes for breadboard testing in Phase I and prototype testing in Phase II. Areal weights of the thin ply composites are targeted to be less than 60 g/m². OOA processing of thin ply prepregs potentially eliminate expensive autoclaves and ovens impracticable for manufacturing large structures. Potential NASA Applications (Limit 1500 characters, approximately 150 words) NASA has interest in thin-ply technology for large structures such as deployable booms for solar sails, solar arrays, and communication antennas. Prepreg-based OOA methods are critical for processing next generation heavy launch vehicles. Given the component size and low production volumes, OOA processes are key to keeping costs low. Recent success in developing OOA carbon fiber/BMI prepreg shows that it is possible to achieve satisfactory results for the application. Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words) The general approach and specific technologies developed in this STTR can also be applied to other commercial applications such as Airbus A340 & A380 fixed wing leading edges, keel beam ribs, and Boeing 787 pressure bulkheads. Other military Aerospace and Wind applications that demand high stiffness are also potential candidates.

Touchstone produced carbon foam (CFOAM), graphite foam (GFOAM) composite core tool materials for evaluating heat transfer characteristics. In addition a high in-plane heat spreader was evaluated along with fiber reinforced bismaleimide (BMI) composite that is the tool surface. The heat source were 300 and 600 W flexible heaters manufactured from glass reinforced silicone and polyimide. The thermal results were collected and submitted to Clemson University and used for validating a 2D model that they developed. After completing the flat panel test a graphite core having DCB geometry was constructed and evaluated for thermal gradients. It was concluded that future development work would be on a tool having GFOAM core and BMI composite surface. The technology readiness level for Phase I started at TRL-1 and ended at TRL-5 based upon a BMI-GFOAM system and that has bottom mount heaters. It is proposed in Phase II to build a segmented 12ft span DCB self-heating composite tool prototype that may be used to validate the technology and provide thin ply composite booms with corrugated geometry in support of NASA LaRC thin-ply composites research. Potential NASA Applications (Limit 1500 characters, approximately 150 words) NASA has expressed interest in improving materials and processes. The intent of this technology development is to provide NASA with a more adaptable, or logistically favorable, process for curing large composite structures. A composite tool that can heat cure large composite structures without autoclave pressure and large ovens is a potential game changer for onsite production needs. The proposed Touchstone self-heating composite tool technology is modular, thus allowing for disassembly, storage, and transportation. Potential Non-NASA Applications (Limit 1500 characters, approximately 150 words) The general approach and specific technologies developed in this STTR can also be applied to other commercial applications such as Airbus A340 & A380 fixed wing leading edges, keel beam ribs, and Boeing 787 pressure bulkheads. Other military Aerospace and Wind applications that demand high stiffness are also potential candidates.