CompositesWorld
Issue link: https://cw.epubxp.com/i/891910
NOVEMBER 2017 8 CompositesWorld DESIGN & TESTING » Have you ever looked outside an airplane window during in-flight turbulence and wondered how strong the wings really are and how much load they can take? Don't worry, they can take at least 10 times the worst turbulence you can imagine! We know that, because in the aerospace industry, what we call traceability of materials information plays a critical role in ensuring materials auditability and, thus, their eventual qualification for safe use. Traceability, in short, is the ability to track the trail of data generated during product development, so that one can "follow the bread crumbs" to prove the performance of, and do quality assurance verifications for, manufactured products. e trace- ability trail, however, might be long and very detailed. For example, to qualify a composite material, one must ensure that it meets a variety of requirements, such as strength. Many tests must be performed. Test data must be captured and linked to informa- tion about the final material and product. is link, and access to the test information, is critical so that anyone, at any point, can prove what tests were done, and then inspect the test results. You may be thinking that ensuring this level of traceability is only important for aerospace parts, but that isn't the case. Trace- ability is an increasingly important issue in the automotive industry, among energy producers and for materials suppliers as well. e ability to understand the context of your materials, and inspect those materials at any time, plays a pivotal role for audit- ability of design data and protection of intellectual property (IP). Auditability becomes particularly important when multimil- lion-dollar decisions need to be made based on high confidence in the material properties, or when OEMs require the full proof and history that confirms that the materials meet specifications. Or when material properties are being used in simulations that ultimately will drive design decisions. Regulatory risk. Another concern associated with traceability is the need to comply with regulations, such as the European Union's Registration, Evaluation, Authorization and Restriction of Chemicals (REACH), and the US Environmental Protection Agency's (EPA) Toxic Substances Control Act (TSCA) Chemical Substance Inventory. Today, those who manufacture products that contain restricted substances, whether they are hazardous to humans, the environment or both, face potentially costly recalls, loss of consumer confidence, huge fines and even imprisonment. Traceability of materials and the substances they contain plays a crucial role in reducing that risk. It is possible to ensure that, during product development, a compliance report can be gener- ated on both existing and new products to ensure they comply with all regulations. Complex composites. Although, traceability is important and applicable to all materials, composite materials introduce a unique challenge to its application. ey are far more complex than conventional materials, such as metals. Made up of multiple Tackling the traceability of composite materials materials, reinforcements and matrices — each with its own behavior and properties — the composite system's final properties depend on the material combination's process history, the layup, fiber orientations and part geometry. All this complexity makes it more challenging to track data, ensure its traceability and under- stand the effect the various input parameters will have on the final composite's behavior. Maintaining traceability. So how do you do it for complex composite materials? First, the necessary information must be acquired within the manufacturing organization and without, from its suppliers. Unfortunately, suppliers and even internal depart- ments often do not supply all the necessary information and underlying raw data, either for reasons of intellectual property (IP) protection or because that information does not exist. It is critical, therefore, to demand minimum information gathering. FIG. 1 A schematic of the composites data schema developed by Granta Design, in collaboration with the members of the MDMC. Source | Granta Design FIG. 2 Software tools import, analyze and manage the data to enable engineers to search, browse and apply it. For example, a material's full "history" is shown in this example datasheet. Source | Granta Design