Litcius/Paper detail

From aviation to automotive - a study on material selection and its implication on cost and weight efficient structural composite and sandwich designs

Mathilda Karlsson Hagnell, S. Kumaraswamy, Tonny Nyman, Malin Åkermo

2020Heliyon71 citationsDOIOpen Access PDF

Abstract

The design of a composite material structure is often challenging as it is driven by the trade-off between lightweight performance and production costs. In this paper, the boundaries of this design trade-off and its implications on material selection, geometrical design and manufacturability are analysed for a number of design strategies and composite material systems. The analysis is founded on a methodology that couples weight-optimization and technical cost modelling through an application-bound design cost. Each design strategy is evaluated for three levels of bending and torsional stiffness. The resulting stiffness-versus cost-range together constructs the design envelope and provides guidelines on the suitability and improvement potential of each case. Design strategies researched include monolithic, u-beam-, sandwich-insert- and sandwich-stiffened plates. Considered material systems include carbon-, glass, recycled carbon-, lignin- and hemp-fibre reinforced composites. Optimized sandwich designs are shown to have lowest design cost. Glass-, recycled carbon-, lignin- and hemp-fibre reinforced composite materials are all shown to reduce costs but at lower stiffness performance. Ultimately, the case study demonstrates the importance of early structural design trade-off studies and material selection and justifies introducing novel fibre systems in low-cost applications of moderate stiffness levels.

Topics & Concepts

Automotive industryComposite numberAviationSelection (genetic algorithm)Material selectionEngineeringAeronauticsManufacturing engineeringForensic engineeringComposite materialComputer scienceMaterials scienceAerospace engineeringArtificial intelligenceAdditive Manufacturing and 3D Printing TechnologiesNatural Fiber Reinforced CompositesMechanical Engineering and Vibrations Research