Waviness and fiber volume content analysis in continuous carbon fiber reinforced plastics made by tailored fiber placement

Abstract In this paper, the influence of Tailored Fiber Placement (TFP) processing-related parameters on in-plane waviness and fiber volume content of unidirectional carbon fiber reinforced plastic (UD-CFRP) composites is experimentally investigated. Twelve UD-CFRP laminates, whose preforms are produced via TFP, are manufactured by considering different values of stitch width, stitch distance and stitch sequence as well as two different stitching yarn types by resin transfer molding (RTM). The investigated TFP parameters are representative of the producing capability of a typical TFP machine. Based on calibrated high-resolution photographic images and manual recognition of the roving orientation on the laminate surface, the in-plane waviness is qualitatively and quantitatively measured using Fourier analysis. With this approach, the dominant waviness, in-plane wavelengths, and amplitudes of different stitching parameters can be evaluated. Both mean fiber volume content within the roving and within the TFP layer are determined through optical micrographs of the produced laminates. Experimental results reveal that the resulting waviness and the fiber volume content in the roving and within the TFP layer strongly dependent on TFP process parameters. In particular, the stitch width plays a major role on both fiber volume contents, whereas the stitch distance is less relevant.

[1]  Paul M. Weaver,et al.  Optimal Design of Postbuckling Behaviour of Laminated Composite Plates using Lamination Parameters , 2014 .

[2]  Paul M. Weaver,et al.  Framework for the Buckling Optimization of Variable-Angle Tow Composite Plates , 2015 .

[3]  Marco Montemurro,et al.  On the effective integration of manufacturability constraints within the multi-scale methodology for designing variable angle-tow laminates , 2017 .

[4]  Richard Degenhardt,et al.  Tailored Fibre Placement Technology – Optimisation and computation of CFRP structures , 2007 .

[5]  G. Heinrich,et al.  Development of a Highly Stressed Bladed Rotor Made of a CFRP Using the Tailored Fiber Placement Technology , 2013, Mechanics of Composite Materials.

[6]  G. Heinrich,et al.  Using tailored fibre placement technology for stress adapted design of composite structures , 2008 .

[7]  Marco Montemurro,et al.  A new paradigm for the optimum design of variable angle tow laminates , 2016 .

[8]  K. Gliesche,et al.  Application of the tailored fibre placement (TFP) process for a local reinforcement on an “open-hole” tension plate from carbon/epoxy laminates , 2003 .

[9]  José Humberto S. Almeida,et al.  Optimizing Variable-Axial Fiber-Reinforced Composite Laminates: The Direct Fiber Path Optimization Concept , 2019, Mathematical Problems in Engineering.

[10]  Axel Spickenheuer Zur fertigungsgerechten Auslegung von Faser-Kunststoff-Verbundbauteilen für den extremen Leichtbau auf Basis des variabelaxialen Fadenablageverfahrens Tailored Fiber Placement , 2013 .

[11]  Marco Montemurro,et al.  A general B-Spline surfaces theoretical framework for optimisation of variable angle-tow laminates , 2019, Composite Structures.

[12]  Simon Astwood,et al.  A review on design for manufacture of variable stiffness composite laminates , 2016 .

[13]  Richard Degenhardt,et al.  Tailored fibre placement optimization tool , 2006 .

[14]  Paul Mattheij,et al.  Tailored Fiber Placement-Mechanical Properties and Applications , 1998 .

[15]  K Hazra,et al.  Experimental fabrication and characterization of out-of-plane fiber waviness in continuous fiber-reinforced composites , 2012 .

[16]  Sudip Dey,et al.  Meso-scaled finite element analysis of fiber reinforced plastics made by Tailored Fiber Placement , 2016 .