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Abstract

Application of automated fiber placement is limited by defects formed in the prepreg tows during the layup process. An extensive experimental study is performed to investigate the effect of compaction roller on the quality of the layup. Five different compaction rollers with different stiffness and architectures were manufactured and employed to dispense prepreg tows at various process conditions. Layup quality was examined and different defects including tow buckling and blister were identified. In addition to automated fiber placement trials, static testing and finite element simulations were performed to probe the pressure distribution and contact width of each roller. This data was used to support and understand the results of the automated fiber placement trials. Results indicate the solid elastomer rollers that are compliant enough to produce the same level of contact width under similar levels of compaction forces are superior to the perforated rollers in terms of achievable layup quality.

Keywords

Automated fiber placement layup defects tow compaction roller

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References

Dirk

H-J

Ward

Potter

KD.

The engineering aspects of automated prepreg layup: history, present and future. Compos Part B 2012; 43: 997–1009.

Ahn

Seferis

Pelton

, et al. Analysis and characterization of prepreg tack. Polym Compos 1992; 13: 197–206.

Crossley

Schubel

Warrior

The experimental determination of prepreg tack and dynamic stiffness. Compos Part A 2012; 43: 423–434.

Endruweit

Choong

Ghose

, et al. Characterisation of tack for uni-directional prepreg tape employing a continuous application-and-peel test method. Compos Part A 2018; 114: 295–306.

Budelmann

Detampel

Schmidt

, et al. Interaction of process parameters and material properties with regard to prepreg tack in automated lay-up and draping processes. Compos Part A 2019; 117: 308–316.

Nagelsmith

Guerrits

Influence of steering radius on the mechanical properties of fiber placed composite laminates. In: ICCS17-17th international conference on composite structures, Porto, Portugal, 17–21 June 2013.

Gurdal

Tatting

Tow-placement technology and fabrication issues for laminated composite structures. In: 46th AIAA/ASME/ASCE/AHS/ASC structures, structural dynamics and materials conference, Austin, Texas, 18–21 April 2005.

Hallett

Wisnom

MR.

Modelling the effect of gaps and overlaps in automated fibre placement (AFP)-manufactured laminates. Sci Eng Compos Mater 2015; 22: 115–129.

Falcó

Lopes

Naya

, et al. Modelling and simulation of tow-drop effects arising from the manufacturing of steered-fibre composites. Compos Part A 2017; 93: 59–71.

10.

Beakou

Cano

Le Cam

, et al. Modelling slit tape buckling during automated prepreg manufacturing: a local approach. Compos Struct 2011; 93: 2628–2635.

11.

Matveev

Schubel

Long

, et al. Understanding the buckling behaviour of steered tows in automated dry fibre placement (ADFP). Compos Part A 2016; 90: 451–456.

12.

Belhaj

Hojjati

Wrinkle formation during steering in automated fiber placement: modeling and experimental verification. J Reinf Plast Compos 2018; 37: 396–409.

13.

Bakhshi

Hojjati

Time-dependent wrinkle formation during tow steering in automated fiber placement. Compos Part B 2019; 165: 586–593.

14.

Bakhshi

Hojjati

An experimental and simulative study on the defects appeared during tow steering in automated fiber placement. Compos Part A 2018; 113: 122–131.

15.

Materials CE. CYCOM 977-2, Product data sheet. 2012.

16.

Mischler

Tingley

Hoffmann

Compaction roller for a fiber placement machine 7810539B2 USA, 2010.

17.

Joyce

Boyce

Durometer hardness and the stress–strain behavior of elastomeric materials. Rubber Chem Technol 2003; 76: 419–435.

Effect of compaction roller on layup quality and defects formation in automated fiber placement

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References