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Abstract

The fiber patch placement (FPP) technology enables the automated manufacturing of complex-shaped components. However, placement defects such as bridging and wrinkling may occur during the deposition of patches onto the tool surface, which are typically unacceptable in high-performance applications. To analyze and prevent such defects, this study investigated the patch placement process using finite element (FE) simulations. Various obstacle geometries were designed to deliberately induce wrinkling, and these scenarios were subsequently simulated. Furthermore, simulations and experimental placements were carried out on an aerospace demonstrator. The simulation results were validated using 3D scan data, and typical placement defects were successfully replicated in the numerical model. The maximum deviation between scanned and simulated patches was 4.49 mm, corresponding to only 3% of the patch’s short edge length. This confirms the suitability of the approach for capturing key defect mechanisms. The placement behavior of the FPP technology has not yet been investigated using simulations validated with 3D scan data. The findings contribute to a deeper understanding of defect formation mechanisms—particularly wrinkling and bridging—under defined placement conditions. This work provides a foundation for predictive process optimization and the development of defect-preventing placement strategies for complex geometries.

Keywords

Fiber patch placement FPP automated composite production foam gripper gripper simulation

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References

Yassin

Hojjati

. Processing of thermoplastic matrix composites through automated fiber placement and tape laying methods. J Thermoplast Compos Mater 2018; 31: 1676–1725.

Carosella

Hügle

Helber

, et al. A short review on recent advances in automated fiber placement and filament winding technologies. Compos B Eng 2024; 287: 111843.

Brasington

Sacco

Halbritter

, et al. Automated fiber placement: a review of history, current technologies, and future paths forward. Composites Part C: Open Access 2021; 6: 100182.

Lukaszewicz

DH-J

Ward

Potter

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

Heinecke

Willberg

. Manufacturing-induced imperfections in composite parts manufactured via automated fiber placement. J Compos Sci 2019; 3: 56.

Oromiehie

Prusty

Compston

, et al. Automated fibre placement based composite structures: review on the defects, impacts and inspections techniques. Compos Struct 2019; 224: 110987.

Yousefi

Mosavi Mashhadi

Safarabadi

. Numerical analysis of cracked aluminum plate repaired with multi-scale reinforcement composite patches. J Compos Mater 2020; 54: 4341–4357.

Hosseini

Safarabadi

Ganjiani

, et al. Experimental and numerical fatigue life study of cracked AL plates reinforced by glass/epoxy composite patches in different stress ratios. Mech Base Des Struct Mach 2021; 49: 894–910.

Mirmohammad

Safarabadi

Karimpour

, et al. Study of composite fiber reinforcement of cracked thin-walled pressure vessels utilizing multi-scaling technique based on extended finite element method. Strength Mater 2018; 50: 925–936.

10.

Majic

Weidinger

Drechsler

. Experimental and simulation study on the performance of fiber patch placement. 17th European Conference on Composite Materials (ECCM 2016), Munich.

11.

Wolf

. Grippers in motion: the fascination of automated handling tasks. Munich, Cincinnati: Hanser Publishers, 2018.

12.

Wang

Zhang

. A design of bionic soft gripper for automatic fabric grasping in apparel manufacturing. Textil Res J 2023; 93: 1587–1601.

13.

Takahashi

Nagato

Suzuki

, et al. Flexible vacuum gripper with autonomous switchable valves. 2013 IEEE International Conference on Robotics and Automation. Karlsruhe, Germany, 2013, pp. 364–369 IEEE.

14.

Shintake

Cacucciolo

Floreano

, et al. Soft robotic grippers. Adv Mater 2018; 30.

15.

Papadopoulos

Andronas

Kampourakis

, et al. On deformable object handling: multi-tool end-effector for robotized manipulation and layup of fabrics and composites. Int J Adv Manuf Technol 2023; 128: 1675–1687.

16.

Kordi

Husing

Corves

. Development of a multifunctional robot end-effector system for automated manufacture of textile preforms. 2007 IEEE/ASME international conference on advanced intelligent mechatronics. Zurich, Switzerland, 2007, pp. 1–6 IEEE.

17.

Choi

Lee

, et al. A vision-guided adaptive and optimized robotic fabric gripping system for garment manufacturing automation. Robot Comput Integrated Manuf 2025; 92: 102874.

18.

Dutta

Körber

Frommel

. Automated fixation of dry carbon fibre fabrics with RTM6 for autonomous draping and sensor-aided preforming. Proced CIRP 2019; 85: 329–334.

19.

Löchte

Kunz

Schnurr

, et al. Form-flexible handling and joining technology (FormHand) for the forming and assembly of limp materials. Proced CIRP 2014; 23: 206–211.

20.

Kunz

Löchte

Dietrich

, et al. Novel form-flexible handling and joining tool for automated preforming. Sci Eng Compos Mater 2015; 22: 199–213.

21.

Atalay

Ozturk

. Effects of gripper location and blank geometry on the thermoforming of a carbon-fiber woven-fabric/polyphenylene sulfide composite sheet. J Thermoplast Compos Mater 2023; 36: 2737–2756.

22.

Zhang

Chi

. Discrete path planning of carbon fiber patch placement with complex surface. Textil Res J 2023; 93: 4010–4022.

23.

Ogden

. Non-linear elastic deformations. Chichester: Horwood, 1984.

24.

Cruz Gómez

Gallardo-Hernández

Vite Torres

, et al. Rubber steel friction in contaminated contacts. Wear 2013; 302: 1421–1425.

Process FEM simulation of fiber patch placement laminates with a flexible foam-based gripper

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