Sage Journals: Discover world-class research

Abstract

This study investigates the curing deformation and drilling effects in composite hat-shaped stiffened panels, which are widely used in aerospace structures for their high strength-to-weight ratio. A numerical path-dependent constitutive model was developed to simulate the curing process, demolding, and drilling operations using ABAQUS, with experimental validation conducted via laser scanning on a full-scale AS4/8552 composite panel (radius: 3000 mm, length: 2000 mm). The results show that the curing deformation exhibits a distinct “X” shape, with a maximum out-of-plane deformation of 2.48 mm in the center and downward edges. Secondary drilling significantly reduced the curing deformation through residual stress relief, whereas pre-reserved holes markedly increased deformation due to stress concentration and reduced stiffness, as confirmed by both experimental and simulation results. Furthermore, an optimal hole size of 300 × 200 mm (3% of panel area) minimized deformation, while larger holes (e.g. 700 × 600 mm) led to a 49.5% reduction in buckling load and increased distortion. These findings provide quantitative guidance for optimizing manufacturing processes to balance stress release and structural integrity in composite stiffened panels.

Keywords

hat-shaped stiffened panels curing deformation drilling effects ABAQUS composite manufacturing

Get full access to this article

View all access options for this article.

References

Ozturk

Cobanoglu

Ece

RE.

Recent advancements in thermoplastic composite materials in aerospace industry. J Thermoplastic Compos Mater 2024; 37(9): 3084–3116.

Liu

Cai

Zhou

, et al. Tensile properties and failure mechanism of 3D woven hollow integrated sandwich composites. Appl Compos Mater 2017; 24(5): 1151–1163.

Liu

Zhang

Chen

, et al. Research on the automatic modeling and performance prediction of plain-woven composites based on beam elements. J Strain Anal Eng Des 2024; 59(3): 207–217.

Liu

Zhang

Chen

, et al. Beam element method for mechanical analysis of 2.5D woven composite: modeling strategy and finite element method simulation J Reinforced Plast Compos 2024; 43(5-6): 339–353.

Tuli

Khatun

Rashid

AB.

Unlocking the future of precision manufacturing: a comprehensive exploration of 3D printing with fiber-reinforced composites in aerospace, automotive, medical, and consumer industries. Heliyon 2024; 10(5): e27328.

Wang

Chen

Wang

, et al. Analysis and experimental evaluation framework for buckling and post-buckling of composite stiffened panels. J Compos Mater 2025; 59(1): 99–117.

Xiao

Sha

, et al. Experimental and numerical studies on compressive failure behaviors of stepped-scarf repaired composite stiffened panels. Eng Fail Anal 2024; 163: 108458.

Han

Dong

Buckling analysis for carbon and glass fibre reinforced hybrid composite stiffened panels. J Compos Sci 2024; 8(1): 34.

Albayrak

Experimental and numerical investigation of patch effect on the bending behavior for hat-shaped carbon fiber composite beams. Mater Test 2024; 66(4): 584–597.

10.

Cai

, et al. Effect of impact position on the mechanical response and viscoelastic behavior of double-blade composite stiffened structures. Polym Compos 2024; 45(16): 14916–14930.

11.

Xiao

Qian

, et al. An experimental and numerical study of curing deformation considering tool-part interaction for two-step curing tooling composite materials. J Manuf Process 2023; 94: 435–453.

12.

Ding

Wang

, et al. Prediction of process-induced distortions in L-shaped composite profiles using path-dependent constitutive law. Appl Compos Mater 2016; 23(5): 1027–1045.

13.

Ding

Wang

, et al. A three-dimensional thermo-viscoelastic analysis of process-induced residual stress in composite laminates. Compos Struct 2015; 129: 60–69.

14.

Svanberg

Altkvist

Nyman

Prediction of shape distortions for a curved composite C-spar. J Reinforced Plast Compos 2005; 24(3): 323–339.

15.

Bellini

Sorrentino

Analysis of cure induced deformation of CFRP U-shaped laminates. Compos Struct 2018; 197: 1–9.

16.

Ding

Bao

, et al. Analysis of curing deformation for resin matrix composite T-shaped stiffened panel. J Reinforced Plast Compos 2024; 0(0): 07316844241272959.

17.

Zhao

Wang

Liu

, et al. Study of integral hat-stiffened composite structures manufactured by automated fiber placement and co-curing process. Compos Struct 2020; 246: 112427.

18.

Yuan

Wei

Kong

, et al. Simulation method for curing deformation of composite part considering tool–part interaction. Arab J Sci Eng 2024; 49(9): 12483–12492.

19.

Tang

Hui

, et al. Multi-objective optimization of curing profile for autoclave processed composites: simultaneous control of curing time and process-induced defects. Polymers 2022; 14(14): 2815.

20.

Xie

Zhou

, et al. Mechanism of curing behavior for CFRP compression molding under thermo-mechanical-chemical multi-field coupling. Mater 2022; 27(3): e20220108.

21.

Kim

Lee

Evaluation of curing process-induced deformation in plain woven composite structures based on cure kinetics considering various fabric parameters. Compos Struct 2022; 287: 115379.

22.

Fan

Zhang

Wang

, et al. A deep learning method for fast predicting curing process-induced deformation of aeronautical composite structures. Compos Sci Technol 2023; 232: 109844.

23.

Kim

Choi

Kweon

JH.

Manufacture and performance evaluation of the composite hat-stiffened panel. Compos Struct 2010; 92(9): 2276–2284.

24.

Ding

Numerical and theoretical study on process-induced distortions in thermoset composites. Wuhan University of Technology, 2016.

25.

Camanho

Matthews

FL.

A progressive damage model for mechanically fastened joints in composite laminates. J Compos Mater 1999; 33(24): 2248–2280.

Investigation of curing deformation and drilling effects in composite hat-shaped stiffened panels: Experimental and numerical analysis

Abstract

Keywords

Get full access to this article

References