Development and verification of a cure-dependent visco-thermo-elastic simulation model for predicting the process-induced surface waviness of continuous fiber reinforced thermosets

Lorenz, Niklas; Gröger, B.; Müller-Pabel, Michael; Gerritzen, Johannes; Müller, Jonas; Wang, A.; Fischer, Kai; Gude, Μaik; Hopmann, Ch.

doi:10.1177/00219983221150046

Cited by 3 publications

(3 citation statements)

References 58 publications

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“…Due to this, the roughness before any post-processing treatment is of great concern, especially in the case of thermoset matrix composites manufactured via AM, due to amorphous polymerization. The roughness simulation for continuous GF and bisphenol photosensitive (Lorenz et al, 2022) [113]. The model was developed in TexGen software 3.13.1, with experimental material properties.…”

Section: Surface Roughness Simulationmentioning

confidence: 99%

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The Three-Dimensional Printing of Composites: A Review of the Finite Element/Finite Volume Modelling of the Process

Zach,

Dudescu

2024

J. Compos. Sci.

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Composite materials represent the evolution of material science and technology, maximizing the properties for high-end industry applications. The fields concerned include aerospace and defense, automotive, or naval industries. Additive manufacturing (AM) technologies are increasingly growing in market shares due to the elimination of shape barriers, a plethora of available materials, and the reduced costs. The AM technologies of composite materials combine the two growing trends in manufacturing, combining the advantages of both, with a specific enhancement being the elimination of the need for mold manufacturing for composites, or even post-curing treatments. The challenge of AM composites is to compete with their conventional counterparts. The aim of the current paper is to present the additive manufacturing process across different spectrums of finite element analyses (FEA). The first outcomes are building definition (support definition) and the optimization of deposition trajectories. In addition, the multi-physics of melting/solidification using computational fluid dynamics (CFD) are performed to predict the fiber orientation and extrusion profiles. The process modelling continues with the displacement/temperature distribution, which influences porosity, warping, and residual stresses that influence characteristics of the component. This leads to the tuning of the technological parameters, thus improving the manufacturing process.

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Section: Surface Roughness Simulationmentioning

confidence: 99%

“…polymerization. The roughness simulation for continuous GF and bisphenol photosensitive (Lorenz et al 2022) [113] The model was developed in TexGen software, with experimental material properties. The model was developed for two directions, with mean profiles and extremum values, as shown in Figure 56 .…”

Section: Surface Roughness Simulationmentioning

confidence: 99%

The Three-Dimensional Printing of Composites: A Review of the Finite Element/Finite Volume Modelling of the Process

Zach,

Dudescu

2024

J. Compos. Sci.

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“…Lorenz et al [17] suggested a method for the numerical prediction of surface waviness effects on glass fiber reinforced plastics (GFRP) in a resin transfer molding (RTM) process. They revealed that simulations and experiments agreed satisfactorily and observed surface waviness significantly influenced by the curing temperature rather than the analyzed neat resin layer thickness.…”

mentioning

confidence: 99%

Influence of tool pin profiles on waviness and natural frequency during friction stir welding of Al-Li alloys plates

Kumar

Soni

Katiyar

et al. 2023

Surf. Topogr.: Metrol. Prop.

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The third generation of Al-Li 2050-T84 alloy was primarily used in aerospace industries due to its exceptional potential for weight saving, high strength, and increased fatigue crack growth resistance. In the present research, three different types of tool pin profiles, namely, hybrid, taper threaded, and triangular, were used to join 2050-T84 Al-Li alloy by using Friction Stir Welding (FSW) at a constant rotational speed of 23.33 rotation/second with a traverse speed of 0.003 meters per second and tilt angle of 2°. The research explored the effect of different tools on weld bead structure, waviness and natural frequency of welded plates. The experimental results show that the hybrid tool pin side generates 10.9% higher heat than the threaded taper tool and 25.8% higher than the triangular tool. Moreover, the hybrid tool produces 50.1% lower waviness of welded specimens than the threaded taper tool and 55.7% lower than the triangular tool at the nugget zone (NZ). The research established that a hybrid tool pin profile is advantageous as it generates a higher frequency and lower acceleration under the applied load in friction stir welded specimens.

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Surface waviness of continuous fiber-reinforced thermosets – Experimental and numerical studies considering the viscoelasticity of the resin

Lorenz,

Hennes,

Fischer

et al. 2024

Composites Part A: Applied Science and Manufacturing

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Development and verification of a cure-dependent visco-thermo-elastic simulation model for predicting the process-induced surface waviness of continuous fiber reinforced thermosets

Cited by 3 publications

References 58 publications

The Three-Dimensional Printing of Composites: A Review of the Finite Element/Finite Volume Modelling of the Process

The Three-Dimensional Printing of Composites: A Review of the Finite Element/Finite Volume Modelling of the Process

Influence of tool pin profiles on waviness and natural frequency during friction stir welding of Al-Li alloys plates

Surface waviness of continuous fiber-reinforced thermosets – Experimental and numerical studies considering the viscoelasticity of the resin

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