Introduction
AniForm, an advanced simulation tool that predicts the formability of composite laminates, is collaborating with Moldex3D to offer their users a higher-level RTM analysis. AniForm Engineering is a Dutch-based simulation technology company founded in 2011, which originally spun off the University of Twente. Today, AniForm is recognized and used by many entities worldwide, particularly in the aerospace industry.
Nowadays, the composite industry has access to a wide variety of process simulation software, each having its own specialization. Engineers can benefit even more from these predictive tools when their results are coupled. Moldex3D and AniForm collaborated the last few months to deliver their first interface, such that their users are able to perform more accurate infusion analyses as of today.
“We are delighted to cooperate with AniForm, which is undoubtedly a remarkable player in our industry,” said Dannick Teng, Managing Director at Moldex3D, “This is the first step of Moldex3D and AniForm’s exciting collaboration, and we are both looking forward to further integration very soon”.
This long-awaited collaboration will allow users to run superior simulations of RTM – which is particularly relevant for the wind power and aeronautic sector – by coupling AniForm’s fabric orientation simulation capabilities with Moldex3D’s RTM simulation. Users can now smoothly import the fiber reorientation data (recorded as an ASCII file) from AniForm Suite and run the RTM simulation with Moldex3D’s powerful simulation tools.
“AniForm strives to deliver a software tool that enables engineers to focus on the analysis of a prediction, rather than spending too much time on modelling and data transfer between various simulation tools. Moldex3D is a renowned partner in the industry, so we were thrilled to cooperate with them. We were very happy with this collaborative effort, which led to a seamless interface between our tools.” Said Sebastiaan Haanappel, Managing Director at AniForm.
Challenges
- Lack of a seamless workflow between the different simulation tools;
- The fiber orientations in a fabric change significantly during forming;
- Fabric shear and fiber reorientation affects locally the magnitude and orientation of the fabric’s permeability property.
Solutions
Coupling between Moldex3D RTM simulation and AniForm forming results.
Benefits
- Make data interfacing easier and improve the workflow for the design engineers
- Improve input accuracy for the RTM model
- Increase the accuracy of the RTM simulation result
Case Study
The main objective of this case study is to compare the different results between two models; one that directly assigns an assumed orthogonal fabric orientation, and one that considers the fabric orientation result from an AniForm forming prediction, in order to see how different input can have a significant impact on the resin infusion simulation results.
In the context of this case study, AniForm’s team generated a simulation of a woven fabric forming that we have used as an input in Moldex3D software for the fabric orientation. The fabric simulation was exported as an ASCII file from AniForm and smoothly imported in Moldex3D to run the RTM simulation.
For this case study, a laminate consisting of five fabric layers with a [(0/90)]5 layup is formed into a mold cavity that represents the final part shape. Subsequently, the mold itself is heated and injected with resin. The part is eventually released after curing. We refer to the final part as the Formed Woven Fabric.
To take into consideration the forming induced fabric distortions in a subsequent infusion simulation in Moldex3D, a composite forming simulation in AniForm was performed. Figure 3 shows the predicted laminate deformations at various instances during the forming. These deformations lead to the resulting in-plane shear distribution and related fiber re-orientation at complete mold closure in the final step as shown in Figure 4.
As addressed above, two infusions models were created in Moldex3D. Fig. 5 shows the two configurations of the infusion models. The first model assumes the fabric still to be orthogonal, namely 0- and 90-degree in every part (light blue: 0-degree, dark blue: 90-degree). However, in reality, an orthogonal fiber orientation shall not be present since the forming leads to in-plane fabric deformation and the fabric orientation is not 0- and 90-degree in every part anymore. Therefore, the second model considers the forming results from AniForm, and uses the forming induced fiber-reorientation. The fiber reorientation will affect the permeability, which is a measure to describe the ability of a fluid to flow through the fabric. For this reason, an effect on the flow progression is to be expected, which for the second model would result in a more accurate representation of reality.