Resin flow - A263

Modeling Resin Flow[edit | edit source]

Modeling the flow within a composite structure is a complex process, influenced by various factors including the materials used in the layup stack, the chemical properties of the resin being infused, and the design of the tooling and process. These factors can vary significantly depending on the scale of analysis. Composite flow is typically evaluated at three distinct scales: microscale, mesoscale, and macroscale. Each scale considers different aspects of the flow dynamics, as illustrated in Figure below.

Three (3) scales for evaluation of flow - depicted from ^[1]

The macroscale is often the simplest and quickest model to consider, as it examines the flow through the entire laminate stack. At this scale, flow properties can be averaged across the stack, providing a broad overview. At the mesoscale, the focus shifts to the individual plies and their architecture. Factors such as tow size, weave type, ply compaction, and other physical properties are taken into account to develop a more detailed flow model. Mesoscale modeling is more complex and demands greater computational power than macroscale modeling. The microscale, on the other hand, is used to analyze resin flow around individual fibers within the tows and their interactions with neighboring fibers. This level of modeling is the most intricate and computationally intensive, typically used for small, localized areas to assess specific material properties, rather than for evaluating the flow across the overall part geometry.

Effect of Ply Drape on Flow Modelling[edit | edit source]

The geometry of the plies within a composite part has a significant effect on the flow behavior. Key characteristics of the reinforcing material, such as tow size, weave type (if applicable), yarn compaction, fiber type, and yarn angle, all impact the flow dynamics. Part geometries can cause deformation of the plies during mold placement, which may alter flow characteristics. For simple parts or cases where precise flow results are less critical, these effects can be overlooked. However, when employing more detailed modeling techniques, particularly at the mesoscale and microscale, it is essential to account for the draping effects, as they can significantly affect resin flow and material consolidation.

Darcy’s Law[edit | edit source]

As the resin flows from the inlet(s) towards regions under lower pressure, the resin velocity decreases according to Darcy's law. Darcy’s law governs flow through porous medium\[Q = -\frac{KA}{\mu}\frac{\Delta P}{x}\]

Where,

\(Q = \) Volumetric flow rate

\(K = \) Preform permeability

\(A = \) Preform cross-sectional area

\(\mu = \) Resin viscosity

\(\Delta P = \) Pressure differential across preform

\(x = \) In-plane flow distance of pressure differential

The time taken for resin to flow a certain distance from the inlet can be derived from Darcy's law. Please see How to assess the resin filling time in LCM processes for more detail. When manufacturing large components, multiple resin inlets and vacuum outlets at different locations are typically used. The inlets and outlets can be controlled to open either simultaneously or sequentially. In practice, it is common to open and close the inlets and outlets to manipulate flow fronts in order to fully impregnate the preform. The sequence however, is largely empirically and can even vary from part to part.

Numerical Simulation[edit | edit source]

Resin flow is typically modeled using generalized forms of the Navier-Stokes equations and Darcy’s law. To simplify the modeling process, many flow models assume uniform properties across the ply stack, neglecting through-thickness effects ^[2]. Several strategies have been explored over time to develop accurate flow simulation models. The two most commonly used methods are variations of the Control Volume / Finite Element (CVFE) method and the Volume-of-Fluid (VOF) method ^[3][4]. These approaches offer distinct advantages in simulating resin flow through composite structures, each suited to different aspects of the process.

Control Volume / Finite Element Flow Simulation Method[edit | edit source]

The Control Volume Finite Element (CVFE) method is widely used due to its efficiency and accuracy across various scenarios. This approach, however, does not account for the presence of air within the laminate stack. It works by solving a series of small, steady-state flow problems sequentially.

In the CVFE method, the area is subdivided into distinct elements and nodes, with each node corresponding to its own control volume. The pressure gradient between the inlet and the advancing flow front is calculated using Darcy's law, alongside the mass continuity equation for incompressible Newtonian fluids. From this pressure gradient, a velocity field for the flow front is derived, allowing for the determination of the time required to fill the next element at each location. The first element to be fully filled dictates the next time step increment. The remaining cells are partially filled according to the results, and a new flow front is established. An example of this process is illustrated in Figure 18. This cycle is repeated for each successive flow front until the entire control volume is completely filled.

Flow advancement in the CVFE method - depicted from ^[1]

The CVFE is an efficient method for determining flow progression though can be very time consuming for solutions with a large number of control volumes.

Volume-of-Fluid Methods[edit | edit source]

The Volume of Fluid (VOF) method is particularly well-suited for simulating flows involving two or more immiscible fluid phases that cannot coexist in the same space ^[5]. In the context of resin flow modeling, the two phases typically considered are the resin and the air within the system. The domain is divided into discrete control volumes, where the volume fraction of all phases sums to one, and a set of equations is applied to describe the behavior of each phase.

This method is very effective at modelling flow progression and is able to account for open channels and other areas that the CVFE is unable to solve for. The success of VOF methods is highly dependent on the establishment of appropriate mesh and time discretization; otherwise the solutions may not converge.

Other Considerations[edit | edit source]

Several additional factors can impact the accuracy of flow simulations and must be carefully considered. Variability in the properties of reinforcement materials, arising from differences in handling and cutting of the plies, can significantly affect flow behavior. Factors such as wrinkles, ply distortion, and variations in material properties can alter flow paths, potentially leading to race-tracking. If not properly controlled, race-tracking can cause significant deviations in flow behavior. To address this, probabilistic methods have been developed to account for such variability in flow models.

Design considerations can further complicate the modeling process. Many composite designs include multiple vacuum ports, which are closed off as the resin reaches them. Additionally, flow media may be applied only in specific areas of the part, with the optimal placement of these media typically determined through infusion trials. These trials, while effective, are time-consuming and resource-intensive. To streamline this process, various studies have explored methods to improve flow control modeling. One such approach involves using centroidal Voronoi diagrams, which have been shown to significantly reduce the number of iterations required to determine optimal placement. However, introducing these complexities into the simulation model should be carefully evaluated, as doing so can significantly increase the computational complexity and make the system more challenging to solve.

The methods discussed so far primarily focus on in-plane flow properties within a laminate, assuming a rigid tool structure. These assumptions are generally valid for thin laminates, where the in-plane flow dominates. However, as laminate thickness increases, through-thickness properties and tool compaction effects become more influential in the resin flow process. Tool compaction is especially critical when using flexible tools that may deform under pressure changes during the infusion process, impacting the final flow behavior.