2. Methodology

The product development process for components made of LFT materials is characterized by a strong interdependency between structural design, material design and manufacturing process design. In theory, all parameters of the three domains have to be optimized simultaneously during product development. However, this is not yet possible today. Therefore, suitable models need to be developed. These models have to be able to represent the relevant parameters for the bead optimization to be investigated, while taking into account the residual stresses resulting from the manufacturing process. Due to the described interdependencies between design, material and manufacturing, it is indispensable to identify the relevant parameters of the respective domain and to simulate them for a reliable prediction of the stiffness. For this purpose, a simulation method has been developed that consists of a coupling of individual simulation models. The coupling diagram is shown in Figure 3. The advantage of coupling different models in one method is to overcome the isolated assessment of individual parameters and thus to be able to answer complex, cross-domain questions (Albers et al. Reference Albers, Spadinger, Serf, Reichert, Heldmaier, Schulz, Bursac, Schumacher, Vietor, Fiebig, Bletzinger and Maute2017). The reason for choosing commercial (simulation) software is their good availability and high robustness.

Figure 3. Coupling diagram for the optimization of manufacturing-based beads in fibre reinforced polymers considering residual stresses from the manufacturing process.

Starting with the first step of the workflow shown in Figure 3, the component to be beaded as well as the initial charge are generated in a CAD software, for example, Creo Parametric. The initial charge is the cut to shape and stacked semi-finished product. It has to be ensured that the volume of the initial charge is slightly higher than the component volume in order to avoid a short shot which means an underfilling of the mold. In the developed workflow, the height of the initial charge is adjusted automatically so that the volume of the initial charge is 105% of the final component. Afterwards, the manufacturing of the component by compression molding is simulated as a three-dimensional (3D) model in Moldflow with a defined number of element layers over the thickness. Within Moldflow, the Navier–Stokes equations for non-Newtonian viscosity are solved to determine the flow field. The 3D modelling allows the consideration of varying flow patterns over the thickness such as fountain flow, which is typical for thermoplastic polymers. The heated initial charge solidifies when in contact with the cold mold and thus, the flow velocity is zero at the surface and no slip occurs. At the inner region the velocity remains high and the material passes the solidified outer region.

For the calculation of the fibre orientations, there are different models which are developed for mold filling simulations. In the present work, the Anisotropic Rotary Diffusion – Reduced Strain Closure model model (ARD-RSC) is chosen. This orientation model, developed by Phelps & Tucker (Reference Phelps and Tucker2009), is particularly suitable for long fibres. However, as all one-phase approaches, this model can only calculate probabilities for the fibre orientation tensor and does not calculate the motion of each fibre itself. The calculation of the anisotropic material parameters resulting from the fibre orientation is performed using the micromechanics model of Mori & Tanaka (Reference Mori and Tanaka1973). In the work of Tucker III and Liang (Tucker & Liang Reference Tucker and Liang1999) different micromechanics models were compared and the Mori–Tanaka model was identified as the most suitable for fibre reinforced polymers. The calculation of local anisotropic material properties is performed in a two-step procedure (Eom & Veinbergs Reference Eom and Veinbergs2017). First, the fibres are assumed to be unidirectionally oriented, resulting in a transversely isotropic material. In the second step, the material properties are adapted to the simulated fibre orientation and local orthotropic material parameters are calculated. Five independent material parameters are required for this procedure: $ {E}_1 $, $ {E}_2 $, $ {\nu}_{12} $, $ {\nu}_{23} $ and $ {G}_{12} $.

When the simulation of the compression molding is completed, the fibre orientation tensors and the mechanical material properties are exported to provide them for the structural model in Abaqus (as shown in Figure 3). The fibre orientations are used to calculate the eigenvectors, which define the local coordinate systems for each element. Thus, each element has an individual orientation and individual mechanical properties. The MpCCI MapLib of Fraunhofer SCAI is used for the transfer. The Abaqus model consists of the same number of solid layers as chosen for the mold filling simulation. After mapping on the Abaqus solid model, the parameters are further transferred to a shell model (see Figure 4).

Figure 4. Two-stage mapping exemplary for three layers in thickness direction (Revfi, Spadinger, & Albers Reference Revfi, Spadinger and Albers2019).

This procedure is necessary because the tool used for the bead generation requires the description of the structural problem as a shell model. The external loads are applied on this shell model according to the load case to be investigated in order to derive the bead positions. To ensure that the calculated stress distribution corresponds to the load case, no residual stresses are used for the structural simulation of the component in this step.

Then, the stress results are transferred to the beading tool. The tool calculates the main bending stresses and the main bending stress directions for each element. The elements with the highest main bending stress values are potential trajectory starting points. Trajectories are generated along the highest bending stresses and their directions as long as they lie in a predefined design area (see Figure 5a). The trajectories are sorted in a list according to the bending stress value at the trajectory’s starting point. Each trajectory is a possible course of a bead. The beading tool allows a definition of course restrictions such as minimum bending radius and minimum length. Furthermore, a minimum distance between beads can be set. Beginning at the top of the trajectory list, the trajectories that fit the position constraints are added to the model and represent the centreline of the beads. Afterwards, the partition of the bead is created along the centrelines on the component (see Figure 5b). For a more accurate description of the bead geometry, the local element size has to be fine enough within the bead partition. The global element edge length can be chosen coarser. The only bead parameter that affects the partition and hence the mesh of the flat component is the bead width. A variation of the other bead parameters does not change the total number of elements. After meshing is complete, the nodes within the partition are moved perpendicular to the shell surface according to piecewise defined functions to create the beads (see Figure 5c). Based on this newly created beaded shell model, a solid mesh consisting of a defined number of element layers is created by a both-sided offset using the shell model as the midsurface.

Figure 5. (a) Design area (b) bead partitions and trajectories according to Revfi et al. (Reference Revfi, Spadinger and Albers2019) (c) schematic bead generation via perpendicular nodal displacement.

During the optimization process, several hundred beaded components are generated in this way. To generate different bead cross sections, the bead parameters (see Figure 2) are varied within a specified range. The upper limit of the flank angle and the lower limit of the radii depend on the mesh size. The perpendicular nodal displacement of the beading tool (see Figure 5c) can lead to a low number of elements in the flank, if the flank is designed too steep. This results in long stretched elements of poor quality. To avoid this, the maximum flank angle has to be chosen carefully. Every change in the geometry of the bead cross section leads to a change of the component volume. Since the initial charge of the original component cannot be used for the beaded components because of the volume difference, a corresponding initial charge is created for each bead geometry. To keep the volume of the initial charge at 105% of the final component, the initial charge’s height is automatically adjusted. All other parameters concerning the initial charge remain the same. For each generated bead geometry, the mold filling process and the following structural analysis are performed as previously described for the original component without beads, but this time residual stresses are considered.

In the present work, after mold filling, the component is cooled down to 25 °C (room temperature) and the in-cavity residual stresses are exported for this temperature. A thermo-viscoelastic model (see Eq. (1)), that describes the material behaviour under thermal and mechanical loads, allows the prediction of the in-mold stress distribution before ejection of the cooled component (Fan et al. Reference Fan, Yu, Zuo and Speight2017).

(1)$$ {\sigma}_{ij}(t)={\int}_0^t{C}_{ij rs}\left({\xi}_{(t)}-{\xi}_{\left(\tau \right)}\right)\left(\frac{{\partial \varepsilon}_{rs}}{\partial \tau }-{\alpha}_{rs}\frac{\partial T}{\partial \tau}\right) d\tau $$

$ {C}_{ijrs} $ is the viscoelastic relaxation modulus tensor. $ {\sigma}_{ij}(t) $ and $ {\varepsilon}_{ij}(t) $ are the stress and strain tensor, respectively, where t is the time. T is the temperature and $ {\alpha}_{ij} $ is the tensor of coefficients of thermal expansion. $ {\xi}_{(t)} $ is a pseudo-time scale defined as $ \xi (t)={\int}_0^t\frac{1}{a_T} d\tau $ with $ {a}_T $ as the time temperature shift factor.

As thermo-viscoelastic material characterization leads to complexities, Moldflow uses the following simplified thermo-viscous-elastic stress-strain relationship for orthotropic material with the mechanical properties calculated from the mold filling simulation (Fan et al. Reference Fan, Yu, Zuo and Speight2017).

(2)$$ \left[\begin{array}{c}\begin{array}{c}{\sigma}_{xx}\\ {}{\sigma}_{yy}\end{array}\\ {}{\sigma}_{xx}\\ {}\begin{array}{c}{\tau}_{xy}\\ {}{\tau}_{yz}\\ {}{\tau}_{zx}\end{array}\end{array}\right]=\left[\begin{array}{cccccc}\frac{1-{\nu}_{yz}{\nu}_{zy}}{E_y{E}_z\Delta }& \frac{\nu_{yx}+{\nu}_{zx}{\nu}_{yz}}{E_y{E}_z\Delta }& \frac{\nu_{zx}+{\nu}_{yx}{\nu}_{zy}}{E_y{E}_z\Delta }& 0& 0& 0\\ {}\frac{\nu_{xy}+{\nu}_{xz}{\nu}_{zx}}{E_z{E}_x\Delta }& \frac{1-{\nu}_{zx}{\nu}_{xz}}{E_z{E}_x\Delta }& \frac{\nu_{zy}+{\nu}_{zx}{\nu}_{xy}}{E_z{E}_x\Delta }& 0& 0& 0\\ {}\frac{\nu_{xy}+{\nu}_{xy}{\nu}_{yz}}{E_x{E}_y\Delta }& \frac{\nu_{zy}+{\nu}_{xz}{\nu}_{yz}}{E_x{E}_y\Delta }& \frac{1-{\nu}_{xy}{\nu}_{yz}}{E_x{E}_y\Delta }& 0& 0& 0\\ {}0& 0& 0& {G}_{xy}& 0& 0\\ {}0& 0& 0& 0& {G}_{yz}& 0\\ {}0& 0& 0& 0& 0& {G}_{zx}\end{array}\right]\left[\begin{array}{c}\begin{array}{c}{\varepsilon}_{xx}\\ {}{\varepsilon}_{yy}\end{array}\\ {}{\varepsilon}_{xx}\\ {}\begin{array}{c}{\gamma}_{xy}\\ {}{\gamma}_{yz}\\ {}{\gamma}_{zx}\end{array}\end{array}\right] $$

(3)$$ \Delta =\frac{1-{\nu}_{xy}{\nu}_{yx}-{\nu}_{yz}{\nu}_{zy}-{\nu}_{zx}{\nu}_{xz}-2{\nu}_{xy}{\nu}_{yz}{\nu}_{zx}}{E_x{E}_y{E}_z} $$

The residual stresses include pressure-dependent stresses after freezing and temperature-dependent stresses resulting from thermal shrinkage during the cooling process. This is described in Eq. (4) (Autodesk Help 2020).

(4)$$ \left\{{\sigma}_g\right\}=-\left[{D}_g\right]\left\{{\varepsilon}_{g0}\right\}+\left\{{\sigma}_{g0}\right\} $$

The index g refers to the global coordinate system. [D] is the stress–strain relationship matrix, [$ {\varepsilon}_{g0} $] is the initial strain from zero pressure state or transitional temperature to room temperature and $ {\sigma}_{g0} $ is the initial stress.

For the structural simulations in the present work, the in-cavity residual stresses are introduced into the Abaqus model by an initial condition which defines the local stress tensor for each element. In the first step of the structural simulation, warpage is calculated and in the second step, the external load is applied.

For the optimizations carried out in this work, a genetic algorithm is used that consecutively creates generations of individuals to determine the stiffness-optimized solution. Genetic algorithms are suitable for parallelization and allow a wide investigation of the solution space reducing the risk of converging at a local optimum which is not the global optimum. The design variables are the bead parameters: height, width, flank angle, head radius and base radius. The bead parameters of each individual are automatically checked before each optimization loop if they meet the requirements for a sufficient number of elements in every segment of the bead cross section. The first generation consists of eight individuals. Every following generation will be generated based on the previous generation. The current optimal solution is kept and recombined with the other individuals that pass the later presented strength constraint. The probability of a recombination of each parameter is 60%. All individuals that do not pass the strength constraint are replaced by a mutation, here that means a slight variation of two bead parameters, of the current optimum. If all individuals pass the constraint, the two worst solutions are replaced by mutations of the current optimum in order to explore the solution space efficiently while maintaining a population size of eight individuals. Due to the limitation of parallel executable simulations, the number of eight individuals per generation is relatively low, resulting in more optimization loops. For the comparison of bead parameter sets and the according bead cross sections, a fitness value is used as objective function which needs to be minimized to determine the parameter set resulting in the highest specific stiffness. To assess the stiffness of the component, the work of the external forces (ALLWK in Abaqus) is used as energy quantity. This has the advantage compared to the Strain Energy (ALLSE) value, which is often used in topology optimization, that the residual stresses generated by the manufacturing process are not considered in the stiffness evaluation. In addition, the component volume is integrated into the fitness function. This is due to lightweight design reasons: the optimization method results in a component with a lower mass if there are individuals showing the same stiffness. The stiffness of a component depends on the two factors, geometry and material. The geometric stiffness results from the second moment of area, whereas the material stiffness is defined by the Young’s modulus. Accordingly, for direction-independent, isotropic materials, the stiffness can only be affected by changing the second moment of area. For these kinds of materials, the optimization of the objective function results in the bead geometry with minimum radii, maximum height and width and largest possible flank angle (Revfi et al. Reference Revfi, Mikus, Behdinan and Albers2020). However, for anisotropic materials, it can happen that due to a different flow behaviour, the material stiffness partly compensates the geometric stiffness (Revfi et al. Reference Revfi, Mikus, Behdinan and Albers2020). As a result, it is possible that two different bead cross sections result in the same stiffness. Therefore, the fitness value is calculated as given in Eq. (5). The objective is to optimize stiffness but at the same time to include the volume so that the optimization results in a lightweight solution if two individuals show a similar stiffness. The definition of the fitness function can be easily adjusted to other optimization problems such as minimum weight with a required stiffness.

(5)$$ f=\frac{\mathrm{Volume}}{\mathrm{Work}} $$

Additionally, a strength constraint is implemented. Since the presented optimization methodology serves the purpose of an initial design proposal and more accurate strength investigations are carried out at a later phase of the product development process, a simple, conservative maximum stress criterion is used. The general definition for a plane stress state is given in Eq. (6).

(6)$$ 1\ge \max \left\{\frac{\sigma_1}{-{R}_{\parallel}^c},\frac{\sigma_1}{R_{\parallel}^t},\frac{\sigma_2}{-{R}_{\perp}^c},\frac{\sigma_2}{R_{\perp}^t},\left|\frac{\tau_{12}}{R_{\mathrm{shear}}}\right|\right\} $$

By replacing the longitudinal and transverse strengths by the smaller one, the formulation can be further simplified and only compressive strength, tensile strength and shear strength are necessary material parameters. In addition, the principal stresses are used for the strength criterion. With $ {\sigma}_I<{\sigma}_{II}<{\sigma}_{II I} $, the strength criterion for each element is given as in Eq. (7). Again, the definition of the constraint can be easily adjusted to other criterions.

(7)$$ 1\ge \max \left\{\frac{\sigma_I}{-{R}^c},\frac{\sigma_{III}}{R^t},\left|\frac{\sigma_{III}-{\sigma}_I}{2\times {R}_{\mathrm{shear}}}\right|\right\} $$

Based on the Eqs. (5) and (7) the optimization problem for this work can be mathematically formulated as shown in Eq. (8).

(8)$$ {\displaystyle \begin{array}{c}\min f\left(\overrightarrow{x}\right)\\ {}\mathrm{with}\;\overrightarrow{x}={\left[\mathrm{bead}\hskip0.17em \mathrm{height},\mathrm{bead}\hskip0.17em \mathrm{width},\mathrm{flank}\hskip0.17em \mathrm{angle},\mathrm{head}\hskip0.17em \mathrm{radius},\mathrm{base}\hskip0.17em \mathrm{radius}\right]}^T\\ {}\mathrm{so}\ \mathrm{that}\ \mathrm{for}\ \mathrm{each}\ \mathrm{element}\\ {}{\sigma}_I\left(\overrightarrow{x}\right)\hskip0.20em \ge -{R}^c\\ {}{\sigma}_{III}\left(\overrightarrow{x}\right)\hskip0.20em \le \hskip0.30em {R}^t\\ {}{\sigma}_{III}\left(\overrightarrow{x}\right)-\sigma \left(\overrightarrow{x}\right)\hskip0.20em \le\ \left|2\times {R}_{\mathrm{shear}}\right|\end{array}} $$