Abstract
Purpose
Finite element (FE) analysis can be used for both design and verification of components. In the case of 3D-printed materials, a proper characterization of properties, accounting for anisotropy and raster angles, can help develop efficient material models. This study aims to use compression tests to characterize short carbon-reinforced PA12 made by fused filament fabrication (FFF) and to model its behaviour by the FE method.
Design/methodology/approach
In this work, the authors focus on compression tests, using post-processed specimens to overcome external defects introduced by the FFF process. The material’s elastoplastic mechanical behaviour is modelled by an elastic stiffness matrix, Hill’s anisotropic yield criterion and Voce’s isotropic hardening law, considering the stacking sequence of raster angles. A FE analysis is conducted to reproduce the material’s compressive behaviour through the LS-DYNA software.
Findings
The proposed model can capture stress values at different deformation levels and peculiar aspects of deformed shapes until the onset of damage mechanisms. Deformation and damage mechanisms are strictly correlated to orientation and raster angle.
Originality/value
The paper aims to contribute to the understanding of 3D-printed material’s behaviour through compression tests on bulk 3D-printed material. The methodology proposed, enriched with an anisotropic damage criterion, could be effectively used for design and verification purposes in the field of 3D-printed components through FE analysis.
Keywords
Citation
Bandinelli, F., Scapin, M. and Peroni, L. (2024), "Effects of anisotropy and infill pattern on compression properties of 3D printed CFRP: mechanical analysis and elasto-plastic finite element modelling", Rapid Prototyping Journal, Vol. 30 No. 11, pp. 142-158. https://doi.org/10.1108/RPJ-11-2023-0385
Publisher
:Emerald Publishing Limited
Copyright © 2024, Francesco Bandinelli, Martina Scapin and Lorenzo Peroni.
License
Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial & non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode
1. Introduction
Short fibre-reinforced polymer composites represent an interesting class of materials, combining the lightweight and ductility properties of the polymeric matrix with the high load-bearing capability of several types of fibres (Tekinalp et al., 2014; Ning et al., 2015; Zhang et al., 2018; Khan et al., 2021). One of the most used additive manufacturing techniques is fused filament fabrication (FFF) (Turner et al., 2014; Turner et al., 2014; Bikas et al., 2016; Wickramasinghe et al., 2020), where the component is built layer by layer through the direct deposition of fused material through a heated nozzle. Despite its popularity, there is still much work needed to fully understand the mechanical behaviour of FFF components, and the characterization of printed materials is an ongoing process (Zhao et al., 2019; Yao et al., 2020; Fang et al., 2021; Scapin and Peroni, 2021; Zouaoui et al., 2021; Athale et al., 2022; Bandinelli et al., 2023).
The building strategy of the FFF process introduces peculiar aspects of the printed material, among which mechanical anisotropy is the most relevant. The printing process is based on the deposition of fused material on a printing bed, where the nozzle moves combining translations along X and Y directions (as shown in Figure 1), and the vertical growth of the component is assured by the bed motion along the Z direction, which creates the characteristic layers. The poor adhesion between different layers and different rasters makes the material inhomogeneous, creating weak interfaces and voids that play a fundamental role in defining the mechanical behaviour of the whole structure (Zhang et al., 2018; Sood et al., 2009; Fallon et al., 2019; Birosz et al., 2022). As already observed in many past works (Ziemian et al., 2012; Garg and Bhattacharya, 2016; Dudescu and Racz, 2017; Gonabadi et al., 2020; Calignano et al., 2020), the weakest direction in terms of tensile properties is the growth direction of the print (Z direction), because of poor adhesion. The lateral interface between rasters is also a critical aspect of the material’s integrity; in fact, the newly fused material is deposited in a later stage with respect to the previously deposited one, with a time delay that depends on the printing speed and strategy (Sun, 2008; Sood et al., 2012; Samy et al., 2022). Material adhesion depends on many printing parameters as well as material properties such as viscosity and wettability. In the case of fibre-reinforced materials, the bonding between two distinct portions of material is particularly critical because of the presence of fibres in the matrix that enhance discontinuity and increase the viscosity (Zhang et al., 2018; Fallon et al., 2019). Many authors focused on the characterization of tensile properties with particular attention to the effects of material orientation and raster angle, observing a relevant influence of both parameters on the material’s anisotropy (Zhao et al., 2019; Yao et al., 2020; Zouauoi et al., 2021; Bandinelli et al., 2023; Dudescu and Racz, 2017; Gonabadi et al., 2020; Guessasma et al., 2016; Kannan et al., 2020; Zeybek et al., 2023). Generally, tensile testing is the most used material characterization method to find the elastic modulus, yield and ultimate tensile strengths. Especially in the case of anisotropic materials, tensile tests could be insufficient to fully understand the mechanical behaviour, as different deformation and failure modes could be involved depending on the nature of the load applied. With the aim of complete material characterization, compression tests on bulk FFF materials should be considered along with tensile ones, but only some works focus on this type of testing to obtain the material’s properties (Athale et al., 2022; Sood et al., 2012; Guessasma et al., 2016; Zeybek et al., 2023; Song et al., 2017; Tabacu and Ducu, 2020; Corvi et al., 2023; Peng et al., 2022). Athale et al. (2022) focused on the characterization of PA12 with short carbon fibres, observing a neat difference between tensile and compression properties. Zeybek et al. (2023) focused on PA6 with short carbon fibres, obtaining a dependency of compression properties on the strain rate of deformation. Among previous works, to the best of the authors’ knowledge, only a few use compression properties of FFF materials to represent their compressive behaviour using finite element (FE) models (Athale et al., 2022; Guessasma et al., 2016; Song et al., 2017; Tabacu and Ducu, 2020; Corvi et al., 2023). The present work has the objective of characterizing and modelling the compressive behaviour of an FFF-printed composite material, made of a polyamide matrix (PA12) and reinforced with short carbon fibres, using compression tests on cubic specimens built with different orientations in space and different stacking sequences of raster angles. Compression tests are used to evaluate both elastic and plastic properties, and obtained data are subsequently used to define a material model that describes the elastic regime, the transition between the elastic and the plastic regime and, finally, the evolution in the plastic regime, before the onset of damage mechanisms. Plastic deformation mechanisms are fundamental for a complete understanding of 3D-printed polymers’ behaviour, especially when dealing with the design of components, failure analysis and design of manufacturing processes (Bandinelli et al., 2024). Hence, the present work is particularly focused on the plastic behaviour of 3D-printed materials and a possible strategy for its modelling. The final scope of this work is demonstrating the possibility of using FE calculation methods as design and verification tools for this special class of materials. The present work adopts a commercial FE software named LS-DYNA (Livermore Software Technology Corporation (LSTC), 2012), as well as a correlated optimization software named LS-OPT (Stander et al., 2019).
2. Materials and methods
The material analysed in the present work is Nylforce Carbon produced by FiberForce (Treviso, Italy) composed of a nylon matrix (PA12) reinforced with short carbon fibres (20% Wt.) and characterized by significant mechanical properties, low density (1 g/cm3) and resistance to high temperatures (long term at 90°C–120°C and short term at 150°C). Previous work by the authors on the same material showed a strong anisotropic nature in tensile conditions. Specimens printed with a ±45° raster angle with a 0° orientation with respect to the printing bed exhibited an ultimate tensile load of 35 MPa, whereas specimens with a 90° orientation with respect to the printing bed exhibited a much lower 16 MPa (Bandinelli et al., 2023).
For the present work, specimens are printed with a cubic shape, with a final side dimension of 10 mm. The slicer software used for the specimen’s preparation is Cura Slicer (version 5.2.1). The printer used is the Ultimaker S5 (Ultimaker B.V., Utrecht, NL) with a 0.4 mm Olsson ruby nozzle (3DVerkstan, Stockholm, Sweden). The filament used is produced by FiberForce with a diameter of 2.85 mm. The printing parameters are adjusted to have the optimal results in terms of geometrical accuracy, raster bonding and layer adhesion. In this sense, the printing temperature is set to 270°C, the printing chamber is enclosed and heated through an electrical resistance and a fan to maintain a temperature of 80°C, material’s flow rate is raised to 120% of its default value and the printing speed is set to 40 mm/s while layer height is set to 0.2 mm. These changes enhance raster bonding and layer adhesion, as the material has a longer cooling time, promoting better chemical and physical adherence between material deposited in different moments of the print. Longer cooling time promotes the crystallization of the polymeric matrix, increasing mechanical performances (Calignano et al., 2020; Ferreira et al., 2020; Yu et al., 2023). Furthermore, higher chamber temperatures promote low cooling rates and low-temperature gradients, limiting the warping of the final parts and the formation of voids (Wang et al., 2007; Yu et al., 2020).
As already stated in Ferrell et al. (2021); Ginoux et al. (2023); Phillips et al (2022); Sola et al. (2023), FFF material characterization is particularly difficult when dealing with the repeatability of results, because of numerous influences of different printing parameters on the final component. Furthermore, the absence of a standardized testing procedure results in obtaining different mechanical properties between various research works on the same material, highlighting the need for standardization, especially from the specimen fabrication point of view. Up to date, ASTM D695 and ASTM D1621 can be used for compression tests on plastics, although they are not intended for 3D-printed materials they provide few indications to deal with anisotropic materials. It is of fundamental importance to describe the procedure followed for the realization of test specimens, because each parameter plays a role in the result, and the FFF process involves many parameters to be controlled (Samy et al., 2022; Phillips et al., 2022; Chacón et al., 2017).
In the present work, the experimental campaign conducted to study the mechanical behaviour of the material and to find its properties is divided into two phases: the first phase is aimed to assess the repeatability of the results and observe the influence of raster angle on the compression properties of the material; the second one is instead aimed to extend the mechanical behaviour analysis to the dependence of the material’s compression properties from its orientation with respect to the load. In the latter phase, the work is focused on two stacking sequences of raster angles only: the most anisotropic (0° raster angle configuration) and the most isotropic configurations (135° raster angle configuration), based on the paths of raster deposition. This is intended to highlight differences in the behaviour of the same material. Specimens used in the present work do not follow the standards for plastic compression testing but are designed to analyse multiple manufacturing and loading cases.
2.1 Specimens tested along the main material’s directions
For the first phase of the experimental campaign, specimens are realized to be tested as printed, aligning the loading directions with the main directions X, Y and Z of the printing reference system, as shown in Figure 1. Four different raster angles are analysed: the 0° configuration (in which rasters are aligned with the Y direction), the ±45° configuration, the 0°/90° configuration and, finally, the 0°/45°/90°/135° configuration. These specimens were printed in four batches consisting of 24 cubes (a total of 8 repetitions for each combination of loading direction and raster angle) to conduct a statistical analysis of the mechanical properties to evaluate the repeatability of the printing process and testing procedure. Specimens were characterized by a slight curvature of the face in contact with the build plate, showing the effects of shrinkage and warping as observed in past works (Tekinalp et al., 2014; Samy et al., 2022; Wang et al., 2007; Ferrell et al., 2021; Cattenone et al., 2019; Trofimov et al., 2022).
2.2 Specimens printed with various orientations between loading and material directions
For the second phase of the experimental campaign, inclined specimens are printed to investigate the effects of material orientation and anisotropy.
These specimens are realized by progressive rotations of the previous cubic samples along each of the material’s main directions X, Y and Z. They are printed with the help of printing supports (made by the same material). The rotation angles considered are 15°, 30°, 45°, 60° and 75°, to have a progressive transition from one main material’s direction to the other as shown in Figure 2 (Ning et al., 2015), where the latter represent the endpoints of the inclined series. Specimens rotated along one axis represent the transition between the remaining two.
Figure 3 shows the orientation procedure of specimens printed with progressive inclination around the y-axis, observable in Figure 2 as the top left row of specimens. Continuous lines represent the material’s layers while small arrows show the direction of the compressive load so that relative orientation between the material’s directions and load direction (ζ) is visible.
Printing supports are a critical feature of 3D printing, in fact, they inevitably introduce a defective surface in the finished component as can be observed in Figure 4, especially for low angles such as in the case of 15° inclined specimens (or equivalently 75°), where the spacing of layers’ profiles is more evident (Buj-Corral et al., 2019). Printing on inclined supports inevitably suffers from the stair-step effect (Reddy et al., 2018). This phenomenon is typical of the FFF process and leads to rasters being deposited on non-planar faces, with the result of rough and inaccurate surfaces. Furthermore, specimens Z15 and Z75 presented defective surfaces because of rasters’ angle with respect to the external faces, which caused prominent ridges (right image in Figure 4).
Considering the possible influence of the phenomena just discussed, the authors focused on a new specimen realization procedure to obtain more consistent results. Supports were replaced by bulk material, and the specimen’s dimensions were augmented to 12 mm to allow post-print milling (Figure 5).
The final shape of the specimens is identical to the previously described one, having the same dimensions (side dimension of 10 mm). This procedure allows to obtain more reliable results.
2.3 Testing procedure and equipment
The test methodology involves compression tests on the cubic specimens, which are subjected to a compression load at a constant engineering strain rate of 0.01 s−1 until the reach of at least 50% of engineering strain, to obtain material behaviour at elevated levels of deformation. Mechanical testing is conducted with the electromechanical testing machine Zwick100 (ZwickRoell GmbH & Co. KG, Ulm, Denmark) with a 100 kN load cell. The experimental setup is completed by two PixeLINK PL-B777 cameras with 5MP resolution and equipped with a 1/2.5” sensor (PixeLINK, Ottawa, Canada) and a Tokina Macro 100 F2.8D camera lens (Kenko Tokina Co. Ltd, Tokyo, Japan). The anisotropic nature of the material analysed requires the observation of two different faces of the cubic specimens, to capture the deformation behaviour in the two directions perpendicular to that of the application of the load. Video recording was conducted through the waveform generator Lecroy WaveStation 2012 (Teledyne Lecroy, Chestnut Ridge, NY, USA), to impose an image-capturing frequency of 4 Hz. Subsequent video analysis was conducted using Tracker software (tracker.physlets.org).
3. Experimental results
The results of the compression tests are analysed evaluating stress and strain in the different printing configurations and observing the effect of both raster angle and build orientation. Data from mechanical tests are elaborated to find the mechanical properties of the material. The elastic phase is used for the evaluation of elastic modulus in the testing direction ζ (Figure 3). The next phase is the deviation of 0.2% of strain from the proportionality, which in the present work is considered as the elastic limit of the material. The transition between elastic and plastic phases is different from specimen to specimen, showing dependence on material orientation and raster angle.
3.1 Experimental results of as-printed specimens
Compression tests conducted on the as-printed specimens described in Section 2.1 show a clear effect of raster angle on the mechanical properties of the material. In Table 1 elastic moduli are reported (with standard deviations in brackets):
Results of the compression tests on these specimens show some peculiarities that lead to the conclusion that their mechanical properties are strongly influenced by printing supports (Turner et al., 2014). The results emphasize the negative impact of printing supports on elastic moduli, observed by comparing inclined specimens with those tested in the main material directions. Especially looking at the specimens between Z and X directions (from Y15 to Y75), the trend of inclined specimens is significantly lower than expected, which can be explained by the presence of printing supports (Figure 6), as they introduce a defected surface that is relatively extended with respect to the specimen’s dimensions (Figure 4). Irregularities of the external surfaces induce higher deformation in earlier stages of compression, thus lowering the elastic modulus. The graphs also show that specimens inclined by 15° and 75° to the main directions are remarkably out of trend with respect to the others, especially X15, Y15 and Y75 specimens.
The 0° raster angle configuration shows the highest anisotropy, with the Y direction (coinciding with that of the deposition of the rasters) being the stiffest. This result is expected as fibres are mainly aligned with the deposition direction, so the material exhibits its maximum mechanical resistance (Tekinalp et al., 2014; Heller et al., 2016; Mulholland et al., 2018; Tessarin et al., 2022). X and Z directions of the 0° raster angle configuration show remarkably similar behaviour, with an almost identical elastic modulus. The other raster angle configurations substantially show analogous results, with material directions having perfectly comparable elastic moduli despite having different raster angles. This is because these three configurations introduce a theoretical symmetry between the X and Y directions. Compression loading in the latter configurations encounters the same orientations of rasters (and fibres) (namely, 0°, 45°, 90° and 135°) and should give comparable outputs in terms of mechanical properties. However, the experimental evidence shows a systematic difference between the X and Y directions, with X being the stiffer. This could be found in the warpage of the portion of the cube that is in contact with the building plate as specimens report curved bottom faces. The curvature is observed to be around the x-axis, so when load is applied in the Y direction the stiffness experienced is lower due to a pre-deformed configuration. Stacking sequences as +45°/−45° and 0°/90° are more subjected to warping because of higher residual stresses induced by the printing strategy, which has been shown to affect the cooling phase (Samy et al., 2022; Wang et al., 2007; Trofimov et al., 2022). The results of these tests demonstrate that the specimens (as printed) are not completely adequate and should be post-processed to avoid the effects of warping.
3.2 Experimental results of post-processed specimens
For as the post-processed specimens are concerned, only the 0° and the 0°/45°/90°/135° configurations were tested. The authors decided to focus on these two stacking sequences to analyse the most anisotropic and the most isotropic configurations, respectively. Observing the elastic moduli obtained for the 0° raster angle configuration, it is evident that the deposition direction Y has the highest elastic modulus, due to the alignment of the load direction with that of the rasters, followed by X and Z directions that are almost comparable. This is because of the fibres’ alignment during the extrusion phase (Heller et al., 2016; Mulholland et al., 2018; Love et al., 2014). For as the elastic limit is concerned, the 0° raster angle configuration shows an analogous trend, in fact, the Y direction results in the highest value, while the Z and X directions show lower and similar values. Experimental values of the material’s properties in the 0° configuration are reported in Table 2 (with standard deviation in brackets).
Where the elastic moduli Exx, Eyy, Ezz and yield values Yxx, Yyy, Yzz are identified using compression tests along the three main material’s directions (X, Y and Z), whereas νxy, νxz, and νyz Poisson’s ratios are derived from video analysis of transversal deformation.
The second configuration analysed has the following stacking sequence of raster angles: 0°/45°/90°/135° so that each layer is rotated by 45° with respect to the previous one. This printing strategy generates, as expected, an almost isotropic result in the printing plane (XY) in terms of elastic moduli and elastic limits, as rasters have four alternated deposition directions (Yao et al., 2020; Dong et al., 2017; Retolaza et al., 2021). X and Y directions are stiffer than the Z direction, and the anisotropy is less noticeable with respect to the 0° configuration. Specimens tested along the main material’s direction appear to behave very similarly and show analogous deformation (and failure) mechanisms: they deform almost equally along the two transverse directions (as confirmed by Poisson’s ratios values) and show crack openings while being compressed. For as the elastic limit is concerned, the 0°/45°/90°/135° raster angle configuration shows remarkably similar yield values in the three main directions X, Y and Z. Experimental values of the material’s properties in the 0°/45°/90°/135° configuration are reported in Table 3 (with standard deviation in brackets).
Observing the material’s properties in the two different stacking sequences it is obvious to notice the effect of the raster angle on the final printed material. This single parameter changes the distribution of the material’s stiffness in its directions, affecting its anisotropy. This suggests that raster angle is a fundamental choice for design purposes and should be selected with regard to the final application in a similar fashion as in laminate composites, where fibre orientation plays a crucial role.
4. Modelling methodology
The printing process is accurately represented by a reference system based on three axes: X, Y and Z (as shown in Figure 1) (Paul, 2021). The modelling methodology considers the directionality of the material’s behaviour and will be treated accordingly.
Tests on specimens with different orientations in space provide valuable information on the dependence of elastic and plastic properties from relative orientation between material (X, Y and Z) and loading directions (ζ) (as shown in Figure 7), giving an insight into the characteristic anisotropy of printed materials (Guessasma et al., 2016; Zeybek et al., 2023). Also, the latter type of test increases the number of experimental information about the mechanical behaviour of the material, strengthening considerations and reliability of the trends observed. Compression tests only conducted along the main material’s directions cannot give a complete overview of the characteristic anisotropy of FFF materials and should then always come along with those where loading and material’s directions do not coincide. This allows for an appropriate consideration of the behaviour of the material, especially when dealing with shear stress acting between printed layers. Shear tests are difficult to perform, and the evaluation of shear elastic and plastic properties can be conducted by uniaxial tests on inclined specimens (Bandinelli et al., 2023).
4.1 Numerical modelling
Composite materials for 3D printing, such as the one analysed in this paper, show an almost linear elastic behaviour in the region of small deformations, followed by a plastic behaviour for larger deformations. For these reasons, it is plausible to consider a material model based on an elastic stiffness matrix for the description of the elastic phase and a yield criterion with a contextual hardening law for the evolution in the plastic region (Zouaoui et al., 2021; Bandinelli et al., 2023; Kucewicz et al., 2018; Bhandari et al., 2020). For as the elastic phase is concerned, an orthotropic elastic matrix is considered to describe the material’s behaviour. In particular, nine independent elastic constants are needed to fully characterize the material’s orthotropy: the elastic moduli in the three main material’s directions (X, Y and Z), the elastic shear moduli in the planes identified by the three main directions and three Poisson’s ratios. Elastic moduli of X, Y and Z directions are derived from experimental values, as well as three out of six Poisson’s ratios. Shear elastic moduli are evaluated by comparing trends of experimental and numerical elastic moduli with respect to the material’s orientation. In this sense, the latter is calculated by equation (1), usually adopted for composite materials (Daniel, 2006):
For what the transition between the elastic and the plastic regimes is concerned, the material’s behaviour is modelled through Hill’s anisotropic yield criterion (Hill, 1948):
4.2 Finite element model
From experimental observations different hypotheses are made about the material model used in the FEA: the 0° configuration is represented with the assumptions of both a generic orthotropic model and a transversely isotropic one (with X and Z directions considered equal), while the 0°/45°/90°/135° configuration is represented by a transversely isotropic model only (with X and Y directions considered equal).
The FE analysis is conducted to represent the material’s compressive behaviour in the test condition. In this sense, a FE model is built inside the LS-DYNA environment to simulate the compression tests on all the specimens. For each specimen 343 (7 × 7 × 7) fully integrated solid elements are used, while 162 (2 × 9 × 9) constant stress solid elements are used for each of the two rigid plates that are used to apply the compressive load. Between the latter, one is fixed in space, while a prescribed motion of 6 mm is imposed on the other (Figure 8). An anisotropic elasto-plastic material model (MAT 157) is used to model the printed material, as it accounts for anisotropy both in elastic and plastic regimes, whereas a rigid elastic material (MAT 020) is used to model the testing machine’s steel plates. Material’s orientation in space is accounted for by specific parameters of MAT157’s card, where a global material’s coordinate system is specified, so each specimen has its own while the geometry of the simulation is kept equal. A node-to-surface contact is added to transfer load, with a friction coefficient of 0.08.
Tables 4 and 5 report the material’s properties used for the simulations in the case of 0° raster angle in both the general orthotropic configuration and transversely isotropic configuration, respectively.
Table 6 reports the material’s properties used for the simulations in the case of 0°/45°/90°/135° raster angle stacking sequence, considering a transversely isotropic material model.
5. Results and discussion
The following analysis compares experimental and numerical material properties as well as engineering stress–strain curves and deformed shapes at the end of the compression tests.
5.1 Elastic behaviour
Experimental and numerical elastic moduli of the 0° and 0°/45°/90°/135° configurations are presented in Figure 9, showing good fitting of the material models used. Here continuous and dashed curves represent numerical values of the compressive elastic modulus and its dependence on the material’s orientation is derived from equation (1) which exactly reflects values of the FE simulations (Zhao et al., 2019; Daniel, 2006). For as the 0° configuration is concerned, the generic orthotropic elastic model can better represent the trend of elastic moduli (with a maximum error of 5.09% of specimen Y75), but the assumption of a transversely isotropic model is considered acceptable, as the maximum deviation between experimental and numerical moduli is 8.9% (specimen X45). Observing trends of the 0°/45°/90°/135° configuration, the hypothesis of a transversely isotropic model appears more appropriate as specimens rotating around the z-axis present almost identical elastic moduli, and the two remaining trends are almost overlapping. It can be noted that in the 0° configuration, the isotropic plane appears to be XZ, while in the 0°/45°/90°/135° configuration it appears to be XY.
5.2 Plastic behaviour
As previously discussed, the FE model is generated to describe the plastic behaviour of the material, adopting Hill’s yield criterion and Voce’s isotropic hardening law. In this work, neither damage nor failure are analysed using FE, but a phenomenological discussion is given in the following. This said the authors choose to identify the onset of damage mechanisms with the decrease in true uniaxial compressive stress and restrict the validity of the comparison between FE models and experimental data accordingly. Figures 10 and 11 display a comparison between curves of the experimental and FE analyses in the cases of the 0° (comparison with the orthotropic model only) and 0°/45°/90°/135° configurations, respectively, showing good accuracy in representing the plastic behaviour of the material in the range of validity. This is further motivated by the fact that a single material model (one for each printing configuration) can describe the material’s behaviour in 18 different cases, which represent various relative orientations between loading and the material’s directions. The experimental curves shown are selected by being the closest to the corresponding mean curves. The experimental curves display once again the significant difference between the two printing configurations, showing how the 0°/45°/90°/135° stacking sequence is more prone to damage and failure. In the 0° configuration, only 5 specimens out of 18 (X60, X75, Y, Z60, Z75) are prone to failure, whereas others show almost no sign of a decrease in true uniaxial compressive stress.
Figure 12 displays comparisons between experimental and FE results with engineering stress evaluated at different engineering strains, where the first are mean values of the corresponding tests. This comparison shows a good agreement between the experimental and numerical values considering the range of validity of the model (the grey background represents strain levels at which the onset of damage occurred, therefore the region in which the presented model has no validity).
FE models are also able to capture an accurate representation of the deformed shapes of some specimens. Figure 13 shows the comparison between numerical and experimental deformed shapes for some of the specimens:
The numerical model is not able to capture deformed shapes when damage and failure mechanisms occur but accounts for the anisotropic nature of the material; in fact, the model does not represent the damage and failure mechanisms and therefore fails to capture this type of behaviour. As an example, specimens X60 show premature failure for both stacking sequences of raster angles, so their deformed shape cannot be entirely represented by the FE model. It is interesting to notice the difference in final shapes between the same specimens of the two different printing configurations, both in FE models and experimental pictures, that highlights the effect of the stacking sequence of raster angles.
5.3 Damage and failure
In this section, a phenomenological discussion about damage and failure mechanisms observed during compression tests is proposed. In the case of the 0° configuration, considerable damage is observed for the Y specimen, which has the highest stiffness and where the Z direction is perpendicular to the loading direction. Specimens Y, as already observed in Zeybek et al. (2023), show two perpendicular shear bands that drive the opening of a central crack (as shown in Figure 14). Specimens X show a deformation behaviour driven by the separation between layers, along the Z direction, but do not reach a failure condition. The specimens tested along the Z direction show a transversal deformation behaviour that is mainly driven by the stretching of the raster’s interfaces along the X direction, but again no failure condition is reached.
Specimens X60, X75, Z60 and Z75 are the closest in terms of orientation to the Y specimens and are in fact characterized by high stiffness. Their orientation in space facilitates damage because printed layers are favourably aligned for delamination and shear sliding (Figure 15), but only X60 and Z75 show failure mechanisms: shear sliding and delamination of printed layers respectively. Other specimens do not show signs of failure, except for X45 and Y75 specimens that presented signs of shear failure in only one test.
In the case of the 0°/45°/90°/135° configuration, many specimens are subjected to damage and premature failure, with interlayer delamination being the principal cause (Guessasma et al., 2016), followed by shear failure where the printed layers are favourably oriented. Specimens X, Y, Z15, Z30, Z45, Z60, and Z75 showed the first failure mode in all tests because the printed layers are always perpendicular to the load direction. Specimens X45, X60, X75, Y45, Y60 and Y75 showed the second failure mode in all tests (except for one Y45 specimen) because the printed layers are favourably oriented to shear sliding. The explanation for the 0°/45°/90°/135° configuration being more prone to failure is found in the deposition pattern, in fact, rasters crossing with different orientations promote the formation of voids and enhance residual stresses, decreasing the layer adhesion strength (Khan et al., 2022; Turner et al., 2014).
Damage and failure mechanisms strongly depend on material orientation, so an anisotropic criterion should be considered to model the material’s failure behaviour. In the present work, an isotropic hardening law is used to represent the plastic evolution, so there is no possibility of describing the anisotropic nature of the material’s failure.
6. Conclusions
3D-printed material’s characterization is not an easy task, and its anisotropic nature poses many challenges from the behaviour modelling point of view. Most of the literature works focus on the tensile characterization of printed materials, leaving their compression behaviour unsolved. Compression tests are a useful tool to characterize FFF material’s behaviour and the use of post-processed specimens (presented herein) allows for a more representative study of the mechanical properties. The present work delivers an effective procedure to characterize the compressive behaviour of 3D-printed materials, focusing the attention on the post-processing of specimens and the FE modelling technique. No work to date, to the authors’ knowledge, has explored a more complete combination of raster angles and building orientations, making this work valuable as a reference for anisotropy studies in the field of 3D-printed materials. Among different findings, the present work highlighted the dependency of mechanical behaviour (both elasto-plastic behaviour and failure modes) on both building strategy and orientation in space. The material model based on an elastic stiffness matrix with a combination of Hill’s yield criterion and Voce’s isotropic hardening law is able to represent the short carbon-reinforced PA12 anisotropic behaviour, also capturing some aspects of the deformation modes. Once enriched with a failure criterion, the FE model can be effectively used for verification and design purposes. Future work will be conducted to deepen the understanding of failure modes and novel material’s characterization techniques.
Figures
Figure 9
Comparisons between experimental (squared markers) and numerical distributions (continuous lines for the generic orthotropic model and dashed lines for the transversely isotropic ones) of elastic moduli in the 0° configuration (on the left) and in the 0°/45°/90°/135° configuration (on the right)
Elastic moduli of specimens tested as printed
Elastic modulus (MPa) | Stacking sequence | |||
---|---|---|---|---|
Material direction | 0° | +45°/−45° | 0°/90° | 0°/45°/90°/135° |
X | 1,021 (79) | 938 (69) | 953 (37) | 968 (31) |
Y | 1,618 (57) | 775 (46) | 818 (31) | 812 (56) |
Z | 986 (35) | 1,181 (50) | 1,172 (41) | 1,178 (36) |
Table by authors
Experimental values of material’s properties of the specimens with 0° configuration
Exx (MPa) | Eyy (MPa) | Ezz (MPa) |
---|---|---|
1393 (90) | 2530 (44) | 1495 (68) |
νxy (−) | νxz (−) | νyz (−) |
0.115 (0.013) | 0.400 (0.021) | 0.250 (0.018) |
Yxx (MPa) | Y (MPa) | Yzz (MPa) |
41.58 (1.72) | 54.81 (0.95) | 41.96 (0.80) |
Table by authors
Experimental values of material’s properties of specimens with 0°/45°/90°/135° configuration
Exx (MPa) | Eyy (MPa) | Ezz (MPa) |
---|---|---|
1,679 (178) | 1,761 (105) | 1,530 (133) |
νxy (−) | νxz (−) | νyz (−) |
0.320 (0.023) | 0.400 (0.027) | 0.400 (0.019) |
Yxx (MPa) | Yyy (MPa) | Yzz (MPa) |
42.27 (1.65) | 41.01 (2.06) | 39.04 (2.01) |
Table by authors
Material properties adopted in the FE simulations in the LS-DYNA environment for the case of 0° raster angle, in the general orthotropic configuration
Exx (MPa) | Eyy (MPa) | Ezz (MPa) | Gxy (MPa) | Gxz (MPa) | Gyz (MPa) |
---|---|---|---|---|---|
1,400 | 2,530 | 1,500 | 570 | 505 | 470 |
νxy (−) | νyx (−) | νxz (−) | νzx (−) | νyz (−) | νzy (−) |
0.115 | 0.208 | 0.400 | 0.429 | 0.250 | 0.149 |
F (1/MPa2) | G (1/MPa2) | H (1/MPa2) | L (1/MPa2) | M (1/MPa2) | N (1/MPa2) |
0.000135 | 0.000494 | 0.000299 | 0.001422 | 0.001303 | 0.001295 |
Cr (−) | Qr (−) | Crs (−) | Qrs (−) | ||
4.028 | 0.474 | 0.001 | 8.097 |
Table by authors
Material properties adopted in the FE simulations in the LS-DYNA environment for the case of 0° raster angle, in the transversely isotropic configuration
Exx (MPa) | Eyy (MPa) | Ezz (MPa) | Gxy (MPa) | Gxz (MPa) | Gyz (MPa) |
---|---|---|---|---|---|
1,450 | 2,530 | 1,450 | 550 | 510 | 510 |
νxy (−) | νyx (−) | νxz (−) | νzx (−) | νyz (−) | νzy (−) |
0.144 | 0.250 | 0.400 | 0.400 | 0.250 | 0.144 |
F (1/MPa2) | G (1/MPa2) | H (1/MPa2) | L (1/MPa2) | M (1/MPa2) | N (1/MPa2) |
0.000214 | 0.000466 | 0.000214 | 0.00141 | 0.00139 | 0.00141 |
Cr (−) | Qr (−) | Crs (−) | Qrs (−) | ||
4.263 | 0.463 | 0.033 | 0.418 |
Table by authors
Material’s properties adopted in the FE simulations in the LS-DYNA environment for the case of 0°/45°/90°/135° stacking sequence
Exx (MPa) | Eyy (MPa) | Ezz (MPa) | Gxy (MPa) | Gxz (MPa) | Gyz (MPa) |
---|---|---|---|---|---|
1,720 | 1,720 | 1,530 | 605 | 400 | 400 |
νxy (−) | νyx (−) | νxz (−) | νzx (−) | νyz (−) | νzy (−) |
0.320 | 0.320 | 0.400 | 0.356 | 0.400 | 0.356 |
F (1/MPa2) | G (1/MPa2) | H (1/MPa2) | L (1/MPa2) | M (1/MPa2) | N (1/MPa2) |
0.000430 | 0.000430 | 0.000425 | 0.00207 | 0.00207 | 0.00122 |
Cr (−) | Qr (−) | Crs (−) | Qrs (−) | ||
3.701 | 0.554 | 0.035 | 1.050 |
Table by authors
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Further reading
Turner, B.N. and Gold, S.A. (2015), “A review of melt extrusion additive manufacturing processes: II. Materials, dimensional accuracy, and surface roughness”, Rapid Prototyping Journal, Vol. 21 No. 3, pp. 250-261, doi: 10.1108/RPJ-02-2013-0017.
Acknowledgements
The authors would like to thank FiberForce for providing the printing materials. The research used the equipment of DYNLab Laboratory at Politecnico di Torino co-funded by POR FESR Piemonte 2014–2020.