Fiber Loading Research Articles

Mechanical and tribological characterization of vacuum pressurized impregnation (VPI) treated bamboo fiber-reinforced polymer (FRP) composites with jute mat layer under fretting wear conditions

ABSTRACT The study explored the performance of VPI-treated bamboo fiber reinforced FRP laminated composites, focusing on fretting wear and mechanical behavior with various chemical treatments. FTIR analysis revealed that NaOH treatment effectively removed hemicelluloses and lignin, with peak shifts at 3330, 2918, and 1420 cm−1, while tannic acid induced peak shifts at 1640 and 1500 cm−1, indicating cellulose interactions. Phosphoric acid treatment reduced intensity at 3340 and 2890 cm−1, suggesting cellulose depolymerization. TGA showed varied weight loss profiles, reflecting thermal property modifications. XRD analysis indicated changes in crystalline structure, and SEM revealed structural alterations. Tensile strengths at 0.5% weight were 216 ± 3.0 MPa for alkaline-treated bamboo fiber composite (A-BFC), 256 ± 0.01 MPa for tannic acid-treated bamboo fiber composite (T-BFC), and 281 ± 3.0 MPa for phosphoric acid-treated bamboo fiber composite (P-BFC). Fretting wear analysis demonstrated that P-BFC withstood loads up to 45N, with wear resistance improving with increased fiber content. dynamic mechanical analysis (DMA) highlighted that P-BFC exhibited the highest initial storage modulus and a tan δ peak of 69°C, compared to T-BFC and A-BFC, both at 68°C. The wear rate decreased with higher bamboo fiber content and load, showcasing the potential of VPI-treated bamboo fiber composites for applications requiring enhanced strength and wear resistance.

Comprehensive Evaluation of Printing Process Parameters and Tensile Properties of Coconut Polypropylene Filament Composites in Additive Manufacturing

The printing process parameters are important in producing coconut polypropylene (CcPP) products by filament composite in the additive manufacturing industry. Fused deposition modeling techniques in 3D printing applications have considered multiple parameters to meet good finishing parts. This study uses comprehensive measurements to identify the best printing parameter for evaluating the composite properties. Complete deposition, unwrapping, good finishing, and adequate heat are the qualitative printing process parameters used to finalize the optimum nozzle and bed temperature of the CcPP filament composite. The range between 50⁰C to 80⁰C and 225⁰C to 245⁰C for bed and nozzle temperatures were used to achieve a well surface and successful production. After multiple trials of printing the CcPP filament composite, the optimal bed and nozzle temperatures were found to be 80°C and 230°C, respectively. Two types of infill density were used to analyze the effect on the tensile properties of CcPP filament composite. The result showed that 50% infill density was higher for both 1% and 5% fiber loading than 25% infill density for tensile strength with 15.65 and 22.87 MPa compared to 12.93 and 16.59 MPa. The same pattern as the score of Young’s moduli of 50% infill density was higher than 25% infill density for 1% and 5% fiber loadings with 479.52 and 641.23 MPa compared to 400.17 and 493 MPa. Qualitative and quantitative measurements of printing process parameters and properties help reduce the time and cost and benefit 3D printer users in the industry.

Exploring the potential of agricultural waste enset fibers reinforced poly lactic acid biocomposites

This study explores the environmental sustainability of composite materials by reinforcing agricultural residue enset fiber as a potential reinforcement. Initially, enset fibers underwent a 5 wt% sodium hydroxide treatment to eliminate impurities and enhance fiber-matrix adhesion in the subsequent biocomposite fabrication process. Various enset fiber-to-polylactic acid ratios were blended and opened to enset/PLA fibers mat using a fiber carding machine, and the resulting biocomposite material was prepared through the hot press. A comprehensive assessment covering mechanical, thermal, dynamic mechanical, water absorption, and morphological properties was conducted on the enset/PLA biocomposites. The results showed increased mechanical (tensile strength of 24.12 MPa, bending stress of 33.02 MPa, flexural modulus of 2.01 GPa, the impact resistance of 12 kJ/m2) and thermomechanical properties with increased enset fiber loading, with optimum value at a 30 % weight percentage. The Differential scanning calorimetry results showed the addition of enset fiber increases the glass transition temperatures and degree of crystallinity. SEM images confirmed robust adhesion between enset fibers and PLA. This study highlights the potential applications of enset/PLA composites in automotive, furniture, packaging, and diverse industries, emphasizing their promising role in sustainable material development.

Hydrothermal aging and soil biodegradation characteristics of biopolymer based sustainable composites

The current research endeavor examines the water absorption (in-service life) and soil biodegradation (end-of-the-service life) behavior of short sisal fiber (SF) reinforced poly (lactic acid) (PLA) and bio-based poly (butylene succinate) (bio PBS) composites. Samples were fabricated by extrusion-injection molding with varying sisal fiber loading of 10, 20, and 30 wt%. The water absorption test was conducted in distilled water at three distinct temperatures (5, 25, and 45 °C) for 336 h. The sorption behavior of composites was studied experimentally, and detailed diffusion kinetic behavior is discussed using Fickian diffusion models. The impact of fiber content and hydrothermal temperature on water diffusion and maximum water absorption was investigated in detail. A soil burial test was conducted in local farmland soil for 60 days to determine the influence of fiber content on the biodegradation characteristics of composites. After exposure to hydrothermal aging, it was concluded that fiber loading was most significant in affecting the maximum percentage of water absorption, whereas hydrothermal temperature was more relevant for higher water diffusion. Soil burial tests showed that SF/bioPBS composites degraded quickly as compared to PLA composites. Overall, composites made with bio PBS have shown an expected response than PLA composites in terms of water absorption and soil biodegradation.

Reinforcing Efficiency of Recycled Carbon Fiber PLA Filament Suitable for Additive Manufacturing.

The use of 3D printing technology for manufacturing new products based on sustainable materials enables one to take advantage of secondary raw materials derived from recycling. This work investigates the structural performances of 3D printing composite filaments based on polylactic acid (PLA), as a matrix, reinforced by recycled carbon fiber (rCF). Carbon fibers were recovered from industrial scraps by a patented thermal process and used to produce thermoplastic composite filaments for additive manufacturing without any additional treatment and additives. The influence of the recovered carbon fiber (rCF) content on the thermal properties, mechanical properties and microstructure of the composites was studied in the range of 3-20 wt%. The recorded TGA curves exhibited a one-stage weight loss within the temperature range 290-380 °C for all samples and the residual rCF content was in good agreement with the theoretical fiber loading. The Young modulus of the extruded filaments strongly increased below a critical content (5 wt%), while at higher content the improvement was reduced. An increase in the storage modulus of 54% compared to neat PLA 3D printed sample resulted in a printed specimen with a higher rCF content. SEM images highlighted a strong rCF prevailing alignment in the direction of the extrusion flow, creating almost unidirectional reinforcement inside the filament. These findings suggest that homogeneous composite filaments reinforced with well-dispersed recycled CF without additional chemical modification and additives are suitable materials for additive manufacturing. The effect of rCF topological distribution within the material on the mechanical performances has been discussed, highlighting that the isolated fibers could efficiently transfer loads with respect to the percolated 3D network and have been correlated with the microstructure.

3D printing of continuous metal fiber-reinforced recycled ABS with varying fiber loading

PurposeThe current study aims to develop a 3D-printed continuous metal fiber-reinforced recycled thermoplastic composite using an in-nozzle impregnation technique.Design/methodology/approachRecycled acrylonitrile butadiene styrene (RABS) plastic was blended with virgin ABS (VABS) plastic in a ratio of 60:40 weight proportion to develop a 3D printing filament that was used as a matrix material, while post-used continuous brass wire (CBW) was used as a reinforcement. 3D printing was done by using a self-customized print head to fabricate the flexural, compression and interlaminar shear stress (ILSS) test samples to evaluate the bending, compressive and ILSS properties of the build samples and compared with VABS and RABS-B samples. Moreover, the physical properties of the samples were also analyzed.FindingsUpon three-point bend, compression and ILSS testing, it was found that RABS-B/CBW composite 3D printed with 0.7 mm layer width exhibited a notable improvement in maximum flexural load (Lmax), flexural stress at maximum load (sfmax), flex modulus (Ef) and work of fracture (WOF), compression modulus (Ec) and ILSS properties by 30.5%, 49.6%, 88.4% 13.8, 21.6% and 30.3% respectively.Originality/valueLimited research has been conducted on the in-nozzle impregnation technique for 3D printing metal fiber-reinforced recycled thermoplastic composites. Adopting this method holds the potential to create durable and high-strength sustainable composites suitable for engineering applications, thereby diminishing dependence on virgin materials.

Waste nylon fishing net fiber incorporated natural rubber composites as a remedy for waste reusing into a value‐added material

AbstractThis study focuses on reusing the waste fishing nets with natural rubber (NR) to create a value‐added composite material. WNF fibers at different loadings (2, 4, and 6 phr) and lengths (2, 3, 5, and 7 mm) were investigated for a general tire formulation. The anisotropic nature of WNF was evident in tear strength, with optimal results for 2 mm, 2 phr fiber loading. It displayed 15.87% improvement longitudinally compared with the control. Further, it displayed improved 5.55% hardness, whereas resilience, abrasion volume loss, and tensile strength were decreased. In the second stage, these fibers treated with KOH (2%, 6%, and 10%) with the expectation of enhancing the mechanical properties. The 2% KOH‐treated sample presented a significant escalation in hardness (+12.50%), resilience (+6.25%), abrasion volume loss (+3.63%), tear strength (+17.23%), and tensile strength (+8.20%) as of the control. Partial replacement of carbon black (CB) with 2% KOH treated 2 mm 2 phr WNF was evaluated. A 9% of CB in rubber compound was easily supersede by WNF. Our findings indicated that WNF fibers could be reuse as a filler in rubber composite where special property enhancements are advantageous in tire technology.

Computational modelling and prediction of nonlinear deflection responses of bonded joint component with multiple damage (crack and delamination) – An experimental validation

The present research evaluates the presence of damage, including delamination and cracks, affects the deflection response of an adhesively bonded single lap joint (SLJ). In this study, the numerical analysis is performed for intact and influence of different damages in the adherend of SLJ in the commercial simulation software (ABAQUS). The circular delamination of radius ‘R’ 10 mm and crack having length ‘l’ 20 mm, the radius of curvature ‘Rc’ 0.2 mm are imposed into the laminate adherend using node-to-surface interaction technique. The stability of the simulation model is verified by comparing the deflection values from published results and experimental data. The confirmed simulation model is broadened to examine the impact of design factors (fiber orientation, loading position, delamination shape, crack position and orientation, and delamination position with and without crack) on the deflection response for various overlapping lengths (25, 30, 35, and 40 mm) for final design recommendation. Additionally, the sensitivity analysis was performed using a surrogate model (i.e., variance-based method) by constructing the second-order polynomial function to quantify the influence of damages under the input parameters. The detailed features and multivariate model functions have been analysed for the various damage cases of SLJ.

Effect of Loading of Kapok Fiber with Epoxy on Mechanical and Electrical Properties of Its Composites

Effect of Loading of Kapok Fiber with Epoxy on Mechanical and Electrical Properties of Its Composites

EVALUATION OF THE MECHANICAL PROPERTIES OF STYRENE BUTADIENE RUBBER(SBR)/BANANA FIBRE(BF) COMPOSITES

Tensile strength, rip strength, abrasion loss, hardness, and thermal conductivity are the main characteristics of Styrene-Butadiene Rubber (SBR) composites that are examined in this work as a function of increasing banana fibre loading. Because banana fibres are reinforcing, adding them to the SBR matrix initially increases tensile and tear strength. However, there is an ideal concentration at which fibre aggregation and poor interfacial bonding cause these qualities to drop. Abrasion loss increases with higher loadings because of insufficient fibre dispersion, but it decreases with moderate fibre concentration, indicating enhanced wear resistance. Fibre addition improves the composites' hardness up to a certain point, beyond which adding too many fibres causes inconsistent results and lower hardness. It is discovered that as fibre counts increase, thermal conductivity decreases. KEYWORDS—SBR composites, tensile strength, thermal conducutivty.

Electrospinning of emulsions stabilized by octenylsuccinylated starch and pullulan

Emulsion electrospinning emerges as a promising technique for producing core-shell nanofibers used in delivering bioactive compounds. This work aims to investigate the feasibility of employing octenylsuccinylated (OS) starch-based emulsions in electrospinning for the fabrication of these nanofibers. The influence of sunflower seed oil concentration, ranging from 5% to 50%, on the emulsions was systematically examined. Increasing the oil concentration affects several key characteristics of the emulsions. These changes include a rise in apparent viscosity (from 0.78 to 7.72 Pa·s at 100 s−1) and average droplet size (from 1.21 to 1.79 μm), as well as a decrease in conductivity (from 727 to 193 μs/cm), leading to a larger average diameter of electrospun fibers, which increased from 294 to 533 nm. Confocal laser scanning microscopy and transmission electron microscopy confirmed the core–shell structure of the fibers. Furthermore, the correlation between fiber size and emulsion properties was discussed, and it was noted that the average fiber diameter, loading capacity, and encapsulation efficiency were significantly affected by emulsion composition and properties. These insights contribute to our understanding of the emulsion electrospinning process and offer a valuable guidance for the development of OS starch-based core–shell electrospun fibers.

Sustainable basalt fiber reinforced polyamide 6,6 composites: Effects of fiber length and fiber content on mechanical performance

The aim of this study is to explore the use of sustainable basalt fiber (BF) as compared to glass fiber and talc in injection molded engineering polyamide 6,6 (PA 6,6) plastic composite. Basalt fibers having lengths of 3 mm and 12 mm were added to PA 6,6 at 23 and 30 wt.% to fabricate the composites. The addition of basalt fiber restricts the mobility of the polymer chain in the composites, leading to its increased viscosity. Rheological results showed that the out-of-phase response to the applied stress indicated that the 3 mm basalt fiber composite could dissipate more energy, and the elastic behaviour of the composite under deformation increased with increasing basalt fiber wt.%. The fiber length had a larger effect on the mechanical properties of the composites as compared to the fiber load. The 12 mm basalt fiber composites at 23 wt.% and 30 wt.% produced higher tensile strength and modulus than the 3 mm basalt fiber composites while the 3 mm basalt fiber composite at 30 wt.% resulted in a 25 % increase in flexural strength. The experimental and the theoretical modulus predicted by the rule of mixtures showed an interaction between the matrix and the basalt fiber. Morphological analysis shows more agglomeration in composites with 3 mm fiber than the 12 mm. Glass fiber-reinforced PA 6,6 showed slightly higher performance than basalt fiber-reinforced PA 6,6. However, the basalt fiber-reinforced composites demonstrated better performance in tensile strength, flexural modulus, flexural strength, and heat deflection temperature than talc-reinforced composites.

Testing and Evaluation of Hybrid Polymer Composites Reinforced with Moringa oleifera and Boehmeria nivea Fibers, Embedded with Copper Oxide Particulates, for Thermal, Structural, and Biological Properties

Abstract The increasing need for sustainable materials in industrial applications has prompted a significant shift in attention from synthetic to natural fibers. This study examines the problems and opportunities arising from the utilization of natural fiber-reinforced polymer composites in several industrial sectors. The objective of this work is to fabricate a hybrid composite using a conventional hand layup technique with natural reinforcement of Moringa oleifera (MO) and ramie (Boehmeria nivea) fibers, an epoxy matrix blended with copper oxide filler, utilized to enhance material stability and antimicrobial activity. To quantify the effect of five different weight fractions of MO and ramie fibers on this hybrid composite, its mechanical, thermal, functional, and antifungal properties were examined. The superior tensile strength (61.34 MPa), flexural strength (64.78 MPa), and impact energy (23 J) results indicate that ramie fiber loading should be increased. Additionally, enhanced thermal properties such as thermal conductivity (0.93 W/mK), heat deflection temperature (97°C), thermal expansion coefficient (1.7210−5/°C), and maximal thermal stability were observed at 347°C as a result of the increased ramie fiber loading. This analysis demonstrates that this hybrid composite possesses the antifungal activity necessary to form an inhibition zone against Candida albicans. Scanning electron microscopy analysis was conducted to determine the hybrid composites’ bonding strength and failure mode.

Influence of Z‐pin material on the mechanical properties of fine Z‐pin reinforced composites

AbstractThe insertion of finer Z‐pins is an effective method to reduce the microstructure damage and maintain the in‐plane performance of composite laminates. In this paper, an ultrasound guided insertion process is proposed to achieve the insertion of fine Z‐pins and the influence of Z‐pin material on the mechanical properties of Ø0.11 mm Z‐pin reinforced composite laminates is revealed based on experiments and simulations. For in‐plane mechanical properties, stainless steel Z‐pins help to reduce the loss of compression modulus and compression strength. For the interlaminar mechanical properties, stainless steel Z‐pins and carbon fiber Z‐pins exhibit bilinear and trilinear bridging laws respectively, resulting in the mode‐I maximum load and fracture toughness of carbon fiber Z‐pin reinforced composites being greater than that of stainless steel Z‐pin reinforced composites. By adjusting the insertion spacing, it is found that for unidirectional composite laminates reinforced by Ø0.11 mm carbon fiber Z‐pins with an insertion spacing of 2 mm, the compression strength reduction is only 3.39% while the mode‐I fracture toughness can be improved by 14.4 times in comparison with the unpinned specimens, achieving a better balance between in‐plane performance loss and interlaminar reinforcement effect.Highlights The effect of Z‐pin material on fine Z‐pin reinforced composites is studied. The compression properties are simulated by the RVE model. The mode‐I fracture properties are simulated by the DCB unit strip model.

Characterization of Posidonia oceanica Fibers High-Density Polyethylene Composites: Reinforcing Potential and Effect of Coupling Agent

This study investigated the influence of fiber loading and maleated polyethylene (MAPE) coupling agent on the structural, thermal, mechanical, morphological properties, and torque rheology of high-density polyethylene (HDPE) reinforced with Posidonia oceanica fiber (POF) composites. HDPE/POF composites, both with and without MAPE, were manufactured using a two-step process: composite pellets extrusion, followed by test samples injection molding with various POF loadings (0, 20, 30, and 40 wt%). HDPE/POF composites reinforced with higher loading of POF (40 wt%) exhibit superior stiffness, better crystallinity, and higher stabilized torque and mechanical energy (Em) compared to other composite formulations. Therefore, varying the POF loading leads to extrusion and injection processing variations. Furthermore, the coupling agent significantly enhances the tensile strength, ductility, impact strength, crystallinity, stabilized torque, and Em of the HDPE/POF composite. This improvement is due to the enhanced interfacial adhesion between the POF and the HDPE matrix with the addition of the MAPE, as supported by the Scanning Electron Microscopy (SEM) micrographs.

Material Selection of Natural Fibre Composite Webbing Sling Using Rule of Mixture

Natural fibre composites have grown in popularity as environmental concerns and knowledge about using eco-friendly materials versus synthetic materials. Furthermore, due to their low density and high strength, natural fibres are suitable for use as lightweight composite and reinforcing materials. Webbing slings are commonly used in many industries to lift loads and are typically made of synthetic fibres such as nylon and polyester. This study analysed the physical and mechanical properties, such as density, tensile strength, and Young’s modulus of natural fibre composites. Bananas, pineapple, and jute with polymer matrices such as polypropylene (PP) and epoxy (EP) were used as alternative natural fibre composites for webbing sling application. Furthermore, descriptive statistical analysis was done to summarise the secondary data from the previous study of the physical and mechanical properties of natural fibre and polymer matrix. The rule of mixture (ROM) is used to identify the optimum fibre loading for manufacturing the webbing sling. This study’s volume fractions of fibre were 10%, 30%, and 50%. Using the ROM equation, the results revealed that the higher fibre loading of up to 50% could increase the mechanical properties such as tensile strength and Young’s modulus. Based on the results, pineapple/epoxy composite was the best material to manufacture the webbing sling and complied with the requirements of Product Design Specifications of polyester webbing sling compared to banana and jute composites.

Investigation of the Mechanical Properties of Urethane Dimethacrylate (UDMA) Reinforced with Abaca Cellulose for Vat Photopolymerization (VP)

Additive manufacturing (AM) was developed to cope with the demand for manufacturing goods. It ensures faster production and high waste reduction but is limited by material compatibility. One of the technologies in AM is Vat Photopolymerization (VP). It is a type of AM that uses photopolymer resin and UV light for polymerization. Various materials had been studied to improve the mechanical properties of the photopolymer resin by adding additives from indigenous sources. This study extracted cellulose from abaca and modified it by cross-linking it with Polyethylene Glycol (PEG). The cross-linked abaca cellulose (CAC) was investigated as an additive in the photopolymer resin with fiber loading of 3 wt.%, 6 wt.% and 9 wt.%. Fourier Transform-Infrared Spectroscopy (FT-IR) shows that the presence of the oxygenated functional groups in resin and CAC can interact to form hydrogen bonds. Thermogravimetric Analysis (TGA) showed better thermal stability with the addition of 9 wt.% CAC compared to pure UDMA. Furthermore, the glass transition (Tg) decreased with the addition of CAC by 8.29 °C. The Tensile Test showed that 3 wt.% of CAC resulted in the highest value for tensile strength and toughness with an 11.27% increase for tensile strength and 133.46% for toughness. The elastic modulus increased with fiber loadings and had increased by 48.51% at 9 wt.% of CAC. Based on the results, the effect of adding abaca cellulose into a UDMA based resin had improved the thermal stability and mechanical properties of the composites.

Self-driven ion deflectometry measurements using MeV fusion-driven protons and accelerated deuterons in the deuterated hybrid x-pinch on the MAIZE LTD generator

We report on the results of point-projection ion deflectometry measurements from a mid-size university z-pinch experiment. A 1 MA 8 kJ LTD generator at the University of Michigan (called MAIZE) drove a hybrid x-pinch (HXP) with a deuterated polyethylene fiber load to produce a point-like source of MeV ions for backlighting. In these experiments, 2.7 MeV protons were generated by DD beam-target fusion reactions. Due to the kinematics of beam-target fusion, the proton energies were down-shifted from the more standard 3.02 MeV proton energy that is released from the center-of-mass rest frame of a DD reaction. In addition to the 2.7 MeV protons, strongly anisotropic beams of 3 MeV accelerated deuterons were detected by ion diagnostics placed at a radial distance of 90 mm from the x-pinch. Numerical reconstruction of experimental data generated by deflected hydrogen ion trajectories evaluated the total current in the vacuum load region. Numerical ion-tracking simulations show that accelerated deuteron beams exited the ion source region at large angles with respect to the pinch current direction.

Modeling and evaluation of the fracture resistance of alkali-resistant glass fibre reinforced concrete under different loading rates

Alkali-resistant glass fibre reinforced concrete (AR-GFRC) has garnered significant interest due to its economic and environmental friendliness. Given the critical importance of evaluating the crack resistance of AR-GFRC under dynamic loading conditions and the size effect inherent in determined fracture parameters using traditional methods, this study aims to propose an analytical approach based on the boundary effect model. The goal is to predict the realistic dynamic tensile strength (ft) and fracture toughness (KIC) while elucidating the rate sensitivity of fracture resistance. Three-point bending tests were conducted on AR-GFRC with three different fibre volumes to investigate dynamic fracture behaviors under varying loading rates. By introducing discrete parameter and the microstructure characteristic parameter that account for material discontinuity and heterogeneity, the realistic dynamic ft and KIC of AR-GFRC can be directly obtained as closed-form solutions upon determining the maximum fracture load from the tests. The results revealed a substantial increase in ft and KIC with an improvement in the loading rate. However, due to relatively weakened fibre activities, the enhancement of dynamic fracture resistance decreases with the increase in fibre content and loading rate.

Analysis of fiber-reinforced silicon carbide formed via material extrusion

Here, we report a method for fabrication of robust and near-net shaped carbon-fiber reinforced silicon carbide (Cf/SiC) through the additive manufacturing method of material extrusion. The addition of fibers allows for enhanced damage tolerance and thermal shock resistance but little is known about the resulting affects to resulting ink rheology, printability and resulting fiber alignment in the printed components. As such, three separate inks were developed with carbon fiber loadings of 0 %, 5 % and 15 % by volume. All inks had requisite rheology for material extrusion to fabricate near-net and dense components via pressureless sintering with densities of 93.95 %, 92.11 %, and 85.65 %, respectively. Micro X-ray computed tomography and deep learning auto-segmentation was utilized to fully describe the fiber orientation in 3D, revealing highly oriented fibers. 4-point flexure testing was performed on as-printed bend bars for all 3 ink compositions. The bars had robust average flexural strengths of 114–260 MPa, with a decrease in strength observed in fiber-reinforced samples as attributed to a decrease in sample density. However, an increase in Weibull modulus (18.0 compared to 7.0–7.3) and observed fiber pull out for the 15 % Cf samples suggest promise in toughening and reliability of fiber reinforcements. Oxyacetylene torch testing was performed on all 3 types of printed parts to study the oxidation and ablation resistance of the silicon carbide samples with fibers. Only samples with fiber reinforcements survived thermal shock of testing further emphasizing the need and benefit of fiber inclusions.