Thermal and Flammability Characteristics of Blended Jatropha Bio-Epoxy as Matrix in Carbon Fiber–Reinforced Polymer

Hafiezal, M. R. M.; Abdan, Khalina; Zurina, Z; Azaman, Deros Mohd; Hanafee, Z.M.

doi:10.3390/jcs3010006

Cited by 40 publications

(21 citation statements)

References 30 publications

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“…Moreover, the degradation temperatures of both lignin‐based thermosets are remarkably higher than their T g values (Table 1), indicating that they can be used for applications that do not require high‐temperature stability [58] . The statistical heat resistant‐indices ( T s ) of cured lignin‐based samples were about 33–36 °C lower than T s of cured DGEBA, showing their lower heat tolerance [57] . The epoxy system made with organosolv lignin (4‐O‐CS) had higher thermal stability than the epoxy made with kraft hardwood (11‐K‐HW).…”

Section: Resultsmentioning

confidence: 99%

“…The first stage of degradation is primarily due to the breaking of aliphatic chains and releasing small molecules like CO, CO 2 , and water [56] . The second stage of degradation is most likely associated with the degradation of aromatic rings and oxidation of C−C linkages and different functional groups such as methoxy, phenol, and carbonyl [57] . Although the degradation of lignin‐based thermosets was started at lower temperatures (241–245 °C) compared to the DGEBA thermoset (350 °C), the difference was smaller at higher temperatures.…”

Section: Resultsmentioning

confidence: 99%

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Choosing the Right Lignin to Fully Replace Bisphenol A in Epoxy Resin Formulation

et al. 2021

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Thirteen unmodified lignin samples from different biomass sources and isolation processes were characterized and used to entirely replace bisphenol A (BPA) in the formulation of solubilized epoxy resins using a developed novel method. The objective was to measure the reactivity of different lignins toward bio‐based epichlorohydrin (ECH). The epoxy contents of various bio‐based epoxidized lignins were measured by titration and 1H NMR spectroscopy methods. A partial least square regression (PLS‐R) model with 92 % fitting accuracy and 90 % prediction ability was developed to find correlations between lignin properties and their epoxy contents. The results showed that lignins with higher phenolic hydroxy content and lower molecular weights were more suitable for replacing 100 % of toxic BPA in the formulation of epoxy resins. Additionally, two epoxidized lignin samples (highest epoxy contents) cured by using a bio‐based hardener (Cardolite GX‐3090) were found to show comparable thermomechanical performances and thermal stabilities to a petroleum‐based (DGEBA) epoxy system.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Choosing the Right Lignin to Fully Replace Bisphenol A in Epoxy Resin Formulation

et al. 2021

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“…From the TGA analysis, we can see that the thermal stability of the RDGE resin (T 5% = 337 °C) was improved by ≈2–7 °C by HC reinforcement. The thermal stability of the developed materials was also analyzed by the statistic heat-resistant index (T s ) calculated by equation [ 37 , 38 ]:

where T 5% is the temperature at which the samples lose 5% of their mass and T 30% represents the temperature at which the materials lose ≈30% of their mass. This factor gives the physical heat tolerance limit temperature, and the calculated T s values are presented in Table 1 .…”

Section: Resultsmentioning

confidence: 99%

Hydrothermal Carbon as Reactive Fillers to Produce Sustainable Biocomposites with Aromatic Bio-Based Epoxy Resins

et al. 2021

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Thiswork is focused on the development of sustainable biocomposites based on epoxy bioresin reinforced with a natural porous material (hydrochar, HC) that is the product of spruce bark wastes subjected to hydrothermal decomposition. To identify the influence of hydrochar as a reinforcing material on the designed composites, seven formulations were prepared and tested. An aromatic epoxy monomer derived from wood biomass was used to generate the polymeric matrix, and the formulations were prepared varying the filler concentration from 0 to 30 wt %. The reactivity of these formulations, together with the structural, thermal, and mechanical properties of bio-based resin and biocomposites, are investigated. Surprisingly, the reactivity study performed by differential scanning calorimetry (DSC) revealed that HC has a strong impact on polymerization, leading to an important increase in reaction enthalpy and to a decrease of temperature range. The Fourier Transform Infrared Spectroscopy (FT-IR) investigations confirmed the chemical bonding between the resin and the HC, while the dynamic mechanical analysis (DMA) showed increased values of crosslink density and of storage moduli in the biocomposites products compared to the neat bioresin. Thermogravimetric analysis (TGA) points out that the addition of hydrochar led to an improvement of the thermal stability of the biocomposites compared with the neat resorcinol diglycidyl ether (RDGE)-based resin (T5% = 337 °C) by ≈2–7 °C. Significantly, the biocomposites with 15–20 wt % hydrochar showed a higher stiffness value compared to neat epoxy resin, 92SD vs. 82SD, respectively.

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“…TGA was used to determine the thermal stability of the composite, which was found to be 205°C without the addition of EG and 243°C with a 5 percent EG loading. At 18 percent filler loading, Hafiezal et al [12] found that combining bio jatropha filler with epoxy resulted in enhanced dynamic and thermal performance of the blended composite. By integrating waste peanut shell powder in epoxy resin, Prabhakar et al [13] produced bio composites, and studies were undertaken to determine the effect of filler content on the mechanical and thermal properties of the composite.…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of Pterocarpus Marsupium Resin/LY 556 Epoxy Blended Hybrid Polymer Material

Prasath¹,

Somasundaram²,

Subramanian³

et al. 2022

Mater. Plast.

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In this work an attempt had been made to hybridise the Epoxy resin by incorporating the Pterocarpus Marsupium natural resin powder derived from the Pterocarpus Marsupium tree. The mechanical, dynamic mechanical, biodegradability and thermal stability of the blended polymer was evaluated at different Pterocarpus Marsupium resin particulate loading (10, 15, 20, 25, 30 and 35 v/v %). The composite specimens were fabricated by using hand layup method. The mechanical properties such as tensile strength, flexural strength had shown significant improvement than the tensile modulus and flexural modulus due to blending, the experimental results indicated that the better properties of the blended polymer were obtained at 30% v/v Pterocarpus Marsupium resin incorporated Epoxy polymer. Soil burial test revealed that the incorporation of bio resin resulted in weight loss of the blended polymer over prolonged period of time.

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Thermal and Flammability Characteristics of Blended Jatropha Bio-Epoxy as Matrix in Carbon Fiber–Reinforced Polymer

Cited by 40 publications

References 30 publications

Choosing the Right Lignin to Fully Replace Bisphenol A in Epoxy Resin Formulation

Choosing the Right Lignin to Fully Replace Bisphenol A in Epoxy Resin Formulation

Hydrothermal Carbon as Reactive Fillers to Produce Sustainable Biocomposites with Aromatic Bio-Based Epoxy Resins

Experimental Investigation of Pterocarpus Marsupium Resin/LY 556 Epoxy Blended Hybrid Polymer Material

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