A fused deposition modeling method
was used in this research to
investigate the possibility of improving the mechanical properties
of poly(lactic acid) by changing the thermal conditions of the printing
process. Sample models were prepared while varying a wide range of
printing parameters, including bed temperature, melt temperature,
and raster angle. Certain samples were also thermally treated by annealing.
The prepared materials were subjected to a detailed thermomechanical
analysis (differential scanning calorimetry, dynamic mechanical analysis,
heat deflection temperature (HDT)), which allowed the formulation
of several conclusions. For all prepared samples, the key changes
in mechanical properties are related to the content of the poly(lactic
acid) crystalline phase, which led to superior properties in annealed
samples. The results also indicate the highly beneficial effect of
increased bed temperature, where the best results were obtained for
the samples printed at 105 °C. Compared to the reference samples
printed at a bed temperature of 60 °C, these samples showed the impact
strength increased by 80% (from 35 to 63 J/m), HDT increased by 20
°C (from 55 to 75 °C), and also a significant increase in
strength and modulus. Scanning electron microscopy observations confirmed
the increased level of diffusion between the individual layers of
the printed filament.
The
research presented in this article discusses the subject of
poly(lactic acid) (PLA) modification via reactive mixing with the
poly(butylene adipate-co-terephthalate) (PBAT) copolymer
for 3D printing applications. Filaments suitable for fused deposition
modeling were prepared from blends of PLA containing 10, 20, and 30%
by weight of PBAT. Mechanical testing clearly indicated that the blending
with PBAT effectively increases the impact strength of PLA, from an
initial value of approximately 30 J/m to more than 700 J/m for the
optimized PLA/PBAT (30%) chain extender-modified blend. The addition
of the multifunctional chain extender (ESA) also has a positive effect
on the rheological profile of the PLA/PBAT materials, which facilitates
both the production process of the extruded filament and the maintenance
of a stable width of the printed material path. Despite the use of
a significant PBAT content, the analysis of thermomechanical properties
did not show any significant deterioration in the thermal resistance
of the materials, while a detailed differential scanning calorimetry
analysis indicates a small tendency to nucleate the PLA structure
by PBAT inclusions. The structural analysis of scanning electron microscopy
clearly indicates a change in the mechanism of deformation from a
brittle fracture for pure PLA to a more favorable shear yielding for
PBAT-rich blends. The comparison of the properties of printed and
injected PLA/PBAT blends indicates the possibility of obtaining similar
or in some respects better mechanical properties, especially for ESA-modified
samples.
The physical properties of biocarbon vary widely with the biomass used, and the temperature and duration of pyrolysis. This study identifies the effects of feedstock characteristics and pyrolysis conditions on the production of biocarbon and the corresponding properties for industrial applications. For coffee chaff and soy hulls, ash content and carbon content increased with pyrolysis temperature and duration. Ash content increased thermal conductivity and specific heat, and decreased electrical conductivity. Change in surface area with pyrolysis conditions was dependent on type of feedstock. Increased surface area corresponded with increased thermal and electrical conductivity. Increased carbon content corresponded with increased graphitization and thermal stability and decreased surface functionality. Properties of soy hull biocarbons were found to be similar to the properties of other biocarbons with industrial applications such as incorporation into polymer composites.
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