RESUMO

Flexible films of a conductive polymer nanocomposite-based castor oil polyurethane (PUR), filled with different concentrations of carbon black (CB) nanoparticles or multiwall carbon nanotubes (MWCNTs), were obtained by a casting method. The piezoresistive, electrical, and dielectric properties of the PUR/MWCNT and PUR/CB composites were compared. The dc electrical conductivity of both PUR/MWCNT and PUR/CB nanocomposites exhibited strong dependences on the concentration of conducting nanofillers. Their percolation thresholds were 1.56 and 1.5 mass%, respectively. Above the threshold percolation level, the electrical conductivity value increased from 1.65 × 10-12 for the matrix PUR to 2.3 × 10-3 and 1.24 × 10-5 S/m for PUR/MWCNT and PUR/CB samples, respectively. Due to the better CB dispersion in the PUR matrix, the PUR/CB nanocomposite exhibited a lower percolation threshold value, corroborated by scanning electron microscopy images. The real part of the alternating conductivity of the nanocomposites was in accordance with Jonscher's law, indicating that conduction occurred by hopping between states in the conducting nanofillers. The piezoresistive properties were investigated under tensile cycles. The nanocomposites exhibited piezoresistive responses and, thus, could be used as piezoresistive sensors.

RESUMO

The main objective of this work was to produce and characterize a novel ecofriendly castor oil-based polyurethane (COPU) matrix composite reinforced by Luffa cylindrica mats, luffa for short, to be used as panels, as an alternative to oriented strand board (OSB). To do so, the mechanical behavior was evaluated by tree point flexural, perpendicular o surface tensile, screw pullout, and impact tests that were carried on the novel composite along with the neat matrix. Furthermore, the physical characteristics, the thermomechanical behavior, and the functional groups of the materials were observed by water absorption and thickness swelling tests along with dilatometry and Fourier transform infrared spectroscopy (FTIR). A comparison with commercialized OSB was also performed for control. The luffa/COPU composite was prepared by hand lay-up with 48 vol% of luffa mats incorporated as the maximum allowed by the mold under the available resources for manufacturing. The luffa fibers acted as a good reinforcement for the COPU matrix, where the flexural strength and modulus of elasticity were increased by more than 23 and 10 times, respectively, and the other mechanical properties more than doubled for the composites compared to the neat COPU resin. In general, the composite presented a lower performance compared to the commercial OSB, with the impact results being the exception. The water absorption and thickness swallowing results showed an already-expected behavior for the studied materials, where the better performance was found for the hydrophobic neat resin. The FTIR revealed that there was little interaction between luffa and COPU resin, which can be translated to a weak interface between these materials. However, the mechanical behavior, together with the other results presented by the luffa/COPU composite, confirm it is more than enough to be used as civil construction panels such as OSB.

RESUMO

This study evaluates the hybridization effect of S2-glass/aramid on polyurethane (PU) composites produced by vacuum infusion. Different laminates were produced with similar thickness (around 2.5 mm), using, as reinforcement, only aramid fabrics (five layers, named as K5) or only S2-glass fabrics (eight layers, named as G8). Furthermore, hybridization was obtained by manufacturing symmetrical hybrid inter-ply laminates, with four S2-glass layers and two of aramid, (G2K)S and (KG2)S. The mechanical response of the laminates was evaluated in tensile, interlaminar shear strength, dynamical mechanical analysis and quasi-static indentation tests, and related to their morphological characteristics. The main results show that the pure glass composites presented less voids, but a higher density as well as higher tensile stiffness and strength. The aramid laminates showed a high capability for absorbing impact energy (ca. 30% higher than the pure glass laminates), and the hybrid laminates had intermediate properties. More importantly, this work shows the possibility of using a polyurethane matrix for vacuum infusion processing, effective even for aramid/S2-glass hybrid composites with thermoset polyurethane resin. This study is therefore promising for impact absorption in applications such as protective armor. The studied hybrid laminate may display a suitable set of properties and greater energy absorption capability and penetration resistance for impact applications.

RESUMO

As fraturas em equinos são responsáveis por grande prejuízo financeiro devido às dificuldades encontradas para instituir seu tratamento nessa espécie, principalmente em animais adultos. Entre as dificuldades técnicas no tratamento de fraturas em equinos estão a alta resistência óssea, que acarreta fraturas com grande transmissão de energia, e a escassez de materiais e técnicas de osteossíntese específicos para a espécie, gerando mau prognóstico em muitos casos. [...] O objetivo desse estudo foi avaliar as propriedades biomecânicas de dois biopolímeros a poliuretana de mamona com carbonato de cálcio e uma formulação de quitosana com fosfato de cálcio. Foram preparadas duas formulações diferentes de cada biopolímero, em corpos de prova cilíndricos de 12 mm de comprimento e 6 mm de diâmetro, sendo: poliuretana de mamona porosa e compacta, e quitosana com secagem a 38 e 60 graus Celsius. Essas formulações foram submetidas a ensaios compressivos nos momentos 3, 24, 48 e 72 horas após o preparo e avaliadas quanto sua resistência à compressão, deformação relativa e módulo de elasticidade. A poliuretana de mamona compacta apresentou o maior valor de resistência à compressão (45,805 N/mm2) após 48 horas. A fórmula de quitosana com secagem a 38oC apresentou a menor deformação relativa (3,952 %) após 72 horas de preparo e o maior valor de módulo de elasticidade encontrado foi na poliuretana de mamona compacta após 72 horas (1354,284 N/mm2). Sendo assim a poliuretana de mamona compacta apresenta maior resistência à compressão do que o osso esponjoso de terceiro metacarpiano equino e semelhante aos substitutos ósseos comerciais mais resistentes. A fórmula de quitosana 38oC apresentou valores similares aos observados no osso esponjoso equino. Podemos concluir com esses dados que a poliuretana de mamona compacta e a fórmula de quitosana 38oC apresentam características biomecânicas desejáveis nos materiais para enxerto ósseo

Equine fractures are responsible for great economic losses due to difficulties in establishing their treatment, mainly regarding adult animals. Among technical difficulties faced in the equine fractures treatment, there are high bone strenght, which results in high energy fractures and the lack of materials and specific osteosynthesis techniques for the specimen, resulting bad prognostic in many cases. [...] The target of this study was to evaluate biomechanic properties of two biopolymers, a castor oil polyurethane with calcium carbonate and a formulation of chitosan with calcium phosphate. Two different formulations of each biopolymer were prepared, in cilindric parts of 12mm lenght and 6mm diameter: porous and compact castor oil polyurethane, and chitosan drying at 38oC and 60oC. These formulations were submitted to compressed tests at 3, 24 and 72 hours after preparation and evaluated for compressive strenght, relative deformation and modulus of elasticity. The compact castor oil polyurethane presented greater compressive value (45,805 N/mm2) after 48 hours. Chitosan formulation drying at 38oC presented lower relative deformation (3,952%) 72 hours after prepared, and the highest value for modulus of elasticity found was compact castor oil polyurethane after 72 hours (1354,284 N/mm2). Thus, compact castor oil polyurethane presents higher compressive strenght than trabecular bone of the third equine metacarpal and similar to strenghter comercial bone grafts. The formulation chitosan 38oC presented similar values to those observed in equine trabecular bone. With these data, we can conclude that the compact castor oil polyurethane and the formulation of chitosan 38oC present desirable biomechanic characteristics in materials for bone grafts

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