The mechanical and thermal behavior of ultra-high molecular weight polyethylene (UHMWPE)/metallic quasicrystal powder (MQP) composites are evaluated at filler volume fractions ( ∅ f) of 0.01, 0.02, 0.06 and 0.15. MQP is based on an aluminum alloy, synthesized and characterized to act as a filler for UHMWPE. The preparation of the composites was conducted by compression molding. Morphological analysis reveals larger and smaller MPQ particles, being well distributed, and mechanically anchored in the matrix. The melting temperature was maintained after adding filler, while the crystallinity values decreased. When adding MQP, an improvement in thermal stability is observed by increases in both the initial and maximum weight loss rate temperatures (Tmax). However, when the temperature is about 700°C all composites present oxidation due to the MQP presence. The Pukansky model shows that the 0.06 MQP composites have better interfacial adhesion. This is confirmed by the Nicolais-Narkis equation. This contributes to an increase in the modulus of elasticity of the 0.06 MQP composite in respect to the others. The elongation at break was reduced for the 0.15 MQP composite. However, the higher volume fraction of MQP increased the stiffness of the UHMWPE, reflecting its potential for use as a reinforcement.

Abstract ASTM A 182 F22 steel, used in components subsea for oil extraction, are previously buttered with ductile metal such as Inconel 625, before being welded to steel pipes similar to ASTM A36 steels. The thermal buttering weld cycle provides the formation of high hardness micro-phases and carbides at the interface between F22 steel and the buttering with Inconel, which when in contact with hydrogen, originating from the cathodic protection applied to these equipment, can lead to the embrittlement of this region, causing fragile fractures. In this work, ASTM A 182 F22 steel, buttered with Inconel 625 and welded to A36 steel, submitted to post-weld heat treatment without hydrogenation and subjected to cathodic protection for hydrogen permeation were submitted to fracture toughness test. The welds and buttering were done using GMAW process with AWS ERNiCrMo-3 wire as filler and buttering metal and a mixture of Ar and He as shield gas. The results indicated a 56% of area reduction, and 15% in the elongation values in the tensile tests, in addition to a 13.3% reduction in the CTOD value, for welded joints subjected to hydrogen permeation, which showed a quasi-cleavage fracture mechanism.

RESUMO A exigência contínua de materiais leves e de alto desempenho para as indústrias aeroespaciais e automotivas, levou ao desenvolvimento de materiais compósitos com matriz metálica, destacando-se entre eles, àqueles de base alumínio. Os quasicristais são materiais metálicos com uma estrutura atômica complexa, a qual resulta uma combinação de propriedades físico-mecânicas similares às de algumas cerâmicas frágeis e compostos intermetálicos, como elevada resistência e dureza, elevado módulo de elasticidade, baixo coeficiente de atrito e boa resistência ao desgaste e à corrosão. Essas propriedades são bastante promissoras para aplicação industrial, mas a fragilidade dos quasicristais restringe sua aplicação como fase de reforço em compósitos, podendo substituir os reforços cerâmicos utilizados tradicionalmente, como SiC e Al2O3. No presente trabalho, compósitos de matriz de alumínio reforçado com 2,5%, 5% e 10% em volume de partículas quasicristalinas, foram produzidas através do método de agitação do banho de metal fundido stir casting. Etapas subsequentes de conformação por laminação foram realizadas em todos os compósitos alumínio/quasicrsital. A liga quasicristalina Al61,7Cu25,5Fe12,3Mn0,5 foi obtida via fusão convencional e posterior tratamento térmico. A moagem da liga quasicristalina, para obtenção de pós, foi realizada em moinho de alta energia. A microestrutura dos quasicristais foi investigada através da Difração de Raios-X e da Microscopia Eletrônica de Varredura (MEV). A distribuição das partículas quasicristalinas na matriz de alumínio e a influência na dureza dos compósitos foram investigadas por MEV e Microdureza Vickers, respectivamente. Os compósitos apresentaram uma boa distribuição das partículas quasicristalinas na matriz de alumínio, embora ocorrido em algumas regiões a formação de poros e aglomerados. O processo de laminação promoveu um aumento significativo na dureza em relação aos compósitos obtidos diretamente da fundição.

ABSTRACT The continuous requirement of lightweight and high performance materials for the aerospace and au-tomotive industries led to the development of composite materials with a metallic matrix, among which aluminum-based composites. The quasicrystals are metallic materials with a complex atomic structure, which results in a combination of physico-mechanical properties similar to those of some fragile ceramics and intermetallic compounds, such as high strength and hardness, high modulus of elasticity, low coefficient of friction and good resistance to wear and corrosion. These properties are very promising for industrial application, but the fragility of the quasicrystals restricts their application as a reinforcement phase in composites, and can replace the traditionally used ceramic reinforcements such as SiC and Al2O3. In the present work, reinforced aluminum matrix composites with 2,5%, 5% and 10% volume of quasicrystalline particles were produced by the stir cast method of stir casting. Subsequent steps of laminating were performed on all aluminum / quasicrystals composites. The quasicrystalline Al61,7Cu25,5Fe12,3Mn0,5 alloy was obtained by conventional melting and subsequent heat treatment. The mill of the quasicrystalline alloy, to obtain powders, was carried out in a high-energy mill. The microstructure of quasicrystals was investigated by X-ray Diffraction and Scanning Electron Microscopy (SEM). The distribution of the quasicrystalline particles in the aluminum matrix and the influence on the hardness of the composites were investigated by SEM and Vickers Microhardness, respectively. The composites presented a good distribution of the quasicrystalline particles in the aluminum matrix, although in some regions the formation of pores and agglomerates occurred. The rolling process promoted a significant increase in hardness in relation to the composites obtained directly from the casting.

The formation of brittle microstructures around the fusion line in dissimilar welds has required a deeper microstructural analysis in this region. The study becomes more relevant when these welds are used in environments that facilitate hydrogen embrittlement. The present work aims to characterize the microstructure and hardness at the diluted zone interface in joints welded with dissimilar materials. Aiming for a better efficacy in the microstructural characterization of this zone, samples of both normal cross-section (NCS) and section with slope were used, according to the low-angle microsectioning (LAMS) technique, which allows a greater amplification of partially mixed zones (PMZs). The results indicated the diffusion of carbon from the heat-affected zone (HAZ) towards the fusion line which, in combination with other alloying elements, form highly brittle carbides. In turn, the hardness of the base metal and the HAZ was reduced after post weld heat treatment, whereas in the weld metal an opposite behavior was observed. The dissimilar interface was promising for applications in environments facilitating hydrogen embrittlement, especially regarding the characteristics of zone Φ.