Creep characteristics of porous Ni/Ni3Al anodes for molten carbonate fuel cells

Liang

et al. 2015

The effect of porosity on high temperature compression and creep behavior of porous Cu alloy for the new molten carbonate fuel cell anodes was examined. Optical microscopy and scanning electron microscopy were used to investigate and analyze the details of the microstructure and surface deformation. Compression creep tests were utilized to evaluate the mechanical properties of the alloy at 650°C. The compression strength, elastic modulus, and yield stress all increased with the decrease in porosity. Under the same creep stress, the materials with higher porosity exhibited inferior creep resistance and higher steadystate creep rate. The creep behavior has been classified in terms of two stages. The first stage relates to grain rearrangement which results from the destruction of large pores by the applied load. In the second stage, small pores are collapsed by a subsequent sintering process under the load. The main deformation mechanism consists in that several deformation bands generate sequentially under the perpendicular loading, and in these deformation bands the pores are deformed by flattering and collapsing sequentially. On the other hand, the shape of a pore has a severe influence on the creep resistance of the material, i.e. every increase of pore size corresponds to a decrease in creep resistance.

Section: Introductionmentioning

confidence: 99%

Research on high-temperature compression and creep behavior of porous Cu–Ni–Cr alloy for molten carbonate fuel cell anodes

Liang

et al. 2015

“…Due to these concerns, investigations aiming at increasing the heat-resistance of metallic alloys are immediately needed. However, the current studies on MCFC anode materials are mainly aimed at the porous Ni alloy [5][6][7][8][9][10][11][12]. Thus, it is noted that despite the fact that porous Cu alloys are attractive materials for MCFCs, few papers focus on the mechanical properties of porous Cu alloy in high temperatures and only limited data are available in the literature.…”

Section: Introductionmentioning

confidence: 99%

Investigation on the preparation and mechanical properties of porous Cu35Ni15Cr alloy for a molten carbonate fuel cell

et al. 2015

The preparation process of porous Cu35Ni15Cr alloy was studied in this paper. The effect of ball milling time and sintering temperature on the porosity of Cu35Ni15Cr alloy was identified. It was found that 18 h ball milling and 950°C sintering are the most promising parameters for the preparation of porous Cu35Ni15Cr alloy. The products have a ∼62 % porosity. The alloy consists of an α phase and β phase. The influence of deformation temperature and loading rate on the mechanical properties of Cu35Ni15Cr alloys was investigated. The results show that with decreasing deformation temperature, the yield strength and elastic modulus of the porous alloy increase. With the increase of loading rate, the yield strength of these alloys shows an increasing trend, but the elastic modulus is on a steady level.

“…Due to these concerns, investigations aimed at increasing the heat-resistance of metallic alloys are needed. However, the current research on MCFC anode materials is mainly aimed at the porous Ni alloy [5][6][7][8][9][10][11][12], few papers focus on the mechanical properties of porous Cu alloys at high temperatures. Thus, it is noted that, despite the fact that porous Cu alloys are attractive mate-rials for MCFCs, only limited data are available in the literature.…”

Section: Introductionmentioning

confidence: 99%

Investigation on compressive behavior of Cu-35Ni-15Al alloy at high temperatures

et al. 2014

Microstructures and mechanical properties of Cu-35Ni-15Al alloy in cast and porous states were studied by scanning electron microscopy and compression tests. The influence of porosity, deformation temperature and loading rate on mechanical properties of the two kinds of alloys was investigated. The results show that the as cast alloy and porous alloys have almost the same phase constitution: Cu rich phase, Ni rich phase and K intermetallics. The yield strength of porous alloys increases continuously with decreasing porosity, the relationship between porosity and yield stress follows Gibson-Ashby equation. With decreasing deformation temperature, the yield strength of as cast alloy and porous alloy increase. With the increase of loading rate, the yield strength of these alloys shows an increasing trend. After compression, the microstructure of as cast alloy is more uniform, and porous alloys are more prone to have localized deformations.