粉体および粉末冶金 56 巻, 2 号

WC-Ni(-P)粉末の放電焼結性と得られた焼結体の摩耗特性

The spark sintering technique was utilized to fabricate WC-16 mass%(Ni-P) compacts with different P contents using two starting powders, Ni plated WC particles by elctroless Ni plating solutions with different P contents and their elementally blended ones. The sintering temperature decreased as P content in Ni binders increased, and all compacts had theoretical densities (13.6-13.9 Mg/m³) under the optimum sintering conditions depending on binder-compositions. The sintered compacts consisted of WC, Ni and Ni₃P phases. Higher P containing alloy fabricated at lower temperature (1150 K), showed theoretical density, compared with that (1273 K) for lower P containing ones. Both uniform deformation of Ni+P binders and a large amount of Ni₃P with low melting point, resulted in excellent sinterability. It was found that noticeable grain growth of WC particles during the spark sintering was not observed and homogeneously sintered structure was obtained, due to pressure application at lower temperature and uniformly Ni plating on WC particles. The compacts produced from the electroless Ni plated WC particles showed higher and no-scatter values on hardness, compared with ones produced by elementally powder blending. The dynamic coefficient of friction showed the same value at initial state, but a little higher value at steady state in higher P containing alloys. Wear loss of alloys increased as Ni₃P contents increased in binder phase, because in addition to wear of WC particles, separation of WC particles was also caused from alloy-structure by failure of binder phases consisting of Ni and Ni₃P due to their brittleness under the wear conditions.

アルミナ焼結体の微小領域における熱浸透率/熱伝導率

Thermal properties of sintered alumina at the micrometer-scale were quantitatively measured with a thermal microscope using thermo-reflectance and periodic heating techniques. The average value of thermal conductivity of 28.9 W·m⁻¹K⁻¹ was obtained from a 50 μm×50 μm area, and the average value was also in good agreement with that measured by a laser flash technique.
The anomalous data were found by the measurement with the thermal microscope in some regions, which were correlated with the surface pores or inside defects of the specimen. The portions with very low thermal conductivities, 5 to 10 W·m⁻¹K⁻¹, were found to correspond to around the pore presents.
In addition, unshared 10 square areas of 10 μm×10 μm were randomly selected and were scanned by an area scanning mode in order to calculate the average conductivities at the areas. The conductivity values were in the range of 24.9 to 37.7 W·m⁻¹K⁻¹ and the variation in the conductivities was estimated about 13 W·m⁻¹K⁻¹. The area with maximum thermal conductivity was consisted of large grains and the value was considered to be almost equal to that of one grain. On the other hand, the area including several small grains indicated the minimum conductivity. The decrease of the conductivity was due to the influence of the grain boundaries.

Sr_1-1.5xLa_xTiO₃の焼結性と電気特性ならびに熱膨張挙動に及ぼすLa置換の影響

SrTiO₃ is one of candidates for interconnect materials of solid oxide fuel cell (SOFC). Sintering behavior, electronic properties and thermal expansion character of A site deficient Sr_1-1.5xLa_xTiO₃ (0≤x≤0.6) were evaluated. Substituted La in the Sr_1-1.5xLa_xTiO₃ played an important role for the grain growth and densification, which were indicated from the microstructure observation and the iso-thermal shrinkage. The conductivity of Sr_0.55La_0.3TiO₃ was 0.17 S/cm at 1173 K in the air and the temperature dependence of conductivity was metal like manner. However, this value was not enough conductivity as the interconnect material of SOFC. In order to apply to SOFC, the conductivity of this material has to be improved. Single phase samples were observed by the powder X-ray diffraction for Sr_1-1.5xLa_xTiO₃ (0≤x≤0.4)which did not have phase transition between room temperature and SOFC operation temperature. The thermal expansion coefficients of these materials were similar to those of the other materials of SOFC. They will be the useful materials for interconnect of SOFC when the conductivity was improved.

LiFePO₄/C複合正極を用いた全固体ポリマーリチウム電池に関する研究

The interfacial resistance between the PEO-Li(CF₃SO₂)₂N electrolyte and the Li_xFePO₄ cathode was examined as a function of the content of Li(CF₃SO₂)₂N in PEO and x in Li_xFePO₄. The interfacial resistances were attributed to two parts; one is the interfacial layer produced between the polymer electrolyte and the cathode, and the other is the charge transfer resistance between the interfacial layer and the electrode. The charge transfer resistance increased with increasing x. No significant dependence of the activation energy for the charge transfer resistance on the salt content in PEO and the molecular weight of PEO were observed.