窯業協會誌 66 巻, 747 号

アルミナ系サーメットにおける配合金属の選択について

The factors for the selections of metals to be added to alumina were discussed after the fabrication experiments were described. Since thirteen metals given at Table 2 could be added as metal components in the cermets, all of these metals, their mixtures and industrial ferro-alloys were used in experiments. The mixing of metal and alumina components were made in small steel mill using tungsten carbide balls and methanol for 15-20 hours. The mixed batches were pressed under 1000Kg/cm² to 4×12×68mm. bars, and were sintered for 1 hour in the molybdenum furnace in the atomosphere of hydrogen dried by P₂O₅.
The results of sintering experiments were summerized in Table 4 and 5 where composition, sintering temperature, shrinkage, bulk density, water absorption, and transverse strength at room temperature and at 1000°C in air are listed. Contact angles of molten metals on alumina supports were measured at room temperature and listed in Table 6. From these, experiments, the following results were obtained; The cermets containing Sn, Al, Ag, Cu, Mn, and Si were impossible to sinter. Al, Mn, Si, and Ti metals were partially oxidized in this atmosphere. Strengths at room themperature increased in the order of Ni, Co, Fe, Cr, this order being also that of the decrease of contact angle values (except of Co), while the 1000°C-strength was supposed to be related to the oxidation resistance of metals. Tungsten and molybdenum were oxidized and sublimed at the 1000°C-tests. The strength of alumina-chromium or alumina-chromium alloy cermets were generally high, and this might be related to small contact angles of Cr or Cr-alloy.
Two groups of factors are considered to raise the strength of cermet. These are (1) the factors to promote sintering and (2) the factors concerning to the good texture of sintered body. The former factors are; particle size and crystal grade of original materials, the slight oxidation of metal by oxygen component in the sintering atmosphere and by reaction with alumina, and contact angle and surface tension of metals; and the latter factors are the strength and the microstructure of oxide phase, metal phase, and boundary phase. The strength of boundary phase between metal and oxide is related to physical adherence and the difference in thermal expansion coefficients between oxide and metal phase. It is apparent from the above two factors that iron or chromium metal and these alloys have suitable qualities to be added to alumina.
It is considered that the different sintering atmospheres, especially some changes in oxygen content in hydrogen atmosphere, may be required for the respective metals, and these contents may be approximately the same as those in the oxidation and reduction equilibrium of metals calculated from their free energy values. The abrupt adsorption and desorption of hydrogen at temperatures of phase transformation of metals may have also an important effect on the boundary adherence. The presence of carbon in a hydrogen furnace causes the carbide formation in Cr, Mo and W metals through CO gas, and the formation of Al metal, carbide and oxycarbide by contact with alumina, finally the formation of the AlO and Al₂O vapors. The reactivity of metals with alumina to produce AlO and Al₂O increases in the order of Ni, Co, Fe, Cr with relation to the smaller contact angles. Ti has a great reactivity with alumina. The water vapor pressure inhydrogen, calculated by using the oxidation and reduction equilibrium of metal-alumina compound (for instance, spinell) is generally lower than those calculated similarly with metals alone. It is, therefore, thaught from these results that the vapor pressure of water actually present in hydrogen is perhaps less than the calculated value (Table 7) from metals only. (Rf. This Journal, 64, 183 (1956)

チタン酸バリウム磁器の焼結, 特に高温度におけるCO₂の放出過程について

In the previous paper, the author reported on the sintering phenomenon of Barium Titanate ceramics, especially their expansion and shrinkage characteristics during the firing process. This time, in order to find out the best firing condition of Barium Titanate ceramics, the decomposition curve of BaCO₃ at high temperature was measured. The method of measurement was to observe the change in the weight of test pieces continuously as a function of both temperature and time over the temperature range from room temperature to 1300°C, using a thermo-balance with strain meter. The results obtained are summarized as follows.
(1) In the firing process of Barium Titanate, the libration of CO₂ occurred over a temperature range from 600°C to 1100°C. It was made clear experimentally that the abnormal expansion phenomenon reported in the previous paper occurred when the escaping speed of CO₂ exceeded 0.1cm³/sec per unit volume of sample.
(2) In the reaction of decomposition librating CO₂ at constant temperature, Jander's equation has been valid exactly. Applying these results, the activation energy of reaction was calculated to be 73kcal/mol. Futhermore, applying this value, it was found that at a certain rate of temperature raising the calculated decomposition curve of BaCO₃ coincided with experimental curve.
(3) By adding clay to a few weight percent, the activation energy of reaction increased slightly and shrinkage reaction at higher temperature was accelerated considerably.
(4) If the raising of temperature was kept at a rate of 0.8-12°C/min in the firing process, it was possible to avoid radical abnormal expansion phenomenon. Furthemore, by the experiments on frequency constant for radial mode vibration, residual polarization and so on it was made clear that the sample prepared under such condition showed excellent electrical and acoustic properties.
(5) The thermo-balance with strain meter was very convenient for such an investigation as this, because it was possible to record the change of weight automatically within a limit of 1 milli-gram error.

各種セメントの性能に及ぼす軽焼マグネシアの影響

ポルトランドセメントや高炉セメントに軽焼マグネシアを添加すると凝結はやや遅れ, フローを低下し, 強度を減ずる. 水和膨脹を増し, 乾燥収縮をやや減ずる.
高硫酸塩スラグセメントのアルカリ刺激剤として軽焼マグネシアを単独で用いると, 初期強度が低いが長期強度は大きい. 水和熱は著しく低く, 7日42, 28日58cal/gに過ぎない. ただし収縮量はやや大きい. ポルトランドセメントクリンカーを刺激剤とするものはフローが大で初期強度も良い. クリンカー量が増すにしたがい凝結は促進され, 適量値を越すと強度を低下する. クリンカー量を増してもオートクレーブ膨脹はあまり高まらず, 水和膨脹はやや増しそめ後め乾燥収縮を相殺する. グリンカーを加えさらにマグネジアを加えて行くと凝結はほとんど変らず, フローを低下し, オートクレーブ膨脹と水和膨脹を著しく増ず. しかしマグネシアがある限度を越すと収縮も著しくなる.