粉体および粉末冶金 28 巻, 7 号

表面処理微紛体の濡れと表面エネルギー

When the hydrophobic fine powders were dosed into water, they spread over the water surface as an oil does, whereas they were easily dispersed into acetone. These hydrophobic fine powders were dosed into the aqueous acetone solutions with several concentrations, and the surface tensions of them were the values between that of water and acetone. The surface tension of the solutions into which the powders easily dispersed was determined. The surface energy of these powders was estimated from the thermodynamic consideration on the interface between powder and solution. The surface energy was also estimated for the powders which were easily dispersed into water, whereas they were collected into the interface between water and hexane after adding the hexane to these aqueous suspensions and shaking these suspensions.

Kinetics and Mechanism of the Reaction between Lithium Carbonate and Silica

The reaction of equimolar mixtures between Li₂CO₃ and amorphous SiO₂ has been studied by means of DTA, X-ray diffraction and thermogravimetric techniques. The reaction was found to proceed in seven stages: Li₂CO₃+SiO₂(amorphous)→Li₂O⋅SiO₂+CO₂ (1)
Li₂CO₃+2SiO₂(amorphous)→Li₂O⋅2SiO₂+CO₂ (2)
2Li₂CO₃+SiO₂ (amorphous)→2Li₂O⋅SiO₂+2CO₂ (3)
Li₂CO₃+Li₂O⋅2SiO₂→2(Li₂O⋅SiO₂)+CO₂ (4)
2Li₂O⋅SiO₂+SiO₂(quartz, cristobalite)→2(Li₂O⋅SiO₂) (5)
2Li₂O⋅SiO₂→Li₂O⋅SiO₂+liquid (6)
Li₂O⋅2SiO₂→Li₂O⋅SiO₂+liquid (7)
The main part of the overall reaction concerning with the decomposition of Li₂CO₃ was best expressed by the contracting cube equation and the apparent activation energy was determined as 36.3 kcal/mol. This activation energy can be assigned to the overall reaction (1)-(3).

化学蒸着法による被覆WC-Co超硬合金の強度低下

The transverse-rupture strength of WC-(5.5-20)%Co alloys coated with titanium carbide by CVD was studied to make clear the cause of the strength decrease of those alloys.
It was found that the strength of coated alloys is controlled by the total thickness of coated layer and the layer containing η-phase, in accordance with the result of Stjernberg. Therefore, it is considered that the strength decrease is unavoidable. Some discussions to check the strength decrease have been given.

窒素を含むWC-β-Ni超硬合金の諸性質

The transverse-rupture strength of WC-β-Ni alloy (β; WC-TiC solid solution) having nitrogen, which was prepared by using WC-TiC-TiN solid solution or TiN powder, was mainly studied at room temperature. The alloy was vacuum-sintered at 1693K.
It was found that the strength of nitrogen contained alloy was apt to decrease, owing to the pore formation during sintering; However, after eliminating the pore by HIP, it became superior, in particular in the alloy prepared by using solid solution powder, to that of the nitrogen free alloy, resulting from the sharp refinement of carbonitride grains.

TiB₂-TaB₂基サーメットの機械的性質に及ぼす結合剤の影響

This paper describes, firstly, the effects of the sintering temperature on the mechanical properties of TiB₂-5%TaB₂-1%CoB, TiB₂-5%TaB₂-1%NiB, TiB₂-5%TaB₂-1%FeB and TiB₂-5%TaB₂-1%Co alloys; secondary, the effects of the amount of binders on those of TiB₂-5%TaB₂-CoB, TiB₂-5%TaB₂-NiB and TiB₂-5%TaB₂-FeB alloys. The results were as follows:
1. CoB was the best binder for TiB₂-TaB₂ based cermets. The TiB₂-5%TaB₂-1%CoB alloys sintered at the temperature of 1700 to 1900°C for 28 min under 200 kg/mm² in a vacuum had the transverse rupture strength of 95 kg/mm², and scarcely had pores.
2. In the cases of CoB, NiB and FeB binders, TiB₂-TaB₂ based cermets had a solid solution between TiB₂ and TaB₂. However, TiB₂-5%TaB₂-1%Co sintered body scarcely had the solid solution between TiB₂ and TaB₂.
3. The binder phases of TiB₂-5%TaB₂-1%CoB alloy and TiB₂-5%TaB₂-1%FeB alloy may be CoB and FeB, respectively. The binder phases of TiB₂-5%TaB₂-1%NiB alloy may consist of NiB and monoclinic Ni₄B₃ and unknown phases. Also TiB₂-5%TaB₂-1% CoB alloy may have the binder phases of CoB and Co₂B.