窯業協會誌 73 巻, 837 号

アルカリ鋳込み泥漿の鋳込み性状に及ぼす凝膠剤添加の影響

In order to know the relations between castabilities and rheologcal properties of casting slips, several coagulants were added to the alkaline deflocculated slips. The body used was a typical porcelain body, its calculated mineralogical composition was 53.6% kaolin, 0.8% mica, 20.6% feldspar, and 25.0% quartz, and exchangeable capacity was 4.6m.e./100g. Sodium silicate was used as a deflocculant and the water contents in slips were all 34.7%, selected flocculants were sodium bicarbonate, sodium fluoride, potassium ferrocyanide, sodium citrate, Rochelle salt, chloride of ammonium, magnesium, calcium, manganese, barium, aluminium, and magnesium fluosilicate. The following properties were carried on these slips, i.e. plastic viscosity and Bingham yield value from the slope of the down curve, plasticity ratio (lower yield value/Bingham yield value), rate-on-cast and retained water in cast body; and also an cast bodies, modulus of rupture and apparent porosity.
There was no relations between above-mentioned casting properties and rheological characteristics, but the thixotropic breakdown characteristic of the slip is of considerable importance to the rate-on-cast. Among used coagulants, Rochelle salt is a satisfactory modifying agent, but as the anion takes the major role to castabilities therefore the amount of additions was selected cautiously, many coagulants are useful to the accelerator to the rate-on-cast. The usual control of casting slips is through specific gravity or water content and rheological measurements, but these are inadequate and the working trials to determine casting behavior are very important.

酸化ウラン-酸化トリウム-酸素系の相平衡

The phase study was carried out, in relation to the effective fabrication of the ceramic nuclear fuel of UO₂-ThO₂ system, for obtaining informations of phases present on its sintering or heat treatment in various atmospheres. In addition it is also very interesting that non-stoichionetric UO_2+x and ThO₂ make a non-stoichiometric solid solution U_yTh_1-yO_2+x in various composition.
Ammonia solution was added to the mixed soluton of uranyl nitrate and thorium nitrate to co-precipitate the ammonium diuranate plus thorium hydroxide. The intimate mixture of U₃O₈ and ThO₂ containing a solid solution as starting meterial was obtained by calcination of the co-precipitate in air at 500°-800°C. This powder was pressed to small round pellets which were suspended in the furnace tube to hold at certain constant temperature (700°-1500°C) in an atmosphere (oxygen, air or nitrogen), and then quenched. The specimens obtained were examined with their O/(U+Th) atomic ratio by means of the thermal balance hydrogen reduction, and the phases present by X-ray diffraction analysis.
Fig. 1 shows the variation of O(U+Th) ratio against various temperatures in several atmosheres. Each curve has no break that was seen in the case of UO₂ only. The lattice constants of cubic solutions containing excess oxygen were given in Fig. 2. On these curves the minimum points were obtained. This shows that the lattice parameters of stoichiometric UO₂-ThO₂ solid solution decreased with the O/(U+Th) ratio till the minimum points and then increased again. This fact explains that the non-stoichiometric dissolution of oxygen into lattice made decrease the lattice parameter, reached a saturation, and then the lattice constant of cubic solution increased owing to the increase in thorium content in it by a separation of U₅O₁₃(UO_2.60) phase. In Fig. 3a of X-ray diffraction line intensities of the cubic solution versus O/(U+Th) ratio, an appearance of U₅O₁₃ phase begins above 2.25 of O/(U+Th) and a disappearance of cubic solution at about 2.6 (Fig. 3b).
In order to confirm the limit of disappearance of the cubic solution, the UO₂-ThO₂ compositions rich in UO₂ were examined and the results are shown in Fig. 4. There is no break at 2.60 of O/(U+Th) on the isobaric curve in air for the specimens of 95-5 and 90-10wt.% UO₂-ThO₂, and the X-ray diffraction line intensities of the cubic solid solution almost disappear at 2.64-2.65 of O/(U+Th) passing 2.60. This shows that the terminal composition coexisting with pure thoria without solid solution is found to be UO_2.65.
In the compositions rich in ThO₂(60-90%), the isobaric curves are shown in Fig. 5 for oxygen, air, or nitrogen atmosphere, and the changes of the lattice parameters of cubic solution phase with O/(U+Th) are given in Fig. 6. From the minimum point of each curve, oxygen content of saturation in non stoichiometric solid solution decreases above the 59±1% ThO₂ with increasing in thoria content, and then tends to zero in pure ThO₂. This shows that the terminal composition of U₅O₁₃ phase in equilibrium with ThO₂ or the saturated solid solution in UO_2.65 (Table 1).
The lattice parameters of the non-stoichiometric solution do not satisfy the Vegard rule as shown in Fig. 7. Thus the phase diagram of the UO₂-ThO₂-O system was obtained in the temperature range less than 1500°C, as shown in Fig. 9, and the lattice parameters obtained by using this Figure were compared with the actual data and the agreement was found in the composition range rich in UO₂ (Table 3). The formation of

Ba₂SiO₄の粉末X線回折図への指数配当と原子座標位置の精密決定

The indexing of powder X-ray diffraction patterns and the precise determination of lattice constants and atomic co-ordinates of the synthesized Ba₂SiO₄ were performed using the structure model of β-K₂SO₄. The atomic co-ordinates of each atom in Ba₂SiO₄ was determined by means of trial and error method with IBM 7040 computor.
The results obtained are summarized as follows:
Crystal system Orthorhombic
Lattice constants a=5.772Å, b=10.225Å, c=7.513Å
Space group D_2h¹⁶-P_mcn
Density D_cal.=5.472g/cm³, D_obs.=5.427g/cm³
Molecular number in unit cell z=4
Atomic co-ordinates
The reliability of the calculated intensities about the thirty peaks was 0.171 and the agreement of the thoretical density with observed value was satisfactory, which indicates the above-mentioned indices, lattice constants and atomic co-ordinates are appropriate.