Tetsu-to-Hagane Volume 25, Issue 2

THE EFFECT OF COLUMBIUM ON THE PROPERTIES OF AN 18/8 STEEL.

The author studied the effects of Cb on the physical, mechanical and chemical properties of an 18/8 steel, and the results obtained are compared with those of Ti.
The compositions of the samples are as follow:-
From the experiments, it is concluded that the quantitys of Cb which is necessary for eliminating intergranular susceptibility of 18/8 steel, is more than five times the C content, and within such content, Cb reduces more or less the corrosion resistance of 18/8 steel to some corroding mediums, but it has far less effect on the physical and mechanical properties of 18/8 steel when compared with Ti used for the same purpose.

TREND OF THE STUDY ON THE ABRASION OF METALS.

With the progress in the research on the wear by abrasion testing machines, it has become clear that varied experimental conditions have abnormal influence on the wear, the factors such as sliding speed, contact pressure, oxidation, surface temperature, surface smoothness, etc. being of prime importance.
It is lately cosidered, that the best way for solving the problem of abrasion is in the study of its mechanism. In this paper, the author trys to explain the factors influencing on the abrasion which have become clear until today, and he points out the trend of the research on this line.

NOTES ON THE FLAW OCCURING IN AXLE MATERIAL.

Among axles produced by forging shops of the Yawata Iron Works in Japan where axles for trains and tram cars are manufactured, defective axles to be rejected owing to the flaw amount to the quantity which corresponds to the production of about one month against the total annual production. Under such circumstances, the author investigated processes which may improve the results with respect to the following items:-
A. Axles rejected from the flaw in the light of statistics.
B. Kinds of flaw
C. States of flaw
D. Causes of flaw and its remedies.

X-RAY STUDIES ON THE ANNEALING AND DIFFUSION IN ALUMINIUM ALLOYS.

Problems relating to the annealing of cast Al-alloys and diffusoin in super-duralclad plate were studied by X-ray focussing method using Cu Ka radiation. When chill cast Al -alloy containing 4% Cu is gradually heated, the lattice constant becomes large at first and then small, and finally reaches a constant value at about 500°C. These changes correspond to the changes appeared in the dilatometric curve. The time required to obtain, as the value of the lattice constant, by heating at 500°C the mean of initial and final values about 0·4hrs. These values become large by the addition of Mg: such as 0·5, 1·1 and 1·9hrs for 0·5, 1·0 and 1·5% Mg respectively.
The inner part of the super-duralclad plate becomes uniform when annealed several hours at 500°C, but the surface layer does not become uniform and the values of its lattice constant are quite irregular even after being heated for 50hrs. Also, broadening of (511) line of the surface layer begins at about 10hrs and reaches the final value at about 20hrs. Above results show that the diffusion does not take place uniformly and, in the surface layer, non-uniformness becomes noticable by annealing.

THE INFLUENCE OF CHROMIUM UPON THE OXIDIZING PROPERTY OF TUNGSTEN AT HIGH TEMPERATURES.

As is well known, tungsten has the highest melting point among the metals known at present and is one of the metals having the highest tensile strength at high temperatures. It is, however, one of the most oxidizing metals at high temperatures, in the presence of air. The authors attempt here to investigate the influence of chromium added to tungsten upon the improvement of the properties of this material and the removal of the defect.
The preparation of the W-Cr alloys was the most difficult task. Many attempts for the preparation of samples by sintering powdered tungsten and chromium had failed, but finally it was succeeded with the thermit process.
In Table 2, the compositions of the samples by chemical analysis are given. It will be seen that a certain amount of aluminium, say 5 percent, is always present as a result of the preparation by the thermit process. In this paper, the W-Cr equilibrium diagram is first dealt with. In Sargent's paper, the existence of W₇Cr₃, WCr₃ and WCr₇ is proposed, but it appears to the authors that there is no other literature regarding the W-Cr equilibrium diagram.
In the present research on the diagram, the melting temperatures, microscopic structures, X ray analyses and hardness were investigded in order.
The melting temperatures of the samples were too high to be determined by the ordinary laboratory method. As a result of the observation of the microscopic structures of the samples in the state as cast and annealed at 1200°C for a long duration, the aggregation of the small particles are seen. These structures differ considerably from those which appear in the samples prepared by the ordinary melting process, but they are nearly the same as in the samples containing chromium of from zero to 400/8 in atomic percentage. The X-ray analyses were made by the reflection method, and as is shown in Fig. 3, and Fig. 5, it was found that a solid solution of chromium exists in tungsten in a range from zero to about 26% of Cr, and a solution of tungsten exists in chromium from zero to about 32% of W. The result of the hardness tests is shown in Fig. 4. This curve indicates that the hardness of the samples rapidly increases as the percentage of chromium in tungsten increases, but the maximum point of the hardness in the curve is somewhat shifted towards the lower chromium side from the limit of the solid solution on chromium in tungsten obtained by the X-ray analyses. In this paper, however, the result of the X-ray analyses is adopted for the solid solution range of chromium in tungsten. Anyhow, the existence of some solid solution ranges in the W-Cr binary alloys is certain notwithstanding Sargent's proposition refered above. The authors consider that Fig. 5 is a portion of the supposed W-Cr equilibrium diagram. From the above investigations, the fact of the existence of the solid solution of chromium in the W-Cr alloys is presumable, and also the high resistance to oxidation at high temperatures in the presence of air of the solid solution containing chromium. Therefore, oxidizing tests at 900°C were carried out for the prepared samples, the results being shown in Fig. 6. From this curve, the oxidizing property of tungsten at high temperatures is found to be greatly improved by adding about 13 percent of chromium to tungsten.