Jo May 5, 2024
The crater of Mt Paektu full of mysteries gives a view of extraordinary falls, too.
In the rainy season, the cliffs of the crater are covered with falling water, forming crater waterfalls. When a strong northwesterly wind blows up the slopes of the crater, it changes the downward flow into “upward waterfalls” like spout from a fountain. These extraordinary “upward waterfalls” are seen in the spring thaw from May to June and in the rain spell from July to August.
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Jo May 3, 2024
PhD. Associate Prof. Kwon Chang Dok, a section head at the Faculty of Mining Engineering, is a competent scientist who has made a distinguished contribution to the agricultural development of the country and to the improvement of the people’s living standard. Having developed a paddy rice cultivation method by electrical pulse water treatment, he has introduced and generalized it to a huge number of farms across the country in the last nine years.
Finding that the water treatment technology highly effective in floatation and leaching of nonferrous mineral significantly influences the growth of animals and plants by activating water, he started research for introducing it to stockbreeding, fish farming and vegetable farming followed by paddy rice farming. Starting from a 500-phyong (1 phyong = 3.954 sq. yds) test rice field, he rapidly expanded the area year by year. As a result, he made proud successes of increased yield of a huge amount of rice in a hundred thousand jongbo (1 jongbo = 2.451 acres) of paddy-fields in 2023.
In the course of making a lot of scientific research successes, he was highly appreciated by Chairman
During those days, he moved into a new flat in Kyongru-dong in April, 2022, and he had the greatest honor of having a significant photo session with the respected Comrade
Now he is full of enthusiasm to devote all his talent, wisdom and passion to open up a breakthrough for the economic development of the country with torchlight of science and technology, bearing in mind the trust and expectation of the Party and the fatherland that put him forward as a state top-honor scientist & technician.
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Jo Apr 29, 2024
Investment casting is widely used to make complex castings with high dimensional accuracy at low cost. The impellers of centrifugal pumps have many thin-walled regions and structures of uneven thickness in parts, so shrinkage defects can occur in these areas.
Also, their complex internal cavities cause excessive variations in the velocities of molten metal flowing into the shell mold. This results in gas and non-metal inclusion defects in castings. Therefore, it is important to avoid these casting defects occurring in investment casting of impellers.
Kim Yu Chol, a section head at the Faculty of Materials Science and Technology, has succeeded in making centrifugal pump impellers with no defects by optimal design of runner/riser system and mold tilt angle with ProCast software, thus enhancing the quality of castings and reducing production hours. The sprue was used as a kind of riser to feed shrinkage of casting and enhance casting yield. The shell mold was tilted at various tilt angles to eliminate gas and inclusions during pouring.
You can find the details in his paper “Improvement of quality and yield for investment casting of centrifugal pump impeller by tilting mold and optimizing runner/riser system” in “The International Journal of Advanced Manufacturing Technology” (SCI).
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Jo Apr 26, 2024
Preparation of copper nanoparticles have depended on liquid-phase reduction, where copper sulfate as raw material is dissolved in deionized water and a certain amount of dispersant is added before they were heated under stirring to reach reduction reaction temperature and reducing agent is dropped and mixed to produce copper nanoparticles.
Then, mixing reducing agents takes long while the reduction rate of copper ions is very fast (reduction reaction is already initiated before required amount of reducing agent is mixed). This results in non-uniform nucleation-crystalline growth, thus copper nanoparticles unhomogeneous in size being obtained.
After the reduction reaction, the copper nanoparticles dispersed in liquid phase are separated from the liquid phase using a high-speed centrifuge, which are diluted again in deionized water, and centrifugation washing process is repeated several times, so oxidation by atmospheric oxygen is easily achieved.
Kim Song Chol, a researcher at the Faculty of Materials Science and Technology, prepared relatively uniform-size copper nanoparticles by thoroughly mixing the reactants (copper salt solution + reducing agent solution) at room temperature in the liquid-phase reduction process (based on the fact that reduction reaction never occurs even when copper sulfate aqueous solution and reducing agent solution are mixed below 40ºC) and heating to the reaction temperature under stirring, allowing simultaneous and homogeneous nucleation of crystalline nuclei to be formed in the reaction system.
In addition, he realized separation and wash of produced copper nanoparticles from aqueous solution without a centrifuge, and instead introduced volatile organic solvent into reaction system to encapsulate the produced copper nanoparticles. By doing so, he ensured their surfaces are protected as soon as the copper nanoparticles are produced, and also simplified the separation and washing process.
The proposed technique can reduce the production cost of copper nanoparticles and increase the rate of recovery, particle size homogeneity and oxidation stability. In addition, it is a great potential for practical applications as producing copper nanoparticles as there is no need for expensive high-speed centrifuges. It is also useful for mass production of copper nanoparticles as lubricating oil additives.
You can find more information in his paper “A new method to improve homogeneity and oxidation stability of Cu nanoparticles for lubricant additive in liquid phase reduction process” in “ Materials Research Express ” (SCI).
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Jo Apr 24, 2024
Generally, less active metals (Cu, Ni, Zn…) are electrolyzed in aqueous liquid, but highly active metals such as rare earth elements and light metals are not. This is because hydrogen is gassed on electrode before deposition of metal in aqueous solution. Electrodeposition of rare earth elements is only possible by fused salt electrolysis at high temperature. Therefore, researchers have studied electrodeposition of one or two rare earth elements in molten salts and special organic solvents.
One of the major advantages of ionic liquids in electrodeposition is that electrochemical processes are carried out at low temperatures close to room temperature. This can reduce the energy loss of electrochemical processes that must be carried out at high temperatures. Therefore, some researchers have used various ionic liquids for electrodeposition of various active metallic elements at low temperatures. However, the liquids are highly hygroscopic and thus, an inert gas-filled space must be provided to prevent moisture for the elctrodeposition, which makes them difficult to be applied to industrial applications.
Use of 1-ethyl-3-methyl-imidazolium fluoroborate (EMIMBF4) ionic liquids has the potential for electrolysis of rare earth elements with no special conditions.
An Hyo Song, a researcher at the General Assay Office, has proposed a new method for the co-electrodeposition of dysprosium and terbium using EMIMBF4 ionic liquid.
The experiments demonstrated that the electrodeposition of dysprosium and terbium ions in EMIMBF4 ionic liquids is an irreversible and simultaneous process. He used the measured data to ensure that the electrolyte composition and diffusivity are reasonable, and newly determined the kinetic diffusion coefficients of these chemical reactions from cyclic voltammetric and chronoamperometric analyses.
For more information, please refer to his paper “ Simultaneous electrodeposition behavior of dysprosium and terbium in 1-ethyl-3-methyl-imidazolium tetrafluoroborate ionic liquid” in “ Journal of the Indian Chemistry Society” (SCI).
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Jo Apr 23, 2024
300M steel is a typical ultra-high strength steel with very high strength, excellent fracture toughness, good fatigue strength and stress corrosion resistance, and thus it has found expansive applications in the manufacture of key components of military and civil aircrafts.
300M steel can be formed into complex-shaped parts such as landing gears which are one of the four core components of aircraft, as well as into sheet or rod. However, deformation of 300M steel should be performed at elevated temperatures because of its high strength and limited ductility.
In recent years, some scholars have established constitutive models to predict the hot deformation behavior in ultra-high strength steels. Unfortunately, few studies on phenomenological models for 300M steel have been conducted or reported, except for the AT model.
Sim Kyong Ho, a researcher at the Faculty of Materials Science and Technology, has developed and improved sc-AT, m-JC and KHL models to describe the hot deformation behavior of 300M ultra-high strength steel.
First, he conducted isothermal uniaxial compression tests under various thermo-mechanical processing conditions.
Second, by using the experimental data, he developed the AT, m-JC and KHL models for 300M steel, and evaluated the predictability of the models.
Based on the analysis of the cause of large deviation, he further improved the m-JC and KHL models, and verified the prediction accuracy of the five constitutive models by using standard statistical parameters.
He drew the following conclusions.
The m-JC and KHL models show relatively good predictability at the reference conditions. The sc-AT model exhibits the highest R2 value of 0.9971 and the lowest AARE value of 3.57 %. In view of the prediction accuracy and computation complexity, the improved versions of m-JC and KHL models are preferred models among the phenomenological constitutive models he studied.
The details are found in his paper “Development and Improvement of Several Phenomenological Constitutive Models for Thermo-mechanical Processing of 300M Ultra-high Strength Steel” in “Journal of Materials Engineering and Performance” (SCI).
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