Determination of Critical Velocity of Gravity Corer...

Jo Sep 16, 2025

In order to actively develop marine resources for sustainable economic development, it is necessary to identify the types, distribution locations and reserves of seabed mineral resources. All seabed work is impossible without seabed sample exploration, whether it is a study of seabed geological structure or seabed resource exploration.

Ri Jong Chol, a researcher at the Faculty of Shipbuilding and Ocean Engineering, has designed a gravity corer with a spring release mechanism for re-identification of a seabed phosphorite distribution area, and determined the critical velocity before the free fall of the corer designed for sample seabed phosphorites at the depths of 1 000-2 000m.

He has found that the range of critical velocity increases with the increase in the mass of the corer and the decrease in the stiffness of the spring, and that it decreases with the length of a lever arm.

Optimization of Risers for Pelton Turbine Blade Cas...

Jo Sep 15, 2025

Calculation of riser for steel casting is more important than that for other alloy castings because of the high shrinkage and pouring temperature of cast steels, which leads to severe shrinkage defects.

Among the different calculation methods, the cubic equation method can be used to calculate the shape and dimensions of riser in parametric forms, but it is not widely used due to the large computational amount.

Numerical simulations of the solidification process of cast are more and more used in the design of casting process because of the economy of time and effort as well as the increased accuracy. Many researchers have studied the process of the flow and solidification processes of castings using ProCAST. Most of them, however, found the optimum values by constructing initial design schemes and repeating simulations and modifications. Also, the inclusion of excess mass in the riser is unavoidable, which reduces casting yield.

Hence, it is necessary to establish a methodology to determine the optimum size of the riser while saving the time for simulations.

Ri Hak Song, a researcher at the Faculty of Materials Science and Technology, has set the hydro-powered Pelton turbine blade casting as the main research project, and optimized the riser by combining the numerical simulation analysis by ProCAST with the cubic equation method.

He performed a calculation of the riser by the cubic method and a numerical simulation by ProCAST, a simulation tool for casting processes, to identify the most suitable riser.

The results of the study show that the yield of riser calculated by the cubic method does not differ significantly with the change in the shape of riser, but the elliptical shape is the optimum shape of the riser, with the ratio of height to width of 1.3 and the yield of riser of 67.5%.

Numerical Simulation of Ozone Gas Inhalation Accord...

Jo Sep 14, 2025

Ozone water is made by dissolving into water the gaseous ozone generated during the discharge of oxygen or air or the electrolysis of water.

There are several methods for ozone water production from generated ozone gas, such as porous, bubble tower, U-tube, spray tower, Venturi tube, etc. Among them, venturi-based ozone mixers are widely used, due to their excellent features such as cost, performance, installation area, power consumption, etc.

One of the important ways to increase the concentration of ozone water in the venturi ozone mixer is to increase the amount of ozone gas inhalation into the gas intake. Previous studies only considered the pressure change or velocity change inside the venturi, but not much work has been done on the inhalation volume at the intake.

Rim Chol Bom, a researcher at the Institute of Nano Science and Technology, has determined the optimum geometry of a venturi tube for ozone water production through computational fluid dynamics (CFD) simulations.

The numerical results are inlet diameter of 40mm, throat diameter of 12mm, converging angle of 27° and gas inlet diameter of 7mm, with inhalation rate of 0.100 6g/s.