Study on the Distribution of Hydrothermal Alteratio...

Jo Dec 20, 2024

Research for new deposits using the satellite image analysis method has already been carried out by many previous researchers. Studies to predict mineral prospecting sites by satellite image analysis have been mostly conducted to identify mineralized alteration zones and to detect linear structures.

Satellite image analysis generally begins with remote sensing. The integrated data is prepared for the user. In this stage, the integrated data is interpreted by various methods. In data interpretation, images are interpreted to identify various phenomena with regard to their importance.

It is widely accepted that hydrothermal alteration plays an important role in ore formation. The desirable distribution of alteration zones around the limited borders of an ore body facilitates outdoor exploration activities. Generally, hydrothermal alteration processes lead to emanation of clay and other silicate minerals, including kaolinite, sericite, quartz, chlorite, epidote, and calcite. The application of both spectral and statistical analyses of remotely sensed data can identify the above-mentioned minerals and explore the buried deposits. Hydrothermal alteration zones can be recognized from the spectral characteristics of main mineral assemblages.

Based on the spectral characteristics of main mineral assemblages, Ra Chung Yol, a section head at the Faculty of Earth Science and Technology, has determined the distribution of the hydrothermal alteration zone in the study area, using band-ratio analysis, principal component analysis, and colorimetric synthesis methods.

He has concluded that the hydrothermal alteration zone in the study area was widely distributed over an area of 2 000m×200m above the surface under the control of the ore-bringer structure, especially at the contact with the alkaline rock mass.

Energy Saving of Hybrid Displacement Ventilation Sy...

Jo Dec 19, 2024

A large amount of energy is consumed for buildings around the world, and therefore, energy saving is being studied extensively.

Mixing ventilation system (MVS) is one of the mechanical ventilation systems that makes the entire indoor air mixed completely using the jet flow made from blast air. Displacement ventilation system (DVS) is one of the mechanical ventilation systems, which blows air with lower temperature than indoor air into the lower part of a room and causes upward flow of indoor air by buoyant force to exhaust it at the ceiling.

The basic difference between DVS and MVS is that DVS mainly relies on the buoyancy effect, while MVS uses mechanical ventilation force. As DVS is aimed at only meeting the requirements of the workplace, there is a thermal and concentration stratification between the lower and upper parts. DVS is characterized by good air quality, efficient emission of polluted air and significant energy saving effect. In the design of DVS, the height of thermodynamic stratification has to be set to be higher than the height of the workplace, but not too high, because it might cause waste and increase in the amount of air blast. So, the determination of the height of thermodynamic stratification is one of the vital problems arising in the application of DVS. In DVS, ventilation volume for keeping the temperature below the required level is too much when the cooling load is heavy. For DVS, experiments, experiences and engineering design methods have already been presented and mathematical analysis methods have been studied. However, there is little data about DVS for high-ceiling rooms.

Paek Myong Chol, a section head at the Faculty of Heat Engineering, has investigated the temperature change at the workplace when there is heat source in MVS and HDVS with the vertical supply duct by using CFD and presented its effectiveness. In addition, he has verified the existence of the effective length of the vertical supply duct in HDVS with supply ducts from the view of energy saving.

He has found that under the conditions of providing equal temperature and velocity of air inflow, the temperature of the air in the working zone depends on the length of a vertical supply duct, and that the temperature of the air in the working zone increases when the vertical supply duct is longer than the limited value.

Whole Space Modeling of Polarizable Layered Earth

Jo Dec 17, 2024

In general, in the electromagnetic surveying, frequency dispersion of conductivity is neglected. In contrast, in the common excited polarization method, current is indirectly supplied to the underground, so the secondary voltage originated by ramp turn off in the current flow is actually frequency dispersion of conductivity. Hence, electromagnetic (EM) effect and induced polarization (IP) effect come into being at the same time, which leads to distortion, in other words, sign reversal of EM response. For this reason, many researchers deeply studied the mechanism of the sign reversal and the forward modeling in consideration of this phenomenon.

Many researchers simulated the distorted transient response by conductivity related to frequency. Most of the research results concluded that Cole-Cole model is well suited to considering IP effect observed in TDEM.

Transient response of polarizable whole space is surely different from both polarizable half space response and non-polarizable whole space response.

Jon Kwang Bok, a researcher at the Faculty of Earth Science and Engineering, has approximated the whole space electromagnetic transient field originated by rectangular loop in the whole layered space which includes polarizable layers by using the Cole-Cole model and linear digital filtering method.

As a result, he has drawn two conclusions.

First, induced voltage measured has no relationship with whether the polarizable conductive layers are above or below the measurement spot. Second, polarization must be considered in the whole space inversion as in half space because the response computed by common whole space modeling method is a lot different from that by polarizable whole space modeling method.