PROFESSOR
Prof. Seungwon Shin
Mechancial and System Design Engineering
Hongik University
72-1, Sangsu-dong, Mapo-gu
Seoul, 127-791, Korea
Email: sshin@hongik_dot_ac_dot_kr
EDUCATION
Ph.D Mechanical Engineering (2002), Georgia Institute of Technology.
(Level Contour Reconstruction method for three-dimensional multiphase flows and its application)
MS Mechanical Engineering (1998), Seoul National University.
(PIV algorithm development and application to twin fluid atomizer)
BS Mechanical Engineering (1995), Seoul National University.
RESEARCH EXPERIENCE
2005 ~ Current : Professor, Hongik University
- Developing and upgrading numerical method for general two phase flow
- Parallelization and optimization of the two-phase numerical method (joint project with CNRS)
- Two-phase simulation : drop (impact/collision), bubble (rising/merging/interaction)
- Numerical analysis of boiling problem (nucleate or film), solidification process
- Interface stability near equilibrium (Faraday wave)
- Numerical analysis of laser induced material processing
- Thermal deformation analysis of the thin silicon solar cell and vehicle body part
- Thermodynamic analysis of energy network using SIMULINK
- Industrial problems using commercial software such as FLUENT, ABAQUS, MOLDFLOW etc)
2004 ~ 2005 : Research Engineer, Georgia Institute of Technology
- Liquid film stability on cylindrical rod with non-uniform heating (BWR design)
- Design optimization of T-tube divertor in Fusion Reactor
2002 ~ 2004 : Postdoctoral fellow, Georgia Institute of Technology
- Developing code SCONE (Steam CONditioning Equipment) simulator (KIVA based program)
- Develop and validate mechanistic model for gas/liquid mist cooling of heated channel
- Dynamics of thin liquid films for porous wetted wall protection scheme in IFE reactor
TEACHING
FOR GRADUATE
1. Advanced numerical analysis for Mechanical Engineer
2. Computational Fluid Dynamics
3. Advanced fluid dynamics
4. Advanced heat transfer
FOR UNDERGRADUATE
1. Fluid Mechanics (1) and (2)
2. Turbo-machinery and fluid system
3. Thermodynamics
4. Numerical analysis
5. Heat transfer
6. Thermal system design
7. Application of Computational Fluid Dynamics