; "# A\ptmax Ba==h\:#8X@"1Arial1Arial1Arial1Arial"$"#,##0_);("$"#,##0)"$"#,##0_);[Red]("$"#,##0) "$"#,##0.00_);("$"#,##0.00)% "$"#,##0.00_);[Red]("$"#,##0.00),*'_(* #,##0_);_(* (#,##0);_(* ""_);_(@_)5)0_("$"* #,##0_);_("$"* (#,##0);_("$"* ""_);_(@_)=,8_("$"* #,##0.00_);_("$"* (#,##0.00);_("$"* ""??_);_(@_)4+/_(* #,##0.00_);_(* (#,##0.00);_(* ""??_);_(@_) + ) , * `22Sheet0 LSubject NameCampusAcademic CurriculumCreditsCompletion Criteria
Lecture TypesLecture MethodsSupervising ProfessorsLecture ObjectivesTextbooks and CitationsHow a Lecture is ConductedAssignmentsGrading and Score Evaluations՜0Ǭȴ Ĭ! 83Seminars on Plant Equipment Control and Measurement(Korea Institute of Machinery MaterialsIntegrative programSeminar
Korean coursef? @ ՜ 0ĬY X 8 0D X, X 0x ȴ t`D <\ 䲑\ Qǩ t , Yյ D X ȴ Ĭ!X 0 D ݴ` ĳ] Xp, µD X l ֥ Yյ D ` ĳ] h.
The aim of this lecture is as follows for the future s plant engineers;
 to study the basic automatic control & measurement theory.
 to experience field learning through the practical training. 8\\Ԑ̸
UYչ` 85Seminars on Special Topics of Fluid Power Engineering? @ ՜ 0ĬY X 8 0D X, X 0x U t`D <\ 䲑\ 00X t , Yյ D X U ¤\X 0 D ݴ` ĳ] Xp, µD X l ֥ Yյ D ` ĳ] h.
The aim of this lecture is as follows for the future s plant engineers;
 to study the basic hydraulic theory,
 to acquire basic knowledge about the hydraulic components,
 to experience field learning through the practical training.X ȥ0 84Seminars on Energy Conversion and Storage Technology? X ȥ 0 \ 0 P ) \ YX D tt\.
? This course covers the basic concepts and insights on future renewable energy and thermal storage technology from the views of industry, academia, and research institues. ՜ȴY`)Introduction to Plant Control EngineeringMajorz? ՜ 0ĬY X 8 0D X, X 0x ȴ t`D <\ 䲑\ ȴX t , Yյ D X 0ĬȴX 0 D ݴ` ĳ] Xp, µD X l ֥ Yյ D ` ĳ] h. ? The aim of this lecture is as follows for the future s plant engineers;  to study the basic control theory,  to acquire basic knowledge about the mechanical control,  to experience field learning through the practical training.QǩY 2Applied Mathematics 2? @ QǩYID \ YD <\ ĳǔ YY 0D \.. ? The aims of this course is to study various advanced mathematical techniques for the students who learned Engineering Mathematics I. ՜$ĬPlant Process Designu? ՜ ǀ0 ȴ ¤\ tt $Ĭ D tt\.
? This course covers from a unit process design to the whole system design.
X ȥEnergy Conversion and Storage? X ȥ 0 X Ƭ )D tt\.
? This course covers the concepts and technology trends of energy conversion and storage. Ȱ ǴY`?Introduction to Computational Fluid Mechanics and Heat Transfer? @ Ǵ X 8 X<\ tհ` ǔ %D а0 X DՔ\ <\ D 0)D tǰT XՔ ), Xt 0 D h\. ? The aim of this course is to study the computational fluid mechanics (CFD) and heat transfer methodology to quantitatively analyze problems for thermal and fluid engineering fields. In this course, the general concepts of numerical simulations and how to discretize the generally used governing equations.YAdvanced Thermal Engineering? YX 0P 0) t YյX t QǩX 䲑\ ¤\D $ĬX t` ǔ %D 0\. \x ¤\ QǩƄx tt, ɰٳ tt X 0x tt tt Xĳ] Yյ\. ? The lectures about the basic concepts of thermal engineering and governing equations will be provided in this course. The aims of this course is that students have the ability to design and analyze the various thermal systems such as power generation cycle and refrigeration cycle, etc.՜tĳPlant Risk Assessment)? @ ՜ \ XՔ ǴX tǩ, ȥ XՔ QX0 X 1D X, ɷTX $ĬX i1D XՔ ĳ 0 $Ĭ \ 0 ݴD \\ ՜ tĳ , 1/ɷ tĳ )` X Yյ\. \, ՜ <\ ɷ tĳ  h<\h X ttĳ tĳ] \. ? The aim of this course is to acquire a basic knowledge on the risk based safety design technology for energy plants in order to cope with unexpected hazards or accidents occurring in the production, storage, distribution, and usage of process fluid for energy plants. In this lecture, introduction to risk assessment for energy plants, methodology of qualitative and quantitative risk assessment will be presented. In addition, case studies of the quantitative risk evaluation for the specific plants can help student understand the general aspect of the risk based safety design.՜T֬ 8*Seminar for Fires and Explosions at Plants՜ T֬ X X@ 0 TȲX ttБt 8Seminar for Solar DesalinationZБ t t` l Yյ
Study for<x basic theory of solar desalination and literature survey
}, \, ` ǴY)Fundamental of Thermal and Fluid Sciences? @ Ǵ  lXՔ p DՔ\ Y ǴYX 0x D uǈה D \\ Y 1, 2Y ɷ, Ǵ 0), t ٳ, 1 ٳ X Yյ\. X@ ŵ 8 t ѼX X ttĳ tĳ] \. ? The purpose of this course is to understand basics of thermodynamics and fluid dynamics for doing research in the fields of thermal, fluids and energy. The list of the specific topics is provided as follows;  Laws of thermodynamics, Properties of substances  Governing equations for fluid flow, Inviscid flow, Viscous flow Uٳ%¤\!Hydraulic Power Generation SystemX. Comprehension of hydraulic power unit
. Management and application of hydraulic power՜Y`!Introduction to Plant Engineering? TY(Petrochemical) ՜, ՜, T՜, tՑ՜ X Ȕ $DD YյX Ǵx D tǩX t \. \ ՜$Ĭ DՔ\ x ՜ °ĳ H$Ĭ YյX Yt ՜$Ĭ \ ȴx ݹD ĳ] ĳ \. ? Main process and equipment for several plants such as petrochemical plant, gas or coal fired power plant, desalination plant and offshore plant are introduced based on thermofluid mechanics. Plant reliability and safety design concept are also given so that students can understand the general aspect for plant design.
PX0\T$Ĭ 8,Seminar for Optimal Design of Heat ExchangerPX0 $Ĭ\T \0 ٳ ( 8QǩY 1Applied Mathematics 1M? @ X\. X@ ŵ 8 t ѼX X ttĳ tĳ] \. ? The aims of this course is to study various mathematical techniques for thermal fluid resea7rch field. The lectures of numerical analysis, ordinary and partial differential equations, vectors and complex numbers, special functions and boundary value problems will be provided. RD
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