For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| EME4901 | Management for Engineers | 3 | 6 | Major | Bachelor/Master |
3-4
1-4 |
Mechanical Engineering | - | No |
| Designed for undergraduate and graduate students wanting to understand the interdisciplinary mechanisms between engineering and management. Topics like financial statements and costing, business plan, technology management, role of IT technology in manufacturing are considered. Case study method of instruction emphasizes participation in class discussion. A key component of this subject is a team project. | |||||||||
| EME4905 | Convergence Business Model Planning | 3 | 6 | Major | Bachelor/Master | 1-4 | Korean | Yes | |
| This course amis to learn the methodologies for developing a new business model based on understandings on the needs of internet user group and network communities which are expanding the interconnections and creating new values. Students will study various technological trends such as IoT, cultural trends, big data, and methods for user study. This will be used to establish technology-converging business models and appropriate marketting strategies through multidisciplinary approach. | |||||||||
| EME4905 | Convergence Business Model Planning | 3 | 6 | Major | Bachelor/Master | 1-4 | Mechanical Engineering | Korean | Yes |
| This course amis to learn the methodologies for developing a new business model based on understandings on the needs of internet user group and network communities which are expanding the interconnections and creating new values. Students will study various technological trends such as IoT, cultural trends, big data, and methods for user study. This will be used to establish technology-converging business models and appropriate marketting strategies through multidisciplinary approach. | |||||||||
| EME4907 | Analysis and Design of Manufacturing System | 3 | 6 | Major | Bachelor/Master | - | No | ||
| Emerging technologies provide new opportunity for developing a competitive manufacturing system. Understanding the interaction between components of a manufacturing system as well as capability to analyze the system performance is crucial in smart factory or industry 4.0. This course includes the topics as following: components of a manufacturing system and their inter-relation, design theory like axiomatic design, manufacturing strategies, techniques for analysing manufacturing system performance, and quality engineering. | |||||||||
| EME4907 | Analysis and Design of Manufacturing System | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | - | No | |
| Emerging technologies provide new opportunity for developing a competitive manufacturing system. Understanding the interaction between components of a manufacturing system as well as capability to analyze the system performance is crucial in smart factory or industry 4.0. This course includes the topics as following: components of a manufacturing system and their inter-relation, design theory like axiomatic design, manufacturing strategies, techniques for analysing manufacturing system performance, and quality engineering. | |||||||||
| EME4908 | Processing and properties of thin films | 3 | 6 | Major | Bachelor/Master | - | No | ||
| This course covers the fundamentals of the processing methods of thin films, such as photolithography, PVD, CVD, etching processes, etc. A variety of properties of thin films, such as mechanical, structural, electrical, thermal properties and their characterization methods are introduced. | |||||||||
| EME4908 | Processing and properties of thin films | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | - | No | |
| This course covers the fundamentals of the processing methods of thin films, such as photolithography, PVD, CVD, etching processes, etc. A variety of properties of thin films, such as mechanical, structural, electrical, thermal properties and their characterization methods are introduced. | |||||||||
| EME4909 | Particle and Aerosol Engineering | 3 | 6 | Major | Bachelor/Master | English | Yes | ||
| Currently, particle and aerosol exert big impact on industry, environment, and society. This course covers physical and chemical properties of particle and aerosol and their transport based on the knowledge of thermal and fluid engineering. Application field such as semiconductor/display manufacturing technology, atmospheric particulates and bioaerosol instrumentation and control, and nanoparticle synthesis and application will also be covered. | |||||||||
| EME4909 | Particle and Aerosol Engineering | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | English | Yes | |
| Currently, particle and aerosol exert big impact on industry, environment, and society. This course covers physical and chemical properties of particle and aerosol and their transport based on the knowledge of thermal and fluid engineering. Application field such as semiconductor/display manufacturing technology, atmospheric particulates and bioaerosol instrumentation and control, and nanoparticle synthesis and application will also be covered. | |||||||||
| EME4910 | Automotive Heat Management and Air Quality Control Technology | 3 | 6 | Major | Bachelor/Master | - | No | ||
| Automotive thermal management started with internal combustion engine. While burning fossil fuels, enormous amount of heat is generated and to control the temperature of engine at a proper level, thermal management system is essential. In addition, HVAC system has been implemented to maintain good air quality inside the automobile and this extended the scope of thermal management. Recently, electric, hydrogen electric, and hybrid cars have been adopted and thermal management technology is chaning rapidly. In this course, HVAC, refriegeration/cooling technology, heat pump, thermal comfort and particulate control will be discussed to understand the automotive heat management and air quality control. | |||||||||
| EME4910 | Automotive Heat Management and Air Quality Control Technology | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | - | No | |
| Automotive thermal management started with internal combustion engine. While burning fossil fuels, enormous amount of heat is generated and to control the temperature of engine at a proper level, thermal management system is essential. In addition, HVAC system has been implemented to maintain good air quality inside the automobile and this extended the scope of thermal management. Recently, electric, hydrogen electric, and hybrid cars have been adopted and thermal management technology is chaning rapidly. In this course, HVAC, refriegeration/cooling technology, heat pump, thermal comfort and particulate control will be discussed to understand the automotive heat management and air quality control. | |||||||||
| EME4912 | Future Car Thermal Management System | 3 | 6 | Major | Bachelor/Master | Korean | Yes | ||
| This course aims to acquire fundamental knowledge and cultivate design skills related to the thermal management system and components of future automobiles. Students will gain an understanding of cooling methods and configurations, learn two-phase flow and phase-change heat transfer technologies for designing high-heat flux thermal management systems. The course covers cooling technologies of key components, such as high-heat flux heat exchangers, powertrains, and batteries. Additionally, the course explores design methods to achieve high-performance and high-efficiency thermal management systems through their integration. | |||||||||
| EME4912 | Future Car Thermal Management System | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | Korean | Yes | |
| This course aims to acquire fundamental knowledge and cultivate design skills related to the thermal management system and components of future automobiles. Students will gain an understanding of cooling methods and configurations, learn two-phase flow and phase-change heat transfer technologies for designing high-heat flux thermal management systems. The course covers cooling technologies of key components, such as high-heat flux heat exchangers, powertrains, and batteries. Additionally, the course explores design methods to achieve high-performance and high-efficiency thermal management systems through their integration. | |||||||||
| EME4913 | Advanced Bioadhesive Interfaces | 3 | 6 | Major | Bachelor/Master | Korean | Yes | ||
| The first half of this lecture covers the mechanical theories of biosurface adhesive interfaces. The design and manufacturing process of functional nano/micro structures that maximize mechanical surface adhesion (van der Waals, suction, capillarity) will be introduced. Additionally, we understand the basic mechanisms of elastomeric polymers to design functional soft materials with special properties such as elasticity, toughness, strength, adhesion, fatigue resistance, and actuating. In the second half, we introduce convergence research with the latest wearable/implantable devices and introduce multidimensional methods that demonstrate manufacturing processes, theoretical analysis, and new functions that apply to these bio application technologies. In this lecture, students also read and discuss papers that apply the latest wearable/implantable devices. | |||||||||
| EME4913 | Advanced Bioadhesive Interfaces | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | Korean | Yes | |
| The first half of this lecture covers the mechanical theories of biosurface adhesive interfaces. The design and manufacturing process of functional nano/micro structures that maximize mechanical surface adhesion (van der Waals, suction, capillarity) will be introduced. Additionally, we understand the basic mechanisms of elastomeric polymers to design functional soft materials with special properties such as elasticity, toughness, strength, adhesion, fatigue resistance, and actuating. In the second half, we introduce convergence research with the latest wearable/implantable devices and introduce multidimensional methods that demonstrate manufacturing processes, theoretical analysis, and new functions that apply to these bio application technologies. In this lecture, students also read and discuss papers that apply the latest wearable/implantable devices. | |||||||||