Energy Engineering
In a world increasingly focused on clean energy and sustainable development, the Energy Engineering major becomes an ideal choice for those who wish to engage in a highly applicable technical field while creating practical value for society. This discipline requires a combination of a solid foundation in science and engineering with innovative thinking to solve future energy challenges.
Introduction to the Energy Engineering Major
The Energy Engineering major studies the theories and techniques related to the conversion, transmission, and utilization of energy in the engineering field. This is a discipline closely linked to human production and life, with a long history, and is one of the three key fields of the 21st century, alongside information technology and new materials.
The invention of the steam engine not only marked the beginning of modern Energy Engineering but also ushered in the first industrial revolution. Faced with the ever-increasing demands of modern society for energy, alongside the development of electronics, computer, and materials science technologies, as well as increasingly evident challenges related to resources, environment, and ecology, the Energy Engineering field is facing unprecedented opportunities and pressures for innovation.
New theories and technologies in the field will contribute to improving energy efficiency, reducing primary energy consumption and pollutant emissions, and promoting the sustainable development of the national economy.
Training Objectives
The objective of the major is to train high-level technical and management personnel capable of engaging in scientific research, technological development, engineering design, technical improvement, new technology application, project planning, and management within the Energy Engineering field.
Graduate students will be equipped with solid theoretical knowledge through courses such as mathematics, fluid mechanics, thermodynamics, heat transfer, etc. Simultaneously, the program also expands understanding in fields like information and control technology, optimal decision theory, computer applications, engineering economics, and management.
Learners will grasp new trends in high-efficiency energy equipment and systems, system optimization techniques, safety and environmental protection, and possess the ability to conduct theoretical analysis, experimental research, and economic evaluation on issues within the Energy Engineering field.
Upon graduation, students can undertake teaching, research, design, and technical management work at universities, research institutes, design institutes, enterprises, and related organizations.
Evaluation of the Energy Engineering Major
Energy Engineering is one of the highly applicable majors closely linked to the practical development of global industry, energy, and the environment. In China, this field of study is not only systematically taught at many key universities but also receives strong support from national energy enterprises and corporations.
Students will have access to modern equipment systems, advanced laboratories, and internship opportunities at factories and research institutes, helping to enhance practical capabilities.
Furthermore, with the trend of green transformation and digitalization in the energy industry, graduates have many opportunities to work at renewable energy companies, high-tech enterprises, or continue in-depth research at the doctoral level.
Who is Suitable for This Major?
The Energy Engineering major is suitable for those with a good foundation in Mathematics and Physics, who enjoy researching issues related to mechanics, thermodynamics, energy, and the environment.
Those with logical thinking, an interest in exploring new technologies, a persevering spirit, and a desire to contribute to the sustainable development of society will thrive in this field.
Simultaneously, students aiming for further studies or wishing to work in large energy enterprises, industrial corporations, or state research agencies should also seriously consider choosing this major.
Study Mode and Training Duration
The training program follows a full-time study mode, with a standard study duration of 2.5 years, not exceeding a maximum of 4 years.
Main Courses of the Energy Engineering Major
|
No. |
Course Name (Chinese) |
Course Name (Vietnamese) |
Credits |
|
1 |
中国特色社会主义理论与实践 |
Theory and Practice of Socialism with Chinese Characteristics |
2 |
|
2 |
自然辩证法概论 |
Introduction to Dialectics of Nature |
1 |
|
3 |
英语读写 |
English Reading and Writing |
2 |
|
4 |
英语听力 |
English Listening Comprehension |
1 |
|
5 |
英语口语 |
English Speaking |
1 |
|
6 |
数值分析 |
Numerical Analysis |
1 |
|
7 |
数理统计 |
Mathematical Statistics |
1.5 |
|
8 |
工程矩阵理论 |
Matrix Theory in Engineering |
1.5 |
|
9 |
高等传热学 |
Advanced Heat Transfer |
3 |
|
10 |
高等流体力学 |
Advanced Fluid Mechanics |
3 |
|
11 |
人工智能概论 |
Introduction to Artificial Intelligence |
2 |
|
12 |
硅酸盐窑炉研究方法 |
Research Methods for Silicate Kilns |
3 |
|
13 |
现代控制理论 |
Modern Control Theory |
3 |
|
14 |
第二外国语(日、法、俄语三选一) |
Second Foreign Language (Choose one from Japanese, French, Russian) |
1 |
|
15 |
陶瓷英语文献选读 |
Selected Readings in English Ceramics Literature |
1 |
|
16 |
陶瓷工业窑炉发展前沿 |
Frontiers in Ceramic Industrial Kiln Development |
1 |
|
17 |
测试与控制技术 |
Measurement and Control Technology |
2 |
|
18 |
陶瓷工业窑炉的污染与防治 |
Pollution and Control in Ceramic Industrial Kilns |
2 |
|
19 |
有限元方法与应用 |
Finite Element Method and Applications |
2 |
|
20 |
微机接口技术 |
Microcomputer Interface Technology |
2 |
|
21 |
陶瓷英语文献选读 |
Selected Readings in English Ceramics Literature |
1 |
|
22 |
窑炉微机控制 |
Computer Control of Kilns |
2 |
|
23 |
仿真技术 |
Simulation Technology |
2 |
|
24 |
模糊数学 |
Fuzzy Mathematics |
1.5 |
|
25 |
固体废弃物处理 |
Solid Waste Treatment |
2 |
|
26 |
清洁燃烧技术 |
Clean Combustion Technology |
2 |
|
27 |
微/纳米尺度传热学 |
Micro/Nano Scale Heat Transfer |
2 |
|
28 |
导师自选课 |
Instructor's Elective Course |
2 |
|
29 |
教学实践 |
Teaching Practice |
2 |
Professional Internship
Internship is an indispensable part of the full-time Master of Engineering training program. Students are encouraged to intern at enterprises or research institutes, either in a concentrated or phased manner. The total internship duration should not be less than 6 months. For fresh university graduates, the internship duration should not be less than 1 year.
Training Method
A combined method of theoretical study, practice, and thesis writing is applied. Thesis topics should originate from engineering practice or have a clear technological context.
Research Directions
-
Combustion and Emissions in Energy Machinery
