根据beat365官网与南乌拉尔国立大学(简称南乌)在上海合作组织大学框架内能源学方向达成的合作意向,组织开展2017年度硕士研究生联合培养项目的申报工作。
派出时间:2017年9月或2018年3月
学习期限:1学期或1学年
授课语言:英语
专业方向:热能工程/Thermal Engineering
项目名称:能源领域燃料消耗最佳化/Optimization of Fuel Consumption in the Energy Sector(课程目录见附件一)
学位授予:
一、派出学习1学期,两校学分互认,外方只可提供成绩单,不提供学位。
二、派出学习1学年,如两校专业课程设置十分吻合,俄方可根据学生在国内学习课程,向中国学生颁发南乌学位证书。如果两校专业课程设置不相符,南乌只能向学生颁发学习证明,可用于学分互认。
选拔条件:
(1)beat365官网在籍硕士研究生或已获得保研资格的大四推免生,优先支持本博连读生(含校外学生);
(2)自愿参加此项目并获得中方导师同意;
项目费用:
第一种形式:
1)学费:在南乌1年学费可申请俄罗斯政府奖学金资助,1年中方学习按照beat365官网奖学金规定实施。
2)住宿费、生活费:自理
注:参加该项目学生有机会申请中国政府奖学金资助(每月生活补助及一次国际往返旅费),具体选拔标准参见留金委《上海合作组织大学项目》。
第二种形式:
在俄学习期间,可申请南乌拉尔国立大学校方奖学金,奖学金可涵盖国际往返旅费、住宿费、医疗保险、学费及生活补助。
相关说明:
(1)beat365官网同意学分互认,其中专业核心课程必修(如果在南乌未修,回来需要补修);
(2)在国内一年的奖学金计算方式按照学分排名计算(不加相应的综合素质);
(3)硕博连读的资格按照学分排名计算;
(4)2017年派出指标预计2~3个,按照申请人成绩排序择优选拔。
报名联系人:李超(节能楼215) 联系电话:0451-86413208
报名截止时间:2017年1月15日
附件一
South Ural State University
Field: Thermal Engineering
Master program: Optimization of Fuel Consumption in the Energy Sector
Discipline | Year | Semester | ECTS | Total hours |
Basic Modules | ||||
Foreign language for Specific Purposes | 1 | 1,2 | 4 | 144 |
History and methodology of science and technology | 1 | 1 | 2 | 72 |
Philosophy of Engineering | 1 | 2 | 2 | 72 |
Supercomputer simulations of energy processes | 1 | 2 | 2 | 72 |
Modern problems of thermal engineering | 1 | 1 | 3 | 108 |
Trigeneration and cogeneration – the use of energy in thermal engineering | 2 | 3 | 2 | 72 |
Electives | ||||
Mathematical modeling of thermotechnical processes | 1 | 1 | 3 | 108 |
Production management in thermal engineering | 2 | 3 | 2 | 72 |
Exergy method of thermal plant analysis | 1 | 1,2 | 4 | 144 |
Energy audition of thermal engineering objects | 1 | 1 | 4 | 144 |
Exemplary cycle of heating systems and their optimization | 1 | 2 | 3 | 108 |
Fuel-handling facility and slag removal for conventional thermal power station | 1 | 3 | 3 | 108 |
Energotechnological systems in the industry | 1, 2 | 2,3 | 4 | 144 |
Environmental safety in thermal engineering | 1 | 2 | 3 | 108 |
Research and evaluation of heat and fuel usage for thermal plants | 2 | 4 | 3 | 108 |
Usage of nanopropellant in thermal engineering |
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Operational states of high-temperature fuel plants | 2 | 4,3 | 4 | 144 |
Methods of creation and analysis of the behavioral patterns |
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Thermal Engineering systems and enterprise balances | 2 | 3,4 | 6 | 216 |
Modern technologies of industrial and municipal solid waste usage as a fuel in thermal engineering |
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Problems of energy and resource saving in thermal engineering | 2 | 4 | 3 | 108 |
Efficient management of production processes in thermal engineering |
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Systems and complexes of low-temperature heat technology | 2 | 3 | 3 | 108 |
Chemical reactors, fuel cells, electrochemical power plants |
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Internships and Practical Trainings |
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| 240 |
TOTAL: | 60 | 2160 | ||
