自动化专业(卓越工程师教育培养计划)(080801)
Automation Major
表一
一、培养目标(Educational Aims):
培养适应国家、行业和地方经济社会发展需要的,德智体美劳全面发展,具有创新能力和创业精神,具备良好素质和科学基础,掌握现代控制、信号获取与处理、电力电子、过程控制等基本理论和专业知识,具备卓越的工程实践能力,能在能源电力及相关领域从事生产运行、工程设计、技术开发等方面工作的创新人才。
The program is to cultivate innovative talents who are able to adapt to the needs of national, industrial and local economic and social development. Being all-round developed in morality, intelligence physique, sports,arts and labor, the cultivated students should be innovative, entrepreneurial, qualified and with good scientific basis. On the other hand, students are expected to master the basic theory and professional knowledge such as modern control, signal acquisition and processing, power electronics, process control and can be engaged in production, engineering design and technology development in energy power and other related fields.
二、培养要求(Outcomes):
本专业毕业生应获得以下几方面的知识、能力和素质:
1. 工程知识:能够将数学、自然科学、工程基础和自动化专业知识用于解决电力生产过程中复杂工程问题。
2. 问题分析:能够应用数学、自然科学基本原理和自动化专业知识,结合文献研究,识别、表达、分析电力生产过程中的测量与控制问题,以获得有效结论。
3. 设计/开发解决方案:能够设计针对电力生产过程中测量与控制问题的解决方案,通过综合运用现代控制、信号获取与处理、电力电子、过程控制等基本理论和专业知识,设计满足电力生产过程中的系统、单元或工艺流程,并能够在系统设计环节中体现创新意识,考虑社会、健康、安全、法律、文化以及环境等因素。
4. 研究:能够综合运用计算机技术、电力电子技术、检测技术、控制理论等,采用科学方法对电力等行业生产过程中的测量与控制等复杂工程问题设计实验、分析与解释数据、并通过信息综合得到合理有效的结论。
5. 使用现代工具:能够针对电力生产过程中的测量与控制问题,开发、选择与使用恰当的技术、资源、现代工程工具和信息技术工具,进行计算、分析、设计、仿真,并能够理解其局限性。
6. 工程与社会:能够基于控制系统与电力生产过程相关背景知识进行合理分析,评价工程与实践和复杂工程问题解决方案对社会、健康、安全、法律以及文化的影响,并理解应承担的责任。
7. 环境和可持续发展:能够理解和评价针对电力等行业生产过程中测量与控制等复杂工程问题的工程实践对环境、社会可持续发展的影响。
8. 职业规范:具有人文社会科学素养、社会责任感,能够在工程实践中理解并遵守工程职业道德和规范,履行责任。
9. 个人和团队:能够在多学科背景下的团队中承担个体、团队成员以及负责人的角色。
10. 沟通:能够就复杂工程问题与业界同行及社会公众进行有效沟通和交流,包括撰写报告和设计文稿、陈述发言、清晰表达或回应指令。并具备一定的国际视野,能够在跨文化背景下进行沟通和交流。
11. 项目管理:理解并掌握工程管理原理与经济决策方法,并能在多学科环境中应用。
12. 终身学习:具有自主学习和终身学习的意识,有不断学习和适应发展的能力。
On completion of this program, students will be able to:
1. Solve engineering problems in power production with mathematics, natural science, engineering basics and automation expertise.
2. Obtain an effective conclusion with professional knowledge of mathematics, natural science basic principles and automation, and identify, summarize, analyze the measurement and control problem in the electric power production process through literature research.
3. Design solutions to measure and control problems in power production, design the system, unit, or process through the basic theory and professional knowledge of modern control, signal acquisition and processing, power electronics, process control, and embody innovation consciousness, consider social, health, safety, legal, cultural and environmental factors in the process.
4. Apply computer technology, power electronics technology, testing technology, control theory, etc integrally, and to obtain reasonable results by scientific methods in the field of measurement and control.
5. Develop, select and use appropriate technologies and resources to solve the measurement and control problems in the process of electric power production.
6.Conduct reasonable analysis, evaluate the impact of engineering and practical and engineering solutions on social, health, safety, law and culture, and understand the responsibilities that should be undertaken based on the background knowledge of control system and power production process.
7. Understand and evaluate the impact of engineering practices on the sustainable development of the environment and society in complex engineering issues such as measurement and control in the production process of electric power and other industries.
8. Fulfill the humanities social science accomplishment, the social responsibility, understand and follow engineering ethics and norms in engineering practice.
9. Take on different role of individuals, team members, and principals in a multi-disciplinary team
10. Communicate effectively with industry peers and the public on complex issues of environmental protection, energy and power, and petrochemicals in related areas, including reports writing and manuscripts design, presentation, and clear expression or response to directives. Students are also expected to have a certain international perspective for cross-cultural communication and exchange.
11. Understand and grasp the engineering management principle and economic decision-making method in electric and chemical fields, and to apply them in multidisciplinary environment.
12. Have the consciousness of self-directed learning, lifelong learning and adaptability to development.
三、主干课程(Core Courses):
电路原理、模拟电子、数字电子、微型计算机原理及接口技术、现代控制工程、计算机控制系统、热工基础、热工参数检测技术、过程控制、电厂开关量控制技术等。
Electric Circuits, Analog Electronics, Digital Electronics, Microcomputer Principle & Interface Technique, Modern Control Engineering, Computer Control System, Advanced Control of Thermal Process, Process Control, Switching Control in Power Plant,etc.
四、主要实践性教学环节(Main Practical Courses):
金工实习、电子工艺实习、计算机控制系统设计、实践基地认识实习、企业认识实习、单元机组热工控制系统实习、火电厂典型顺序控制系统实习、火电厂运行仿真实习操作、组态软件应用实训、集散控制系统和PLC控制系统设计、毕业实习、毕业设计等。
Metalworking Practice, Application Design of Electronic Technology, Design of Computer Control System, Practice base visiting, Enterprise Investigation, Unit Thermal Control System of Thermal Power Plant Practice, Typical Sequence Control System Practice, Operation of Thermal Power Plant Simulation Training, Configuration Software Application Training, Distributed Control System and PLC Control System Design, Graduation Practice, Graduation Project, etc.
五、专业特色(Program Features):
面向能源电力领域,突出培养电力生产控制技术和软硬件实践能力,解决电力生产过程中复杂工程问题。
With orientation on the Energy and Power, this program aims to develop students’ skills of electric power control, master software and hardware, and the practical ability of solving complex engineering problems in power production.
六、毕业合格标准(Graduation Qualification Requirements):
学制:4年,允许学生延期毕业,延期最多不得超过2年。
学位:学生平均学分绩点≥65,授予工学学士学位。
毕业合格标准:完成教学计划所要求的教学过程,毕业生获得的总学分应不少于181.5学分,其中理论教学不少于124.5学分,实践环节不少于53学分,课外培养不少于4学分,并应参加全国大学外语等级考试达到学校规定的相关标准。
Duration: 4 years. Graduation could be deferred for no more than 2 years.
Final Award: Bachelor of Engineering will be conferred on students with at least 65 credits on average.
Minimum requirements for graduation: Graduates should meet the requirements of this program, complete no less than 181.5 credits (no less than 124.5 credits for theoretical courses, no less than 53 credits for practical courses, and no less than 4 credits for extra-curriculum activities), participate in the College English Test and meet the relevant minimum requirement of the university.
七、专业课群组说明(Professional Course Packages):
学科基础必修课包括:电路原理、模拟电子、数字电子、现代控制工程、微型计算机原理及接口技术、创新创业教育。
学科基础选修课包括:EDA技术应用及PCB设计、电机基础及控制技术、软件技术基础、电力经济与管理、电力电子技术、面向对象程序设计、网络应用技术、电力经济与管理、最优化理论。
专业必修课:火力发电厂热力设备、热工参数检测技术、计算机控制系统、过程控制、电厂开关量控制技术、热工基础,集散控制系统与现场总线技术。
专业选修课:测控系统设计、控制装置与仪表、虚拟仪器、新能源发电与控制技术、数字图像处理、智能信息处理与智能控制、控制系统CAD及计算机仿真。
Basic Compulsory Disciplinary Courses: Electric Circuits, Analog Electronics, Digital Electronics, Modern Control Engineering, Microcomputer Principle & Interface Technique, Innovation and Enterprise Education.
Basic Elective Disciplinary Courses: Application of EDA Technology and PCB Design, Motor Basic and Control Technology, Foundations of Software Techniques, Electric Power Economy and Management, Technologies of Power Electronics, Object-oriented Programming, Technology of Network Application,Electric Power Economy and Management, Optimization Theory.
Compulsory Specialized Courses: Energetics Equipment, Pyrology Parameter Detection Technology, Computer Control System, Process Control, Switching Variable Control Technology of Power Plant, Pyrology Theory, Distributed Control System & Fieldbus Technology.
Elective Specialized Courses: Design of Measurement and Control System, Control Apparatus and Instrument, Virtual Instrument, New Energy Generation and Control Technology, Image Processing, Intelligent Information Processing andIntelligent control, Control System CAD and Computer Simulation.