Mechatronics Engineering Course Introduction Prof. Tianmiao Wang Prof. Li Wen School of Mechanical Engineering and Automation Beihang University
Professor biography Tianmiao Wang, Full Professor He worked as a Posdoc fellow in the BioRobotics Institute of the Scuola Superiore Sant'Anna (SSSA), Pisa, Italy. He is now the Head of the expert group in the field of advanced manufacturing technology of the National High Technology Research and Development Program (863 Hi-Tech Program). He had published more than 100 papers in international journals and several professional books. Research interests: biomimetic robotics, medical robotics and embedded modular robotics.
Professor biography Li Wen, Associate professor He worked as a Posdoc fellow at Harvard University, USA before joining Beihang University. He has served as the Session Chair for several academic conferences, including the IEEE/RSJ International Conference on Intelligent Robots and Systems and IEEE International Conference on Robotics and Automation. He was also the recipient of several domestic and international awards. Research interests: bio-inspired robotics, soft robotics, 3D printing and micro fabrication, bio-fluid mechanics.
Definition of Mechatronics Mechatronics: comes from Japan(1970s), it s the combination of mechanism and electronics. Mechani sm Electron ics Mechatr onics
Definition of Mechatronics Mechatronics, from the system point of view, is a new science and technology in which the system will be organically consolidated on the basis of mechanical engineering technology, microelectronics, information technology, control technology, in order to optimize the entire system. Mechatronics is not a simple superposition of mechanical and electronics, but an application tech built up on the basis of information theory, control theory and system theory. Mecha nic electro nics Inform atics Mechatronics
Contents of Mechatronics Mechatronics CNC milling machine Mechatronics Technology Mechatronics products Automated Robot Intelligent robot
Function of Mechatronics Just because of mechatronics flexible nature with the introduction of electronic Tech. The basic function of Mechatronics: Extend new functions. enhance the flexibility.
Questions? What to can learn from this course? What does this course mainly include? How we better study this course?
International Achievements The most advanced humanoid robot--atlas? Japanese 5-Axis CNC machining center. The world's first mass-produced battle droid KURATAS.
Typical Mechatronics Device 1. 3D printer 2. Digital Factory 3. CNC Machine Center
1. 3D Printer Definition 3D printing is an emerging technology which is rapidly growing in recent manufacturing industry. It is called technology that can open up a new industrial revolution. Main process 3D model design Print the product layer by layer using liquefied, powdered, gel, sand, live tissues and other materials.
Principles of 3D Printing Traditional Remove the unnecessary portions of raw material in ways like Cutting, Grinding, Melting and so on. Then assemble the parts into a final product. 3D printing In 3D printing, products can be made directly based on computer Stereo-lithography data. This technology simplifies manufacturing processes, shorten the product development cycle, and reduce the costs in both financial and time.
3D printing part demonstration
Component of 3D printer Software: Slice the 3D model, generate numerous printing coordinates command. Mechanical structure: Spatial axis is composed of motor, frame, Timing Pulley, conveyor belts, etc. Electronic components: Storing instructions and data caching; motor controller, temperature sensor, etc.
Key technologies of 3D printing Information technology: Help to design 3D model and generate coordinate information. Precision machinery: High degree of accuracy and stability. Material science: Materials can be liquefied or powdered and then solidified automatically.
Application Area of 3D printer Commercial Manufacture
Application Area of 3D printer Culture and Creativity Industry
Application Area of 3D printer Aeronautics and Astronautics & Military Industry
Application Area of 3D printer Biomedical organism
Application Area of 3D printer Building Project
Application Area of 3D printer Entertainment
Videos about 3D Printing
2. Digital factory Background: 1. All kinds of new manufacturing concept and pattern,such as computer/modern integrated manufacturing, flexible manufacturing, concurrent manufacturing, internet manufacturing and so on,which have improved the digital and intelligent level of manufacturing system. 2. The developments of digital simulation technology and virtual reality technology make it possible that make virtual plan and simulation optimization for the real industry manufacturing. 3. Therefore, there comes into being a new concept of Digital Factories, which provides the development of manufacturing technology with new ways.
2. Digital factory Definition
Components of Digital Factory
Key Technologies of Digital Factory Digital modeling technology: Digital factory is virtual simulation system based on digital models. As the foundation of digital factory, digital modeling technology is rather critical. Virtual reality technology: the virtual technology is able to offer us a immersed, interactive and conceived multidimensional information space, which can offer a good human-computer interaction. The level of virtual technology we can achieve largely affects the maneuverability of the digital factories system, and it also affects the correctness of the users judgments to the product design as well as the producing process.
Key Technologies of Digital Factory Optimization simulation technology: The Optimization simulation technology is all about analyzing all kinds of potential problems and optimizing programs that may occur during the process of the virtual producing according to the built digital models and the simulated results from the simulating system and other predicted data. When it comes to whether can mostly exert enterprise s benefit and improve enterprise s competitiveness, the level of this optimizing simulation technology is vital.
Key Technologies of Digital Factory Application production technology: As the need of the producing automation, digital factories systems is expected to offer all sorts of controlling programs that can be directly applied in the actual producing equipment and all kinds of processes and report files which could be needed. All kinds of friendly and excellent application interface could accelerate the transforming process from digital design to actual producing application.
Significance of Developing Digital Factory Preplanning & Flexible Production Shorten Development Cycle & Improve Product Competitiveness Save Resources, Lower the Cost & Increase Capital Profit Improve Product Quality
3. CNC Machine Center
Course Overview 1 Introduction to the Curriculum 2 Curriculum System 3 4 Demand Syllabus 5 PBL Teaching Mode
Mechanical design, manufacturing and automation technology Modern Design Technology Advanced Manufacturing Technology Manufacturing Automation Technology Modern management technology Life cycle Design Reliability Design Intelligent Design Accurate and efficient metal forming processes Precise and clean casting ultra-precision machining technology Industrial robot CNC technology Flexible Manufacturing Technology CE(Concurrent Engineering) CIMS(computer integrated manufacturing system) ERP(Enterprise Resource Planning)
Discipline professional foundation course Sort SID Course Credit Theoretical 1 Mech mechanics 5.5 anics Mechanics of 2 materials 6 electr icity 3 Circuit analysis 3 4 Circuit testing 3 5 Artificial circuit B 2 6 Digit circuit 2 Total 21.5 Sort SID Course Credit Design Manufa cture Control Info 1 Engineering graphics 6 2 Mechanical principle 3 3 Mechanical Design 3 4 Engineering material 2 5 Process technology 3 6 Manufacturing engineering foundation 1 2 7 Manufacturing engineering foundation 2 2 8 Electrical and control engineering 1 3 9 Electrical and control engineering 2 2 10 Measurement technique 2 11 C language programming 3 12 Software technology foundation 3 13 Microcomputer principle and interface design 4 Total 38
Overview Character: This course is the professional foundation course of mechanical engineering and automation, and it is the core comprehensive practical course of control. 课程结构主要内容学时 机电控制基础知识 机电一体化系统总体设计, 项目研发计划书撰写 传感 驱动 微机控制系统设计 控制系统建模仿真 插补算法与数控编程 14 项目实践 基于 AVR 单片机的步进电机控制实验 MATLAB 软件操作与直流伺服电机系统建模 仿真实验 ; 插补算法与数控编程实验 研讨会 项目实践及前沿发展趋势研讨 6 14
Course overview 1 Introduction to the Curriculum 2 Curriculum System 3 4 Demand Syllabus 5 PBL Teaching Mode
Curriculum System Concepts, definitions, composition, range and classification; Design method (guidelines, procedures, appearance); Machinery - construction and transmission (ball screw drive gear, harmonic gear drive, belt drive, rails, spindle assembly, support); Sensors - positioning and detection (angular displacement, grating displacement, electromagnetic induction); Servo drives (stepper motors, DC motors, AC motors, open-loop servo loop servo); Microcomputer Principle and Control System (principles, interfaces, movement of the transfer function, the control algorithm); Typical examples of mechatronics -robots and CNC machine tools Trends
Course overview 1 Introduction to the Curriculum 2 Curriculum System 3 4 Demand Syllabus 5 PBL Teaching Mode
Our Wishes Consolidate student s basic theory and knowledge Develop student s ability on using comprehensive knowledge to solve a specific problem Let the students know the latest technology in the field of mechatronics Lay the foundation for the research in mechatronic system in the future
Arrangement Combining lecture with practice, 1:1; Grading according to practice project (X-Y NC Worktable) Questions will be answered by laboratory course or through our website.
Hardworking Limited time, a wide coverage of contents. Do not learn for final exam, learn for improving your ability.
Course overview 1 Introduction to the Curriculum 2 Curriculum System 3 4 Demand Syllabus 5 PBL Teaching Mode
1. Topics Arrangement Main Line: Introduction Designing method Choosing devices Modeling and analyse CNC control practice Developing control system Learning exchange Latest technology
序号日期节数教学内容备注 1 3.4 2 课程简介 理论 第一章 : 绪论 机电控制系统体系结构与发展趋势 2 3.11 2 第二章 : 机电一体化系统总体设计, 项目研发计划书 理论 3 3.18 2 第三章 : 传感器分类 常用传感检测系统设计理论 4 3.25 2 第四章 : 驱动系统设计理论 5 4.1 2 第五章 : 微机控制系统的设计与开发方法理论 6 4.8 2 AVR 单片机基础实验实验 7 4.15 2 AVR 单片机基础实验实验 8 4.22 2 步进电机驱动控制实验实验 9 4.29 2 第六章 : 控制系统建模与分析理论 10 5.6 2 MATLAB 软件操作与直流伺服电机系统建模 仿真 实验 与分析实验 11 5.13 2 MATLAB 软件操作与直流伺服电机系统建模 仿真 实验 与分析实验 12 5.20 作业点评 : 基于 AVR 单片机的步进电机控制实验 研讨 13 5.27 2 第七章 : 插补算法与数控编程理论 14 6.3 2 插补算法实验实验 15 6.10 2 数控编程实验实验 16 6.17 2 研讨课 : 机电控制技术前沿发展趋势研讨 17 6.24 2 作业点评 : 插补算法及数控编程实验研讨
2. Examination and Grading Performance in practice will be valued. Usual-time mark : 10% Practice project : 50% Final exam : 40% Distribution of practice project: MCU : : 25 point Interpolation algorithm: 15 point CNC programming: : 10 point
3. PREREQUISITES Prerequisites: Mechanical Design Measurement technology Electromechanical Transmission Control Electrical control engineering I Microcomputer principle and interface technology The basis of computer software technology
4. REQUIRED TEXTS [1] Teaching material & experiment guidebook [2] 王田苗. 机电控制基础理论及应用. 清华大学出版社,2002 [3] 机电一体化系统设计, Devdas Shetty 著, 张树生译, 机械工业出版社,2006
5. Q&A Lecture room:( 一 )212 Laboratory:New Main building B307 Time:Week 1-16 Tuesday(5, 6) TA : 潘俊威 (Pan Junwei);13126522848 Teaching material download: E-mail: xdjdkzbk2014@163.com, password: xdjdkz2014 Assignment submit to: E-mail: xdjdkzbk_zy2014@163.com
6. Group Cases Conceding the limited equipment and to cultivate one s team work sprit, Group Cases are as follows: The recommended member of a group is 3 4. Team up freely, a team, a leader, and the leader should leave his/her contact information to the TA. The work should be clearly divided, which will decides one s final grade. If a student didn t find a team for some special reasons, the teacher will decide for you.
Course Project Three in total: 1 st :Controlling stepping motor based on AVR MCU 2 nd :Programing with interpolation algorithm 3 rd : CNC programming
Course Project Based on specific project Project plan Introduction How to build mechatronics system with reasonable device Unit character How to analyze a specific system Modeling & simulation How to design a specific circuit Hardware design How to accomplish a project Project practice Modern Mechatronics System Control
Course Project 1 1.Title (Undergraduates are not required) The researching and developing plan of bicoordinate numerical control workbench system and the design of system scheme 2.Purposes 1) Cultivate the ability of planning the projects of mechatronic systems; 2) Cultivate the ability to designing schemes of mechatronic systems; 3.Demands 1) Goal:Researching and developing a bicoordinate numerical control workbench as the experimental and teaching platform for this course; 2) Function:Draw the route of the work bench with a pen in the horizontal plain and simulate the process of numerical control processing. 3) Performance a. Degree of freedom:2(can be extended to 3); b. Driver:DC servo motor and stepper motor, open loop control for stepper motor and half closed loop control for DC servomotor; c. Size of the workbench 450 450mm2,effective stroke within 200mm; d. Accuracy of location:1mm; e. Velocity 1mm/s; f. Load<=200N; 4) Others a. Duration:3 months; b. c. Cost:within 20 000; Members:2
Course Project 2 1.Experimental topics The modeling and emulation analysis of velocity loop control system of single-dof and linear motion unit 2.Experimental topics Master modeling and emulation methods and skills of electromechanical control system; Learning to use MATLAB Simulink toolbox to build mathematical model and to draw graph in time-domain and frequency-domain. 3.Task Set up mathematical model of the linear motion unit when the velocity is open loop controlled and determine the key factors with the given data, simplifying it and simulating it with MATLAB.
Course Project 3 1. Title Controlling experiment on linear motion unit of NC Worktable 2. Purpose Master simple application of AVR system; Master application of AD converter in AVR MCU; Study how to use AVR s timer, understand the concept of disruption; Learn how to control stepper motor by AVR MCU; 3. Practice Use MCU to control speed and direction of stepper motor.
Course Project 4 1.Title Comprehensive experimental of CNC programming and interpolation algorithm 2.Purpose Learn how to program in G code. Learn how to realize interpolation algorithm 3.Practice Write your code to realize by-point interpolation algorithm of line and arc, simulate and compare your code to the demo. Design a pattern by G code, get simulation done and manufacture the product by X-Y worktable.
Teaching Equipment: X-Y NC Worktable
Teaching Equipment: MCU test chamber
Teaching Equipment
7. Instruction 1. The Three projects are required to be finished by your own, The similar homework do not count. 2. The contents of one s homework should not be the same as the teaching materials, if you to get a high score. Innovated contents will be helpful. 3. Your homework is intended to be submitted before the deadline, late delivery will lower your grade. 4. Please participate lectures and practice course on time, use our equipment carefully and keep the environment clean. 5. Close your computer after class.
Practical Teaching-Examination & Evaluation Examination & Evaluation Guidance Examination Face to Face By Internet Work Exhibition Classroom Presentation Classroom Discussion
Website itr.buaa.edu.cn