机电一体Mechatronics化.docx

1、机电一体Mechatronics化Mechatronics (机电一体化)1 A blend of mechanics and electronics, mechatronics has come to mean the synergistic use of precision engineering, control theory, computer science, and sensor and actuator technology to design improved products and processes.2 The standard clothes dryer is typi

2、cally controlled by a mechanical timer. The user adjusts the timer according to the size and dampness of the load. If the timing device is not set properly, the drying cycle may be too short and the laundry may come out wet, or the machine could run long and waste energy. 3 A clothes dryer, however,

3、 might be fitted with a sensor-based feedback system that lets the machine measure the moisture content of the fabrics or the exhaust air, and turn itself off when the load is dry. Operating performance is enhanced and energy use is lowered as a result. The redesigned dryer might even be cheaper to

4、buy, depending mainly on the cost of the components that comprise the electromechanical control system.4 The computer disk drive, such as Cheetah from Seagate Technology, is one of the best examples of mechatronic design because it exhibits quick response, precision, and robustness. 5 Many U.S.-trai

5、ned design engineers would say that the improved dryer is the result of up-to-date but conventional design practices. A reliable yet relatively inaccurate mechanical device was replaced by a smarter electronic control. In much of the rest of the world, however, design engineers would say that the dr

6、yer redesign followed the principles of mechatronics.6 Mechatronics is nothing new; it is simply the application of the latest techniques in precision mechanical engineering, controls theory, computer science, and electronics to the design process to create more functional and adaptable products. Th

7、is, of course, is something many forward-thinking designers and engineers have been doing for years. 7 The vaguely awkward word was first coined in Japan some 30 years ago. Since then, mechatronics has come to denote a synergistic blend of mechanics and electronics. The words meaning is somewhat bro

8、ader than the traditional term electromechanics, which to many connotes the use of electrostatic or electromagnetic devices. It is also an amorphous, heterogeneous, and continually evolving concept with 1,001 definitions, many of which are so broad or so narrow to be of seemingly marginal use. 8 Mec

9、hatronics is more than semantics, however. Its a significant design trend that has a marked influence on the product-development process, international competition in manufactured goods, the nature of mechanical engineering education in coming years, and quite probably the success mechanical enginee

10、rs will have in becoming team leaders or engineering managers. Defining Mechatronics 9 For Takashi Yamaguchi, who works at Hitachi Ltd.s Mechanical Engineering Laboratory in Ibaraki, Japan, mechatronics is a methodology for designing products that exhibit fast, precise performance. These characteris

11、tics can be achieved by considering not only the mechanical design but also the use of servo controls, sensors, and electronics. He added that it is also very important to make the design robust. Computer disk drives, for example, are a prime example of the successful application of mechatronics: Di

12、sk drives are required to provide very fast access, precise positioning, as well as robustness against various disturbances, he said. 10 For Giorgio Rizzoni, associate professor of mechanical engineering at Ohio State University in Columbus, mechatronics is the confluence of traditional design metho

13、ds with sensors and instrumentation technology, drive and actuator technology, embedded real-time microprocessor systems, and real-time software. Mechatronic (electromechanical) products, he said, exhibit certain distinguishing features, including the replacement of many mechanical functions with el

14、ectronic ones, which results in much greater flexibility and easy redesign or reprogramming; the ability to implement distributed control in complex systems; and the ability to conduct automated data collection and reporting. The diagram at left illustrates that mechatronics is where mechanics, elec

15、tronics, computers, and controls intersect11 Mechatronics is really nothing but good design practice, said Masayoshi Tomizuka, professor of mechanical engineering at the University of California, Berkeley. The basic idea is to apply new controls to extract new levels of performance from a mechanical

16、 device. It means using modern, cost-effective technology to improve product and process performance and flexibility. In many cases, the application of computer and controls technology yields a design solution that is more elegant than the purely mechanical approach. By having a good idea of what ca

17、n be done using other than mechanical means, design freedom increases and results improve, according to Tomizuka, who is also editor-in-chief of the quarterly IEEE/ASME Transactions on Mechatronics jointly published by the Institute for Electrical and Electronics Engineers and ASME. 12 The journal,

18、first published in March 1996, is another indication that the importance of this interdisciplinary area is being recognized. Transactions covers a range of related technical areas, including modeling and design, system integration, actuators and sensors, intelligent control, robotics, manufacturing,

19、 motion control, vibration and noise control, microdevices and optoelectronic systems, and automotive systems. The Roots of Mechatronics13 Mechatronics was first used in terms of the computer control of electric motors by an engineer at Japans Yaskawa Electric Co. in the late 1960s. The word has rem

20、ained popular in Japan, and has been in general use in Europe for many years. Although mechatronics has been slow to gain industrial and academic acceptance as a field of study and practice in Great Britain and the United States, its increasingly prominent place worldwide is shown by the growing num

21、ber of undergraduate and postgraduate mechatronics courses now being offered. 14 Many engineers would contend that mechatronics grew out of robotics. Early robotic arms, then unable to coordinate their movements and without sensory feedback, benefited greatly from advances in kinematics, dynamics, c

22、ontrols, sensor technology, and high-level programming. The same battery of modern technologies that made robots more flexible and thus more useful was then brought to bear on the design of new generations of high-performance, adaptable machinery of all kinds. 15 In the 1970s, mechatronics was conce

23、rned mostly with servo technology used in products such as automatic door openers, vending machines, and autofocus cameras. Simple in implementation, the approach encompassed the early use of advanced control methods, according to Transactions editors. 16 In the 1980s, as information technology was

24、introduced, engineers began to embed microprocessors in mechanical systems to improve their performance. Numerically controlled machines and robots became more compact, while automotive applications such as electronic engine controls and antilock-braking systems became widespread. 17 By the 1990s, c

25、ommunications technology was added to the mix, yielding products that could be connected in large networks. This development made functions such as the remote operation of robotic manipulator arms possible. At the same time, new, smaller-even microscale-sensor and actuator technologies are being use

26、d increasingly in new products. Microelectromechanical systems, such as the tiny silicon accelerometers that trigger automotive air bags, are examples of the latter use.18 As significant as these developments may seem, a good deal of skepticism remains about the idea of codifying them in an engineer

27、ing field called mechatronics. Its certainly a catchy word, said controls expert Ernest O. Doebelin, professor emeritus at Ohio State and an ASME Fellow, but its an evolutionary, rather than revolutionary, development. Now that computers are small and relatively cheap, it just makes sense for design

28、ers to build them into products. Mechatronics is really the familiarity with all the other technologies-computers, software, advanced controls, sensors, actuators, and so forth-that make the advanced products possible. 19 Similar sentiments were expressed by Davor Hrovat, senior staff technical spec

29、ialist at the Ford Research Laboratory in Dearborn, Mich.: The word singles out an area that perhaps is not a single area. Mechatronics is mixture of technologies and techniques that together help in designing better products. 20 However mechatronics is defined, it means we now have viable technolog

30、y for computer control of mechanical systems at all levels, from toasters to autos, said David M. Auslander, professor of mechanical engineering at Berkeley. Today we have mechanical systems for which performance is defined by whats in a computer, whether its software algorithms, neural networks, or

31、 fuzzy logic. That alone makes it different from anything you could do 25 years ago. 21 Auslander takes a very generalized view of the topic. Any system in which you control or modulate power is a candidate for computer control. For any mechanical component you can ask the question: What is its purp

32、ose? Does it transmit power? Or is its purpose control and coordination? Computers, software, and electronics can generally do this second function more efficiently-simpler, cheaper, with much more flexibility. This approach, he emphasized, constitutes a totally different view of how mechanical syst

33、ems work compared with previous conceptions. This is a machine viewed from the controls outward. 22 Following mechatronic principles, General Electrics Profile Super 32 clothes washer features a sensor-based feedback control that maintains correct water temperature no matter the load size 23 Conside