电气工程-自动化-外文翻译-外文文献-英文文献-PLC未来发展趋势.doc

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1、 4th International DAAAM Conference INDUSTRIAL ENGINEERING INNOVATION AS COMPETITIVE EDGE FOR SME 29 - 30th April 2004, Tallinn, Estonia PROGRAMMABLE LOGIC CONTROLLERS IN PROCESS AUTOMATION Ahti Mikkor, Lembit RoosimlderDepartment of Product Development, Institute of Machinery, Tallinn Technical Uni

2、versity, Ehitajate tee 5, 19086 Tallinn, Estonia ahti.mikkor Abstract: Nowadays, control problems are solved using operating components from a wide variety of technologies: electronics, hydraulics, pneumatics and mechanics. Functio-nality, reliability and price of the controlled system are deter-min

3、ed by the quality of the solution made. The paper concentrates on practical use of programmable logic controllers (PLC) that is based on the five years project development experience in this area. Successful solutions and problems are under focus. Specific hardware, controller programming problems,

4、data/signals exchange and human machine interfaces are considered. As a result the method for selecting programmable controllers according to specific needs is developed. Practical suggestions, possible hazards and warnings are proposed that could help to avoid mistakes. Key words: programmable cont

5、rollers, PLC, automation, automation systems, process automation. 1. INTRODUCTION Modern machinery consists of both mechanical and electronic parts. Overall functionality is determined by “balance” between these components. Initial planning and solution selection plays critical role in final result.

6、 In control methods the selection has to be made between relay-based circuits, special devices, programmable logic controllers (PLC) and new development electronics. This article is concentrated on PLC-s and experience that has collected over 5-year practical work with PLC-s. Strong and weak sides,

7、positive and negative practices are discussed. Suggestions weather to use programmable controllers or not have been formed to help decision making. The most important decision in planning PLC-based system is selecting processor type. Mistakes mean extra costs for modifications or even need for compl

8、etely new devices. The most common error is overestimating programming possibilities of small-sized processors. There are several methods for selecting PLC. Unfortunately most of them focus on electrical side of PLC-s and maximum count of signals allowed. They dont involve analysis to determine poss

9、ible special needs for user program or communications. Based on several existing methods, practical experience and future trends a new method for selecting PLC was developed. Ahti Mikkor has gained his experience by taking part in more than 15 big-scale automation projects. These projects include de

10、velopment of power consumption monitoring system in AS Kunda Nordic Cement factory, renewing testing rig for flowmeters, building Ahtme powerplant turbine safety systems, water treatment plants in towns Rakvere and Plva, waste water treatment plant in town Jgeva and development of monitoring system

11、for central heating network in Tartu.2. PROS AND CONS IN USING PROGRAMMABLE LOGIC CONTROLLERS 2.1 Positive arguments The main advantage that programmable controllers provide is flexibility (Jack, 2003). Behaviour of the system can be easily changed via program without any other alterations. Special

12、devices for example make any changes in control algorithm very hard to implement. Flexibility makes PLC-s well suitable for frequently changed applications, for example in robotics. In PLC-s the relations between inputs and outputs are determined by user program. By using advanced programming techno

13、logies it is much easier to implement complex control algorithms than in any hard-wired solutions. It makes PLC-s very competitive for complex tasks, for example in controlling chemical processes. Special modules allow vast amount of different signals to be connected to the PLC system. Use of PLC-s

14、should be considered in applications that require some “special” input or output signals. Typical example would be positioning using reference data from high-speed input. Typically PC visualization software packages are made for PLC-s. Some special devices have also PC software packages. Wide range

15、of communication options between PLC-s makes it possible to gather all information from field devices into one central control point. Communication lines between PLC-s allow using information collected from other parts of the system in local process control. Modern communication technologies enable

16、remote diagnostics and configuration (Jack, 2003). These two significantly reduce overall maintenance costs of the system. 2.2 Negative arguments Programmable controllers are not equipped with enough memory to store big amounts of data. Although future trends show growth in PLC memory sizes, special

17、 devices (recorders) are still better suited for standalone datalogging applications. For networked solutions there is possibility to use visualization software packages together with PLC-s to archive collected data in any database format necessary. If logged data amounts are small or there are also

18、 control functions included, its reasonable to still use PLC-s. About visualization software packages its good to know that in standard versions most of them do not support offline recording so that after communication breakdown it is not possible to acquire data backwards from PLC. Modern communica

19、tion options for PLC-s include standard protocols for example Ethernet. It is tempting to use existing office networks also as data carrier for automation system communications. Time has shown that it is better practice to keep these two separated if there is a need for constant online communication

20、. Hardly traceable temporal network overloads can cause problems also in automation system communications All PLC-s need be programmed. All programming works include risk for accidental errors in control algorithm. Special devices are well tested and generally free of this kind of problems. If avail

21、able, its economically thoughtful to use special devices. Safety applications that require highest degree of reliability should contain simplest devices and circuits possible. There is a rule that every new link in chain decreases overall reliability. In small applications its often cost saving to u

22、se relay-based circuits instead of PLC-s. 3. FUTURE TRENDS Progress in process automation systems is aiming at so called complete automation when all the human has to do is to enter the parameters of the product wanted and everything else is carried out by machines (Rosin, 2000). Although the destin

23、ation lies far ahead, trends indicate movement in that direction. Firstly, systems become more and more standardized. Big manufacturers organize their products into families. The aim is to reduce amount of knowledge needed for configuration and maintenance works of different devices from same compan

24、y. Its also important that this way built applications are easily expandable. Secondly, importance of communication is rising (Hughes, 2000). There are many reasons, some of more essentials are: Better collaboration of different parts of the system. Cutting costs on cabling. Less cabling results fal

25、l in fault probability, but also increases severity of ones that occur. Sensors and actuators can be at longer distances from the processor module than if using conventional methods. Increased scalability of the systems. New devices can be added at minimal costs. At some cases it is better to make a

26、rchitecture of many small independent modules and network them. This solution enables system to keep working although some parts have failed. Communication networks ease fault diagnostics and provide remote management possibilities. Central operating stations can be formed relatively easy. Possibili

27、ty to connect devices form different manufacturers (OPC Foundation, 2003). Third important tendency is spreading use of so called software controllers or Soft PLC-s (Siemens AG, 2003). These are PC software-based solutions that relate with field devices via communication networks. There is no need f

28、or processor module, resources of PC are used. Some Soft PLC-s are still formed as processor cards for PC (figure 1). Reliable communication networks are essential. Soft PLC-s are well suited for data acquisition applications because of data storage possibilities of PC-s. Figure 1. Siemens Simatic W

29、inAC Slot PLC 412Fourthly, combo-devices (figure 2) that contain both operator panel and medium size processor module gain popularity (Siemens AG, 2002). In this solution possibility of disturbances is low and reuse of some components make whole package cheaper. Figure 2. Combo device Siemens Simati

30、c C7-613 Fifthly, processor software takes over properties from PC software. Data collected from production can be easily transferred into office applications (Siemens AG, 2000). 4. METHOD FOR SELECTING PROGRAMMABLE CONTROLLER A method for forming an application specific list of required properties

31、for selecting programmable controller was developed. There are nine criterions and the results are presented in Table 1. Selection is made by comparing results table with controllers technical data. Following is short description of every criteria involved. Nature of solution determines weather it i

32、s expanding of old system or completely new development. In first case the architecture of system and hardware requirements are limited by already existing solution. Using hardware from same company makes servicing easier and avoids integration problems that would occur when using products form diff

33、erent manufacturers. For example many hardware producers integrate their own specific communication interfaces directly into processor module and for every universal protocol a special module is needed (Siemens AG, 2003). It is also possible to reduce spare part stock amounts when using same type ha

34、rdware all over the system. Maximum number of electrical inputs-outputs allowed is classical criteria to determine processor class. If complex control algorithms and non-standard functions are needed, its not the most important parameter any more. Generally it is money saving to use one bigger proce

35、ssor module for input-output signals that originate from nearby locations than several smaller ones. In this case there will be no need for communication network and programming will be easier too. Special signals and modules are usually available for medium and large controller families only. Many

36、microcontrollers do not even have possibility to add analogue output (Siemens AG, 2003). In some cases using special modules is the only way, in other ones (positioning) it is just an opportunity to save money. Layouts of sensors and actuators can be very different, sometimes the sensors are located

37、 several kilometres away from the actuator (pumping liquids in long pipes). In this case special communication network (Profibus, AS-inteface) might be the only solution. If not, it can at least save costs by reducing cabling works. Not all programmable controllers have interfaces for communication

38、protocols. Properties of processor have important role in complex applications. Most common problem is lack of programming memory, sometimes also data memory. Memory requirements can be estimated by number of input and output signals. But in practice 100 digital input-output points system often has

39、3 times smaller program than 10 digital input-output points system. The only way to estimate program size exactly is using previous experience. Program specialities include special program functions needed. Different areas of applications have some typically used functions, for example temperature c

40、ontrol in building automation. Programming is much simpler if these functions are already built into system software of processor. In process automation 2 digital output (up-down) closed loop PID regulation is quite often used. It might be a surprise but its not included in most of the microcontroll

41、ers (Siemens AG, 2003) and for average programmer its too complicated task to create his own regulator using standard functions. Basically there are 2 solutions: either to avoid this construction or to use applicable controller. Table 1. Table for method results Communication is becoming more import

42、ant in nowadays automation systems. In some cases non-standardised devices as barcode readers or electronic weights have to be included into the system. Then its vital to have functions for protocol programming (freeport programming). Standardised protocols demand existence of specific modules. Work

43、ing conditions can usually be overcome by using special cabinets, but there are also specific series of programmable controllers that have improved resistance for electromagnetic disturbances, humidity and vibrations. In very dusty environments all cooling ventilators have to be equipped withfilters

44、.5. CONCLUSIONS Main benefits of programmable controllers are: flexibility communication possibilities realisation of complex control algorithms reliability Alternative solutions should be considered if: system is very simple special devices are available data recording is necessary Initial selectio

45、n of appropriate solution and hardware has great influence on final result. Mistakes in this step significantly increase overall budget of project as some programs might have to be changed and some hardware replaced. Based on his practical experience the author has formed a method for selecting prog

46、rammable controller. It has 9 criterias: nature of solution (new or existing) maximum number of electrical inputs-outputs allowed (digital, analogue, inputs, outputs) need for special modules (high-speed digital outputs) layout of sensors and actuators (local or periphery) properties of processor (p

47、rogram and data memory) program specialities (special functions) communication needs (Profibus, ASCII) working conditions (humidity, temperature, vibration, dust) Method is not guaranteed to always point out the best selection, but using it certainly avoids mistakes. 6. REFERENCES Hughes, T. A. Prog

48、rammable Controllers, Third Edition. ISA The Instrumentation, Systems, and Automation Society, 2000, 334 p. Jack, H. Automating Manufacturing Systems with PLC-s, 828 p., Available: http:/claymore.engineer.gvsu.edu/jackh/books/plcs/pdf/plcbook4_2.pdf, Accessed: 3.10.2003 LOGO! Manual. Siemens AG, 2003, 312 p. OPC Foundation homepage: http:/www.opcfoundation.org/, Accessed: 9.11.2003 Rosin, A. Programmable Controllers Simatic S7. Tallinn, TTU, 2000, 120 p. Master Thesis in Estonian. Berger, H. Automating with SIMATIC. Siemens AG, 2003, 214 p. SIMATIC Programming with STEP 7 V