版權(quán)說明:本文檔由用戶提供并上傳,收益歸屬內(nèi)容提供方,若內(nèi)容存在侵權(quán),請進(jìn)行舉報或認(rèn)領(lǐng)
文檔簡介
1、Advanced control algorithms for steam temperature regulation of thermal power plantsA. Sanchez-Lopez, G. Arroyo-Figueroa*, A. Villavicencio-RamirezInstituto de Investigaciones Electricas, Division de Sistemas de Control,
2、 Reforma No. 113, Colonia Palmira, Cuernavaca, Morelos 62490, MexicoReceived 5 February 2003; revised 6 April 2004; accepted 8 July 2004AbstractA model-based controller (Dynamic Matrix Control) and an intelligent control
3、ler (Fuzzy Logic Control) have been designed and implemented for steam temperature regulation of a 300 MW thermal power plant. The temperature regulation is considered the most demanded control loop in the steam generati
4、on process. Both proposed controllers Dynamic Matrix Controller (DMC) and Fuzzy Logic Controller (FLC) were applied to regulate superheated and reheated steam temperature. The results show that the FLC controller has a b
5、etter performance than advanced model-based controller, such as DMC or a conventional PID controller. The main benefits are the reduction of the overshoot and the tighter regulation of the steam temperatures. FLC control
6、lers can achieve good result for complex nonlinear processes with dynamic variation or with long delay times. q 2004 Elsevier Ltd. All rights reserved.Keywords: Thermal power plants; Power plant control; Steam temperatur
7、e regulation; Predictive control; Fuzzy logic control1. IntroductionCurrent economic and environment factors put a stringer requirement on thermal power plants to be operated at a high level of efficiency and safety at m
8、inimum cost. In addition, there are an increment of the age of thermal plants that affected the reliability and performance of the plants. These factors have increased the complexity of power control systems operations [
9、1,2]. Currently, the computer and information technology have been extensively used in thermal plant process operation and control. Distributed control systems (DCS) and management information systems (MIS) have been pla
10、ying an important role to show the plant status. The main function of DCS is to handle normal disturbances and maintain key process parameters in pre-specified local optimal levels. Despite their great success, DCS have
11、little function for abnormal and non-routine operation because the classical proportional-integral-derivative (PID) controlis widely used by the DCS. PID controllers exhibit poor performance when applied to process conta
12、ining unknown non-linearity and time delays. The complexity of these problems and the difficulties in implementing conventional controllers to eliminate variations in PID tuning motivate the use of other kind of controll
13、ers, such as model-based controllers and intelligent controllers. This paper proposes a model-based controller such as Dynamic Matrix Controller (DMC) and an intelligent controller based on fuzzy logic as an alternative
14、control strategy applied to regulate the steam temperature of the thermal power plant. The temperature regulation is considered the most demanded control loop in the steam generation process. The steam temperature deviat
15、ion must be kept within a tight variation rank in order to assure safe operation, improve efficiency and increase the life span of the equipment. Moreover, there are many mutual inter- actions between steam temperature c
16、ontrol loops that have been considered. Other important factor is the time delay. It is well know that the time delay makes the temperature loops hard to tune. The complexity of these problems and difficulties to impleme
17、nt PID conventional controllers motivate to research the use of model predictive controllers0142-0615/$ - see front matter q 2004 Elsevier Ltd. All rights reserved. doi:10.1016/j.ijepes.2004.08.003Electrical Power and En
18、ergy Systems 26 (2004) 779–785www.elsevier.com/locate/ijepes* Corresponding author. Tel.: C52777 3623820; fax: C52777 328985. E-mail addresses: jasl@iie.org.mx (A. Sanchez-Lopez), garroyo@ iie.org.mx (G. Arroyo-Figueroa)
19、.a vector. This vector is based on previous control actions and current values of the process. (d) Calculation of control movements. Control movements are obtained using the future vector of error and the dynamic matrix
20、of the process. The equation developed to obtain the control movements is shown below:Dþ ¼ ATA þ f2I ? ?K1ATXþ (2)where A represents the dynamic matrix, AT the transpose matrix of A X the vector of fu
21、ture states of the process, f a weighting factor, I the image matrix and? D the future control actions. Further details about this equation are found in Ref. [5]. (e) Control movements’ implementation. In this step the f
22、irst element of the control movements’ vector is applied to manipulated variables.A DMC controller allows designers the use of time domain information to create a process model. The mathematical method for prediction mat
23、ches the predicted behavior and the actual behavior of the process to predict the next state of the process. However, the process model is not continuously updated because this involves recalcula- tions that can lead to
24、an overload of processors and performance degradation. Discrepancies in the real behavior of the process and the predicted state are considered only in the current calculation of control movements. Thus, the controller i
25、s adjusted continuously based on deviations of the predicted and real behavior while the model remains static.3. Fuzzy logic controlFuzzy control is used when the process follows some general operating characteristic and
26、 a detailed process understanding is unknown or process model become overly complex. The capability to qualitatively capture the attributes of a control system based on observable phenom- ena and the capability to model
27、the nonlinearities for the process are the main features of fuzzy control. The ability of Fuzzy Logic to capture system dynamics qualitatively and execute this qualitative schema in a real time situation is an attractive
28、 feature for temperature control systems [8]. The essential part of the FLC is a set of linguistic control rules related to the dual concepts of fuzzy implication and the compositional rule of inference [9]. Essentially,
29、 the fuzzy controller provides an algorithm that can convert the linguistic control strategy, based on expert knowledge, into an automatic control strategy. In general, the basic configuration of a fuzzy controller has f
30、ive main modules as it is shown in Fig. 4. In the first module, a quantization module converts to discrete values and normalizes the universe of discourse ofvarious manipulated variables (Input). Then, a numerical fuzzy
31、converter maps crisp data to fuzzy numbers characterized by a fuzzy set and a linguistic label (Fuzzification). In the next module, the inference engine applies the compositional rule of inference to the rule base in ord
32、er to derive fuzzy values of the control signal from the input facts of the controller. Finally, a symbolic-numerical interface known as defuzzification module provides a numerical value of the control signal or incremen
33、t in the control action. This is integrated by a fuzzy-numerical converter and a dequantization module (output). Thus the necessary steps to build a fuzzy control system are Refs. [10,11]: (a) input and output variables
34、represen- tation in linguistic terms within a discourse universe; (b) definition of membership functions that will convert the process input variables to fuzzy sets; (c) knowledge base configuration; (d) design of the in
35、ference unit that will relate input data to fuzzy rules of the knowledge base; and (e) design of the module that will convert the fuzzy control actions into physical control actions.4. ImplementationThe control of the st
36、eam temperature is performed by two methods. One of them is to spray water in the steam flow, mainly before the super-heater (Fig. 5). The sprayed water must be strictly regulated in order to avoid the steam temperature
37、to exceed the design temperature range of G1% (G5 8C). This guaranties the correct operation of the process, improvement of the efficiency and extension of the lifetime of the equipment. The excess of sprayed water in th
38、e process can result in degradation of the turbine. The water in liquid phase impacts on the turbine’s blades. The other process to control the steam temperature is to change the burner slope in the furnace, mainly in th
溫馨提示
- 1. 本站所有資源如無特殊說明,都需要本地電腦安裝OFFICE2007和PDF閱讀器。圖紙軟件為CAD,CAXA,PROE,UG,SolidWorks等.壓縮文件請下載最新的WinRAR軟件解壓。
- 2. 本站的文檔不包含任何第三方提供的附件圖紙等,如果需要附件,請聯(lián)系上傳者。文件的所有權(quán)益歸上傳用戶所有。
- 3. 本站RAR壓縮包中若帶圖紙,網(wǎng)頁內(nèi)容里面會有圖紙預(yù)覽,若沒有圖紙預(yù)覽就沒有圖紙。
- 4. 未經(jīng)權(quán)益所有人同意不得將文件中的內(nèi)容挪作商業(yè)或盈利用途。
- 5. 眾賞文庫僅提供信息存儲空間,僅對用戶上傳內(nèi)容的表現(xiàn)方式做保護(hù)處理,對用戶上傳分享的文檔內(nèi)容本身不做任何修改或編輯,并不能對任何下載內(nèi)容負(fù)責(zé)。
- 6. 下載文件中如有侵權(quán)或不適當(dāng)內(nèi)容,請與我們聯(lián)系,我們立即糾正。
- 7. 本站不保證下載資源的準(zhǔn)確性、安全性和完整性, 同時也不承擔(dān)用戶因使用這些下載資源對自己和他人造成任何形式的傷害或損失。
最新文檔
- 外文翻譯--- 火力發(fā)電廠先進(jìn)的蒸汽溫度調(diào)節(jié)控制算法
- 外文翻譯--- 火力發(fā)電廠先進(jìn)的蒸汽溫度調(diào)節(jié)控制算法
- 外文翻譯--- 火力發(fā)電廠先進(jìn)的蒸汽溫度調(diào)節(jié)控制算法
- 外文翻譯--- 火力發(fā)電廠先進(jìn)的蒸汽溫度調(diào)節(jié)控制算法.docx
- 外文翻譯--- 火力發(fā)電廠先進(jìn)的蒸汽溫度調(diào)節(jié)控制算法.docx
- 火力發(fā)電廠
- 火力發(fā)電廠概況 發(fā)電廠作業(yè)
- 火力發(fā)電廠消防規(guī)程
- 火力發(fā)電廠概述ppt
- 火力發(fā)電廠集散控制系統(tǒng)
- 火力發(fā)電廠蒸汽管道的熱應(yīng)力研究.pdf
- 火力發(fā)電廠控制系統(tǒng)的配置
- 火力發(fā)電廠焊接質(zhì)量的監(jiān)理控制
- 全國地方小型火力發(fā)電廠
- 火力發(fā)電廠課程設(shè)計
- 火力發(fā)電廠畢業(yè)設(shè)計
- 火力發(fā)電廠畢業(yè)設(shè)計
- 火力發(fā)電廠基本知識
- 火力發(fā)電廠安全管理淺析
- 火力發(fā)電廠學(xué)習(xí)報告總結(jié)
評論
0/150
提交評論