APPLICATION OF THE SYNERGETIC SYNTHESIS METHOD TO IMPROVE THE QUALITY OF STEAM GENERATOR CONTROL

The possibility of improving the automated control system of the steam generator in peak modes is being considered to improve the stability indicators, increase the speed and efficiency of heat and power systems. To implement the control, it is proposed to use nonlinear models of the control object and synthesize the control system by methods based on new conceptual foundations that allow taking into account the phenomena of interconnectedness and nonlinearity of processes in thermal power units. The method of analytical design of aggregated regulators (ADAR) was chosen as the synthesis method. In the course of computer simulation, it is demonstrated that the synthesized control laws ensure the asymptotic stability of a closed nonlinear system and the fulfillment of specified technological invariants. To demonstrate the effectiveness of the obtained synergetic laws of robust control, a comparison with traditional laws was performed. This comparison shows that with similar dynamic characteristics of transients, traditional laws do not provide the desired value and are operable in a smaller range of load speed changes.

Название журналаTechnical science and innovation
Номер выпуска2023, №3(17)
Количество просмотров64

Ссылка в интернете

DOI

Дата создание в систему UzSCI07-12-2023

Количество прочтений64

Дата публикации23-10-2023

Язык статьиIngliz

Страницы81-93

Ключевые слова

robust control

control system

invariant

synergetic control theory

Thermal power systems

steam generator

excitation system

control laws

English

The possibility of improving the automated control system of the steam generator in peak modes is being considered to improve the stability indicators, increase the speed and efficiency of heat and power systems. To implement the control, it is proposed to use nonlinear models of the control object and synthesize the control system by methods based on new conceptual foundations that allow taking into account the phenomena of interconnectedness and nonlinearity of processes in thermal power units. The method of analytical design of aggregated regulators (ADAR) was chosen as the synthesis method. In the course of computer simulation, it is demonstrated that the synthesized control laws ensure the asymptotic stability of a closed nonlinear system and the fulfillment of specified technological invariants. To demonstrate the effectiveness of the obtained synergetic laws of robust control, a comparison with traditional laws was performed. This comparison shows that with similar dynamic characteristics of transients, traditional laws do not provide the desired value and are operable in a smaller range of load speed changes.

Ключевые слова

robust control

control system

invariant

synergetic control theory

Thermal power systems

steam generator

excitation system

control laws

№ Имя автора Должность Наименование организации

1 Siddikov I.X. teacher TDTU

2 Umurzakova D.M. master 2Fergana branch of Tashkent University of Information Technologies

№ Название ссылки

1 1. I.X. Siddikov., D.M. Umurzakova. Simulation of a two-level control system for nonlinear dynamic objects with a neurofuzzy adaptive regulator. “International conference on information science and communications technologies applications, trends and opportunities“, 2021.

2 2. H. Unbehauen., I. Kosaarslan. Experimental modelling and adaptive power control of 750 MV once-through boiler. “Prepr. 11th IFAC World congress on automatic control“, Estonia, 1990. 32.

3 3. M.G. Na., H.C. No. Design of an adaptive observer-based controller for the water level of steam generators. “Nuclear engineering and design“, 1992. 379.

4 4. K.J. Astrom., R.D. Bell. Drum-boiler dynamics. “Automatica“, 2000. 363.

5 5. D.M. Umurzakova. System of automatic control of the level of steam power generators on the basis of the regulation circuit with smoothing of the signal. “IIUM Engineering Journal“, 2021. 287

6 6. D.M. Umurzakova. mathematical modeling of transient processes of a three-pulse system of automatic control of water supply to the steam generator when the load changes. “14th International IEEE scientific and technical conference dynamics of systems, mechanisms and machines, dynamics proceedings“, 2020.

7 7. X. Zhu., H. Zhang., D. Cao., Z. Fang. Robust control of integrated motor-transmission powertrain system over controller area network for automotive applications. “Mechanical systems and signal processing“, 2014. 15.

8 8. M. Zulfatman., F. Rahmat. Application of self-tuning Fuzzy PID controller on industrial hydraulic actuator using system identification approach. “International journal on smart sensing and intelligent systems“, 2009. 246.

9 9. S. Das., I. Pan., K. Halder., A. Gupta. LQR based improved discrete PID controller design via optimum selection of weighting matrices using fractional order integral performance index. “Applied mathematical modelling: simulation and computation for engineering and environmental systems“, 2013. 4253.

10 10. B. Gasbaoui., A. Nasri. A novel multi-drive electric vehicle system control based on multi-input multi-output PID controller, “Serbian journal of electrical engineering“, 2012. 279.

11 11. Z. Has., A.H. Muslim., N.A. Mardiyah. Adaptive-fuzzy-PID controller based disturbance observer for DC motor speed control. “4th International Conference on Electrical Engineering, Computer Science and Informatics (EECSI)“, 2017. 8.

12 12. S. Hu., Z. Liang., W. Zhang., X. He. Research on the integration of hybrid energy storage system and dual three-phase PMSM Drive in EV. “IEEE Transactions on Industrial Electronics“, 2018. 6602.

13 13. S. Iplikci. A comparative study on a novel model-based PID tuning and control mechanism for nonlinear systems. “International journal of robust and nonlinear control“, 2010. 1483.

14 14. M. Jaiswal., M. Phadnis. Speed control of DC motor using genetic algorithm based PID controller. “International journal of advanced research in computer science and software engineering“, 2013. 2277.

15 15. A. Kalangadan., N. Priya., T.K. Kumar. PI, PID controller design for interval systems using frequency response model matching technique. “International conference on control, communication and computing“, India, 2015. 119.

16 16. S.M.G. Kumar., J. Deepak., R.K. Anoop. PSO based tuning of a PID controller for a High performance drilling machine. “International journal of computer applications“, 2010. 12.

17 17. C. Lu., C. Hsu., C. Juang. Coordinated control of flexible AC transmission system devices using an evolutionary fuzzy lead-lag controller with advanced continuous ant colony optimization. “IEEE transactions on power systems“, 2019. 385.

18 18. D. Pelusi. PID and intelligent controllers for optimal timing performances of industrial actuators. “International journal of simulation: systems, science and technology“, 2012. 65.

19 19. D. Pelusi., R. Mascella. Optimal control algorithms for second order systems. “Journal of computer science“, 2013. 183.

В ожидании

№	Имя автора	Должность	Наименование организации
1	Siddikov I.X.	teacher	TDTU
2	Umurzakova D.M.	master	2Fergana branch of Tashkent University of Information Technologies

№	Название ссылки
1	1. I.X. Siddikov., D.M. Umurzakova. Simulation of a two-level control system for nonlinear dynamic objects with a neurofuzzy adaptive regulator. “International conference on information science and communications technologies applications, trends and opportunities“, 2021.
2	2. H. Unbehauen., I. Kosaarslan. Experimental modelling and adaptive power control of 750 MV once-through boiler. “Prepr. 11th IFAC World congress on automatic control“, Estonia, 1990. 32.
3	3. M.G. Na., H.C. No. Design of an adaptive observer-based controller for the water level of steam generators. “Nuclear engineering and design“, 1992. 379.
4	4. K.J. Astrom., R.D. Bell. Drum-boiler dynamics. “Automatica“, 2000. 363.
5	5. D.M. Umurzakova. System of automatic control of the level of steam power generators on the basis of the regulation circuit with smoothing of the signal. “IIUM Engineering Journal“, 2021. 287
6	6. D.M. Umurzakova. mathematical modeling of transient processes of a three-pulse system of automatic control of water supply to the steam generator when the load changes. “14th International IEEE scientific and technical conference dynamics of systems, mechanisms and machines, dynamics proceedings“, 2020.
7	7. X. Zhu., H. Zhang., D. Cao., Z. Fang. Robust control of integrated motor-transmission powertrain system over controller area network for automotive applications. “Mechanical systems and signal processing“, 2014. 15.
8	8. M. Zulfatman., F. Rahmat. Application of self-tuning Fuzzy PID controller on industrial hydraulic actuator using system identification approach. “International journal on smart sensing and intelligent systems“, 2009. 246.
9	9. S. Das., I. Pan., K. Halder., A. Gupta. LQR based improved discrete PID controller design via optimum selection of weighting matrices using fractional order integral performance index. “Applied mathematical modelling: simulation and computation for engineering and environmental systems“, 2013. 4253.
10	10. B. Gasbaoui., A. Nasri. A novel multi-drive electric vehicle system control based on multi-input multi-output PID controller, “Serbian journal of electrical engineering“, 2012. 279.
11	11. Z. Has., A.H. Muslim., N.A. Mardiyah. Adaptive-fuzzy-PID controller based disturbance observer for DC motor speed control. “4th International Conference on Electrical Engineering, Computer Science and Informatics (EECSI)“, 2017. 8.
12	12. S. Hu., Z. Liang., W. Zhang., X. He. Research on the integration of hybrid energy storage system and dual three-phase PMSM Drive in EV. “IEEE Transactions on Industrial Electronics“, 2018. 6602.
13	13. S. Iplikci. A comparative study on a novel model-based PID tuning and control mechanism for nonlinear systems. “International journal of robust and nonlinear control“, 2010. 1483.
14	14. M. Jaiswal., M. Phadnis. Speed control of DC motor using genetic algorithm based PID controller. “International journal of advanced research in computer science and software engineering“, 2013. 2277.
15	15. A. Kalangadan., N. Priya., T.K. Kumar. PI, PID controller design for interval systems using frequency response model matching technique. “International conference on control, communication and computing“, India, 2015. 119.
16	16. S.M.G. Kumar., J. Deepak., R.K. Anoop. PSO based tuning of a PID controller for a High performance drilling machine. “International journal of computer applications“, 2010. 12.
17	17. C. Lu., C. Hsu., C. Juang. Coordinated control of flexible AC transmission system devices using an evolutionary fuzzy lead-lag controller with advanced continuous ant colony optimization. “IEEE transactions on power systems“, 2019. 385.
18	18. D. Pelusi. PID and intelligent controllers for optimal timing performances of industrial actuators. “International journal of simulation: systems, science and technology“, 2012. 65.
19	19. D. Pelusi., R. Mascella. Optimal control algorithms for second order systems. “Journal of computer science“, 2013. 183.