Document Type : Reseach Article
Authors
1 Belgorod State University, Belgorod, 308015,Russia
2 Belgorod State University, Belgorod, 308015, Russia
3 Vladimir State University, Vladimir, 600000, Russia
4 Orel State University by I. S. Turgenev 95 Komsomolskaya Str., Orel, Russia
Abstract
The functioning of a thermoelectric system in a stationary mode is often inefficient because it does not allow flexible control of the temperature regime. The design of thermoelectric devices and systems in transient modes requires identifying their dynamic models, first of all, the control object – the Peltier thermoelectric module. As a rule, well-known identification techniques involve calculating the parameters of a fractional-rational transfer function (or, equivalently, an autoregressive model) of the object of control. At the same time, the increase in the accuracy of identification requirements is associated with significant computational costs. The proposed identification technique requires the determination of the time dependencies of the control current and temperature deviation, the calculation of their spectra based on piecewise linear approximation, and the calculation of the transfer coefficient as the ratio of the spectra of the output and input signals. The calculated relations of piecewise linear approximating functions, spectral densities, and time forms of input and output parameters of the model under study are presented. The amplitude and phase frequency response of the Peltier module are calculated. The low RMS error in the identification of the amplitude-frequency characteristic and phase-frequency characteristic showed the effectiveness of the proposed identification technique.
Keywords
- [1] Anatychuk, L.I. “Thermoelements and thermoelectric devices”. Reference book, L.I. Anatychuk, Kiev: Naukova Dumka, 1979. - 768 p.
- [2] Anatychuk, L.I. “The current state and some prospects of thermoelectricity”, L.I. Anatychuk, Thermoelectricity, No. 2, 7-20, 2007.
- [3] Bulat, L. P., “Thermoelectric Cooling”, Petersburg State University of Refrigeration and Food Processing Technologies, St. Petersburg, 2002.
- [4] Malkovich, B.E.-Sh. “Thermoelectric modules based on bismuth telluride alloys”, Reports of the XI Interstate seminar "Thermoelectrics and their application". - St. Petersburg, 2008, 462-468, 2008.
- [5] O. Filin, B. Zakrzewski, “Modern state and prospects of development and production of stationary thermoelectric refrigerators”, Journal of thermoelectricity, no. 2. pp.71-84, 2008.
- [6] Nagase, A. Yamamoto, “Development of durability testing for thermoelectric power generation module”, Journal of Kinzoku materials science and technology, No. 3 pp.1347-1364, 2016.
- [7] Karami and N. Moubayed, "New modeling approach and validation of a thermoelectric generator," 2014 IEEE 23rd International Symposium on Industrial Electronics (ISIE), Istanbul, Turkey, 2014, pp. 586-591, doi: 10.1109/ISIE.2014.6864678.
- [8] Guiatni, M. & Drif, A. & Kheddar, Abderrahmane, “Thermoelectric Modules: Recursive non-linear ARMA modeling”, Identification and Robust Control. pp. 568 – 573, 2007. DOI: 10.1109/IECON.2007.4460142.
- [9] Guiatni, M., and Kheddar, A. "Modeling Identification and Control of Peltier Thermoelectic Modules for Telepresence." J. Dyn. Sys., Meas., Control. May 2011; vol. 133, no. 3, 031010. https://doi.org/10.1115/1.4003381.
- [10] Jui, J. J., M. A. Ahmad. “A Hybrid Metaheuristic Algorithm for Identification of Continuous-Time Hammerstein Systems”. Appl Math Model, Vol. 95, pp. 339-360, 2021.
- [11] Gotmare, A., R. Patidar, N. V. George. “Nonlinear System Identification Using a Cuckoo Search Optimized Adaptive Hammerstein Model”, Syst. Appl., Vol. 42, No 5, pp. 2538-2546, 2015.
- [12] A Duwaish, H. N. “Identification of Hammerstein Models with Known Nonlinearity Structure Using Particle Swarm Optimization”, J. of Sci. Eng., Vol. 36, No 7, pp. 1269-1276, 2011.
- [13] Cuevas, E., P. Díaz, O. Avalos, D. Zaldívar, M. Pérez-Cisneros, DE C P et al. “Nonlinear System Identification Based on ANFIS-Hammerstein Model Using Gravitational Search Algorithm”, Intell., Vol. 48, No 1, pp. 182-203, 2018.
- [14] Jui, J. J., M. H. Suid, Z. Musa, M. A. Ahmad. “Identification of Liquid Slosh Behavior Using Continuous-Time Hammerstein Model Based Sine Cosine Algorithm”, In: Proc. of 11th National Technical Seminar on Unmanned System Technology (NUSYS’19), 345-356, 2021.
- [15] -a. Photoon and W. Wichakool, "System identification of Thermoelectric generator using a first order plus dead time model," 2015 12th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON), Hua Hin, Thailand, 2015, pp. 1-5, doi: 10.1109/ECTICon.2015.7207047.
- [16] Yi Hu, Wanping Hu, Kai He [et al.]. “PSO Algorithm Based Thermoelectric Cooler Temperature Control System Design”, 2019 IEEE 3rd Advanced Information Management, Communicates, Electronic and Automation Control Conference (IMCEC), 2019.
- [17] Orlov M.E. “Theoretical foundations of heat engineering. Heat and mass transfer”, Ulyanovsk State Technical University. university. - Ulyanovsk : UlSTU, p. 204, 2013.
- [18] Kurilov, G. S. Vasiliev, S. M. Kharchuk, “Analysis of dynamic characteristics of signal converters based on continuous piecewise linear functions” , Scientific and technical Bulletin of the Volga region, No. 1. pp. 100-104, 2010.
- [19] Vasilyev, I. Kurilov and S. Kharhuk, "Research of static characteristics of converters of signals with a nonlinear control device," 2011 International Siberian Conference on Control and Communications (SIBCON), Krasnoyarsk, Russia, 2011, pp. 93-96, doi: 10.1109/SIBCON.2011.6072603.
- [20] S. Vasilyev, I. A. Kurilov, S. M. Kharchuk and D. I. Surzhik, "Analysis of dynamic characteristics of the nonlinear amplitude-phase converter at complex input influence," 2013 International Siberian Conference on Control and Communications (SIBCON), Krasnoyarsk, Russia, 2013, pp. 1-4, doi: 10.1109/SIBCON.2013.6693641.
- [21] J. Jui, M. A. Ahmad, M. S. Mohamed Ali, M. A. Zawawi, and M. F. Mat Jusof, “Identification of the Thermoelectric Cooler Using Hybrid Multi-Verse Optimizer and Sine Cosine Algorithm Based Continuous-Time Hammerstein Model”. Cybern. Inf. Technol. Vol. 21, No. 3 pp. 160–174, 2021. https://doi.org/10.2478/cait-2021-0036,
- [22] Huang, B. J., C. L. Duang. “System Dynamic Model and Temperature Control of a Thermoelectric Cooler”, J. of Refrigeration, Vol. 23, No 3, pp. 197-207, 2000.
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