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The paper is devoted to the control of operability of Peltier modules based on the analysis of transient modes of their operation. Advantages of using low-power thermoelectric modules for the development of thermoelectric plants with adaptive control systems for the needs of the agricultural complex, which significantly reduce their cost characteristics, are shown. The problem of using the stationary mode of their operation, associated with the low efficiency of the modules, as well as the dynamic mode, associated with the presence of transient processes, is indicated. It is noted that overcoming this problem requires solution of the task of automation of reliability providing the well-known approaches to its solution are shown, for which the key advantages and disadvantages are given. An approach is proposed to complex control of the operability and quality of thermoelectric modules during their expluatation in three components of the physical process of thermoelectric conversion (Peltier thermoelectric effect, electrical and thermal transfer phenomena) by analyzing transients in the system based on identification algorithms. To justify it, the necessary equations and mathematical relations are given. Aprobating of the proposed approach was carried out experimentally by determining the time constants for operable and defective commercially available modules and showed its significant advantages over the standard verification procedure.
Czasopismo
Rocznik
Tom
Strony
31--42
Opis fizyczny
Bibliogr. 22 poz., rys., tab., wykr., wz.
Twórcy
- Belgorod State University, Pobedy 85, 308015 Belgorod, Russia
- Russian State Agrarian University – Moscow Timiryazev Agricultural Academy, Listvennichnaya 5, 127550 Moscow, Russia
autor
- Belgorod State University, Pobedy 85, 308015 Belgorod, Russia
autor
- Belgorod State University, Pobedy 85, 308015 Belgorod, Russia
Bibliografia
- [1] Kwan T.H., Ikeuchi D., Yao Q.: Application of the Peltier sub-cooled trans-critical carbon dioxide heat pump system for water heating – Modelling and performance analysis. Energ. Convers. Manage. 185(2019), 574–585.
- [2] Anatychuk L.I.: Current state and some prospects of thermoelectricity. Thermoelectricity (2007), 2, 7–20.
- [3] Bulat L.P.: Thermoelectric Cooling. Saint Petersburg University, St. Petersburg 2002.
- [4] Malkovich B.E.-Sh.: Thermoelectric modules based on bismuth telluride alloys. In: Rep. of the XI Interstate Seminar ‘Thermoelectrics and their Application’, St. Petersburg 2008, 462–468.
- [5] Filin S.O., Zakrzewski B.: Modern state and prospects of development and production of stationary thermoelectric refrigerators. J. Thermoelectricity (2008), 2, 71–74.
- [6] Ravisha M., Raghunatha K.R., Mamatha A.L., Shivakumara I.S.: Boundary effects on electrothermal convection in a dielectric fluid layer. Arch. Thermodyn. 40(2019), 1, 3–19.
- [7] Kajikawa T., Funahami R.: The latest developments in the field of technology of thermoelectric power generation in Japan. Thermoelectricity (2016), 1, 5–17.
- [8] Trofimov V.E.: The heat storage panel for maintaining the microclimate in a room with electronic equipment. Technol. Des. Elect. Equip. (2017), 3, 36–39.
- [9] Krueger, P. S., Hahsler, M., Olinick, E. V., Williams, S. H., & Zharfa, M.: Quantitative classification of vortical flows based on topological features using graph matching. Proc. Roy. Soc. A., (2019), 475.2228: 20180897.
- [10] Sulin A.B.: Thermoelectric cooling systems. Analysis of losses and ways to improve efficiency. Refrig. Equip. (2009), 8, 36–39.
- [11] Bellcore: Reliabilities Assurance Practices for Optoelectronic Devices in Loop Applications. Bell Commun. Res., Techn. Adv. TA-NWT-000983 (1993), 2, 5–15.
- [12] Wang J., Cao P., Li X., Song X., Zhao C., Zhu L.: Experimental study on the influence of Peltier effect on the output performance of thermoelectric generator and deviation of maximum power point. Energ. Convers. Manage. 200(2019), 112074.
- [13] Babin V.P., Gorodetskiy S.M.: Thermoelectric modules quality testing by a manufacturer. In: Proc. XIV Int. Conf. on Thermoelectrics, June 27-30.1995, St. Petersburg, 338–340.
- [14] Ziman J.M.: Thermoelectrics: Basic Principles and New Material Developments. Clarendon Press, Oxford 1960.
- [15] Chen G.: Nanoscale Energy Transport and Conversion. Oxford University Press, Oxford 2005.
- [16] Ioffe A.F.: Semiconductor Thermoelements and Thermoelectric Cooling. Infosearch, London 1957.
- [17] Rowe D.M.: CRC Handbook of Thermoelectrics. CRC Press, Boca Raton 1995.
- [18] Lee H.S.: Thermal Design: Heat Sinks, Thermoelectrics, Heat Pipes, Compact Heat Exchangers, and Solar Cells. Wiley & Sons, Hoboken 2010.
- [19] Verma S., Mohapatra S., Chowdhury S„ Dwivedi G.: Cooling techniques of the PV module: A review. Mater. Today–Proc. 38(2021), 1, 253–258
- [20] Kuzichkin O.R., Tsaplev A.V.: Temperature correction of the results of geomonitoring studies based on parametric models of media. Des. Technol. Elect. Tools (2007), 2, 39–43.
- [21] Bykov A.A., Kuzichkin O.R.: Regression prediction algorithm of suffusion processes development during geoelectric monitoring. Adv. Envir. Biol. (2014), 8, 1404–1410.
- [22] RMT: Thermoelectric Module, 1MC06-030-05 datasheet, Performace parameters, www.rmtltd.ru/datasheets/1mc06030h.pdf (accessed 10 Apr. 2020).
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-dba00f70-80c9-40e5-805a-3db477415219