Identyfikatory
Warianty tytułu
Analiza matematyczna dwuczęstotliwościowego systemu nagrzewania indukcyjnego
Języki publikacji
Abstrakty
The aim of this research work is to obtain analytical expressions that allow analyzing the dual-frequency current of the induction coil, as well as, the currents of the inverters for the “two inverter power supplies” converter topology. To take into account frequency-dependent parameters of an induction heater load, their implementation is shown through series-parallel connections of frequency-independent resistances and inductances. A simulation study is performed to verify the obtained analytical expressions of the currents.
Celem artykułu było otrzymanie analitycznego opisu umożliwiającego analizę prądu podwójnej częstotliwości stosowanego w nagrzewaniu indukcyjnym. Analizowano prąd w cewce oraz współpracującego z nią przekształtnika. Przeprowadzono też symulację potwierdzającą model analityczny.
Wydawca
Czasopismo
Rocznik
Tom
Strony
69--74
Opis fizyczny
Bibliogr. 29 poz., rys.
Twórcy
autor
- Institute of Electrodynamics of the National Academy of Sciences of Ukraine, 56 Peremohy prosp., office 457, 03680, Kyiv, Ukraine
Bibliografia
- [1] Lucia O., Maussion P., Dede E.J., Burdio J.M., Induction heating technology and its applications: past developments, current technology, and future challenges, IEEE Transactions on Industrial Electronics, 61 (2014), No. 5, 2509-2520
- [2] Rudnev V., Single-coil dual-frequency induction hardening of gears, Heat Treating Progress, 9 (2009), No. 6, 9-11
- [3] Schwenk W.R., Simultaneous dual-frequency induction hardening, Heat Treating Progress, (2003), 35-38
- [4] Przylucki R., Smalcerz A., Induction heating of gears - Pulsing dual-frequency concept, Metalurgija, 52 (2013), 235-238
- [5] Petzold T., Modelling, analysis and simulation of multifrequency induction hardening, Dissertation, Technical University of Berlin, Berlin, Germany, (2014)
- [6] Legutko P., Kierepka K., Zimoch P., Simultaneous dual-frequency inverter for induction hardening of gears, Przeglad Elektrotechniczny, 94 (2018), No. 12, 74-78 (Polish)
- [7] Okudaira S., Nomura K., Matsuse K., New quasiresonant inverter for induction heating, Conference Record of the Power Conversion Conference, (1993), 117-122
- [8] Okudaira S., Matsuse K., Power control of an adjustable frequency quasi-resonant inverter for dual frequency induction heating, Third International Power Electronics and Motion Control Conference, (2000), 968-973
- [9] Okudaira S., Matsuse K., Adjustable frequency quasiresonant inverter circuits having short-circuit switch across resonant capacitor, IEEE Transactions on Power Electronics, 23 (2008), No. 4, 1830-1838
- [10] Okudaira S., Matsuse K., A new quasi-resonant inverter with two-way short-circuit switch across a resonant capacitor, Proceedings of the Power Conversion Conference, (2002), 1496-1501
- [11] Okudaira S, Matsuse K., Dual frequency output quasiresonant inverter for induction heating, IEEJ Transactions on Industry Applications, 121 (2001), No. 5, 563-568
- [12] Esteve V., Jordan J., Sanchis-Kilders E., Dede E.J., Maset E., Ejea J.B., Ferreres A., Comparative study of a single inverter bridge for dual-frequency induction heating using Si and SiC MOSFETs, IEEE Transactions on Industrial Electronics, 62 (2015), No. 3, 1440-1450
- [13] Esteve V., Jordan J., Dede E.J., Sanchis-Kilders E., Maset E., Induction heating inverter with simultaneous dual-frequency output, Twenty-First Annual IEEE Applied Power Electronics Conference and Exposition, (2006), 1505-1509
- [14] Diong B., Corzine K., Basireddy S., Lu Shuai., Multilevel inverter-based dual-frequency power supply, IEEE Power Electronics Letters, (2003), No. 4, 115-119
- [15] Schwenk W., Hsussler A., Heiliger A., European Patent, EP 1363474 A2 (2003)
- [16] Grajales L. and Lee F.C., Control system design and small-signal analysis of a phase-shift-controlled series-resonant inverter for induction heating, Proceedings of PESC '95 - Power Electronics Specialist Conference, (1995), 450-456
- [17] Nagai S., Michihira M., Nakaoka M., New phaseshifted soft-switching PWM high-frequency series resonant inverters topologies and their practical evaluations, 1994 Fifth International Conference on Power Electronics and Variable- Speed Drives, (1994), 274-279
- [18] Young-Sup Kwon, Sang-Bong Yoo and Dong-Seok Hyun, Half-bridge series resonant inverter for induction heating applications with load-adaptive PFM control strategy, APEC '99. Fourteenth Annual Applied Power Electronics Conference and Exposition, (1999), 575-581
- [19] Fujita H. and Akagi H., Control and performance of a pulse-density-modulated series-resonant inverter for corona discharge processes, IEEE Transactions on Industry Applications, 35 (1999), No. 3, 621-627
- [20] Zinn S., Semiatin S.L., Coil design and fabrication. Part1: Basic design and modifications, Heat treating, (1988), 32-36
- [21] Davies E.J., Conduction and induction heating, The institution of engineering and technology, (1990), 416 pages
- [22] Segura G.M., Induction heating converter’s design, control and modeling applied to continuous wire, Doctoral Thesis, Polytechnic University of Catalonia, Barcelona, Spain, (2012)
- [23] AN-9012. Induction Heating System Topology Review. 2013. URL: https://www.onsemi.jp/pub/Collateral/AN-9012.pdf.pdf
- [24] Haimbaugh R.E., Practical induction heat treating. Second edition, Ohia: ASM International, (2015), 379 pages
- [25] Baker R.M., Design and calculation of induction heating coils, AIEE Transactions, 76 (1957), 31-40
- [26] Takau L., Improved modelling of induction and transduction heaters, Doctoral thesis, University of Canterbury, Christchurch, New Zealand, (2015)
- [27] Yen Chu-Sun, Fazarinc Z., Wheeler R.L., Timedomain skin-effect model for transient analysis of lossy transmission lines, Proceedings of the IEEE, 70 (1982), No. 7, 750-757
- [28] Laboure E., Costa F., Gautier C., Melhem W., Accurate simulation of conducted interferences in isolated DC to DC converters regarding to EMI standards, 27th Annual IEEE Power Electronics Specialists Conference, (1996), 1973- 1978
- [29] Forest F., Laboure E., Costa F., Gaspard J.Y., Principle of a multi-load/single converter system for low power induction heating, IEEE Transactions on Power Electronics, 15 (2000), No. 2, 223-230
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-8ec14d83-8223-460f-a477-ca0d739788dd