Journal of Electrical and Computer Engineering Innovations (JECEI)
مقاله 15 ، دوره 14، شماره 1 ، مهر 2026، صفحه 197-210 1.85 M )
نوع مقاله: Original Research Paper
شناسه دیجیتال (DOI): 10.22061/jecei.2025.11945.845 نویسندگان
Bahram Rashidi* ؛ Ali Mirzajani Nooshabadi
تاریخ دریافت : 23 اردیبهشت 1404 ،
تاریخ بازنگری : 19 مرداد 1404 ،
تاریخ پذیرش : 08 شهریور 1404
چکیده Background and Objectives: This paper presents a high-performance and efficient circuit based on low-cost coils for induction heating applications. We design the coils specifically for induction sealing and induction cooker applications. The proposed circuit utilizes two parallel sets of MOSFET transistors to increase the current flow and output power.Methods: Three types of coils have been developed in square and rectangular designs on the printed circuit board (PCB). In this case, the construction process is simple and requires minimal time. Induction coils designed for induction sealing applications have a rectangular structure that effectively seals a wide range of bottles.Results: The flexibility of the proposed circuit is one of its advantages; the output frequency can be adjusted by increasing or decreasing the number of capacitors in the capacitor bank. Performance comparisons (e.g., efficiency, power density, cost) between the proposed method and other studies show that the implementation cost of the proposed circuit is lower than that of others. The proposed circuit achieves 95% efficiency. Thermal imaging confirms the circuit's performance. Based on the electromagnetic interference results, the circuit's performance is not affected by an external magnetic field.Conclusion: The proposed circuit has been tested with different capacitor banks using two power supplies of 24 V and 12 V. The peak-to-peak output voltage is 181 V and 92 V for the 24 V and 12 V power supplies, respectively. The results demonstrate that the circuit and coils are suitable for induction heating applications.کلیدواژهها
Induction Heating ؛ Induction sealing ؛ Induction PCB coils ؛ Hardware implementation ؛ Resonant converter
مراجع
[1] A. Sherwali, W. Dunford, “Experimental evaluation of heating water by electromagnetic induction,” in Proc. the IEEE Canadian Conference of Electrical and Computer Engineering (CCECE): 1-4, 2019.
[2] A. Kumar Paul, “Robust features of SOSMC guides in quality characterization of tank circuit in air-cooled induction cap sealing,” IEEE Trans. Ind. Appl., 54(1): 755-763, 2018.
[3] A. Kumar Paul, “Inverter topology for zero-ventilated high frequency induction heating systems,” in Proc. the IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES): 1-6, 2020.
[4] I. Lope, J. Acero, J., Burdio, C. Carretero, R. Alonso, “Design and implementation of PCB inductors with litz-wire structure for conventional-size large-signal domestic induction heating applications,” IEEE Trans. Ind. Appl., 51(3): 2434-2442, 2014.
[5] F. D. Marques, M. N. Souza, F. G. Souza, “Sealing system activated by magnetic induction polymerization,” J. Appl. Polym. Sci., 134(47): 1-9, 2017.
[6] T. Ngo-Phi, N. Nguyen-Quang, “Variable pulse density modulation for induction heating,” in Proc. International Symposium on Electrical and Electronics Engineering (ISEE): 1-6, 2012.
[7] A. Kumar Paul, “Current density characterization of litz wires used in induction heating coils: A practical approach,” in Proc. the IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES): 1-6, 2018.
[8] O. Lucia, P. Maussion, E. Dede, J. Burdio, “Induction heating technology and its applications: Past developments, current technology, and future challenges,” IEEE Trans. Ind. Electron., 61(5): 2509-2520, 2014.
[9] A. Kumar Paul, S. Chinoy, “Air cooled induction heater for efficient sealing of containers using wide range foils,” IEEE Trans. Ind. Appl., 52(4): 3398-3407, 2016.
[10] A. Kumar Paul, “Structured protection measures for better use of nanocrystalline cores in air-cooled medium-frequency transformer for induction heating,” IEEE Trans. Ind. Electron., 68(5): 3898-3905, 2021.
[11] B. Knauf, D. P. Webb, C. Liu, P. P. Conway, “Low frequency induction heating for the sealing of plastic microfluidic systems,” J. Microfluid. Nanofluid., 9: 243-252, 2010.
[12] A. Kumar Paul, “ZVZCS SRI guides optimal use of copper and core for air-cooled nanocrystalline transformer for induction heating,” IEEE Trans. Ind. Appl., 56(2): 970-978, 2020.
[13] R. Goldstein, W. Stuehr, M. Black, “Design and fabrication of inductors for induction heat treating,” J. Neural Eng. 2014, Book chapter, ASM Handbook, 4(16): 589-606, 2014.
[14] B. Dimitrov, K. Hayatleh, S. Barker, G. Collier, “Design, analysis and experimental verification of the self-resonant inverter for induction heating crucible melting furnace based on IGBTs connected in parallel,” Electricity, 2: 439-458, 2021.
[15] I. Hussain, D. K. Woo, “Inductance calculation of single-layer planar spiral coil,” Electronics, 11: 1-10, 2022.
[16] E. Plumed, J. Acero, L. Lope, J. Burdio, “Design methodology of high-performance domestic induction heating systems under worktop,” IET Power Electron., 13(2): 300-306, 2020.
[17] T. Pandey, P. Deo, A. Dongriyal, B. Patil, “Development of induction sealer and its application in food packaging,” Int. Adv. Res. J. Sci. Eng. Technol., 7(3): 16-23, 2020.
[18] I. M. Abdulbaqi, A. H. A. Kadhim, A. H. Abdul-Jabbar, F. A. Abood, T. K. Hasan, “Design and implementation of an induction furnace, Diyala J. Eng. Sci., 08(01): 64-82, 2015.
[19] N. Vilchez, M. O. Varela de Seijas, A. Bardenhagen, T. Rohr, E. Stoll, “A novel induction heater for sintering metal compacts with a hybrid material extrusion device,” Electronics, 12: 1-23, 2023.
[20] J. Serrano, J. Acero, I. Lope, et al., “A flexible cooking zone composed of partially overlapped inductors,” IEEE Trans. Ind. Electron., 65(10): 7762-7771, 2018.
[21] B. Rashidi, “Hardware structure of an efficient and optimal circuit for induction cap sealing,” Int. J. Ind. Electron. Control Optim., 7(3): 203-212, 2024.
[22] I. Sheikhian, N. Kaminski, S. Vob, W. Scholz, E. Herweg, “ Optimisation of the reverse conducting IGBT for zero-voltage switching applications such as induction cookers,” IET Circuits Devices Syst., 8(3): 176 -181, 2014.
[23] E. Jang, M. Jae Kwon, S. Min Park, H. Min Ahn, B. Kuk Lee, “Analysis and design of flexible-surface induction-heating cooktop with GaN-HEMT-based multiple inverter system,” IEEE Trans. Power Electron., 37(10): 12865- 12876, 2022.
[24] J. Villa, D. Navarro, A. Dominguez, J. I. Artigas, L. A. Barragan, “Vessel recognition in induction heating appliances-a deep-learning approach,” IEEE Access, 9: 16053-16061, 2021.
[25] F. Schapiro, “Using dynamic thermal imaging to correct sealing problems,” Pharm. Technol., 39(11): 50-51, 2015.
[26] P. Vishnuram, G. Ramachandiran, S. Ramasamy, D. Dayalan, “A comprehensive overview of power converter topologies for induction heating applications,” Int. Trans. Electr. Energ. Syst., 30: 1-33, 2020.
[27] P. Vishnuram, G. Ramachandiran, T. Sudhakar Babu, B. Nastasi, “Induction heating in domestic cooking and industrial melting applications: A systematic review on modelling, converter topologies and control schemes,” Energies, 14(20): 1-34, 2021.
[28] V. Jagannath Patil, A. M. Mulla, “A critical review on the low power SIC MOSFET based current fed inverter used in surface hardening application,” in Proc. 3rd International Conference on Electronics and Sustainable Communication Systems (ICESC): 1-6, 2022.
[29] K. Sayed, F. Abo-Elyousr, F. N. Abdelbar, H. El-Zohri, “Development of series resonant inverters for induction heating applications,” Eur. J. Eng. Res. Sci., 3(12): 36-39, 2018.
[30] A. Kumar, A. Goswami, P. Kumar Sadhu, J. R. Szymanski, “Single-stage LLC resonant converter for induction heating system with improved power quality,” Electricity, 5: 211-226, 2024.
آمار
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