Design and Experiments of Electromagnetic Heating Forming Technology

Li, Chengxiang; Zhang, Yan; Wang, Pengfei; Xian-min, Wang; Dong, Shoulong; Du, Jian; Zhi-gang, Liao; Yao, Chenguo; Tan, Jianjun; Mi, Yan

doi:10.1109/access.2019.2912333

Cited by 8 publications

(3 citation statements)

References 32 publications

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“…[5][6][7] Compared with the flame heating and resistance heating, electromagnetic induction heating has the advantage of cleanness, safety, contactless, fast heating, and high efficiency. 8,9 Faraday and Ampere's laws address the main fundamental principle of induction heating technology. The Ampere's law explains that magnetic field is generated surround conductor carrying electric current, and the magnetic field is alternating with the current.…”

Section: Introductionmentioning

confidence: 99%

“…Electromagnetic induction heating technology has been applied in food processing, cooking, plastics processing heating, and medical heating 5‐7 . Compared with the flame heating and resistance heating, electromagnetic induction heating has the advantage of cleanness, safety, contactless, fast heating, and high efficiency 8,9 . Faraday and Ampere's laws address the main fundamental principle of induction heating technology.…”

Section: Introductionmentioning

confidence: 99%

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Experimental and numerical study on induction heating performance of quaternary nitrate‐nitrite molten salt

Zhang

2020

Int J Energy Res

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Summary Induction heating technology has been extensively applied in many industrial processes. The experimental system of electromagnetic induction heating molten salt is designed and built in this study; the molten salt electromagnetic induction‐heating unit is developed. The simulation results and the experimental data are in good agreement. The effect of molten salt inlet temperature, coil current, induction heater material and molten salt velocity are comparatively studied. The results show that the molten salt outlet temperature increases with the increasing of coil current and decreases with the increasing of molten salt velocity under same heating power. The heat absorption power of molten salt increases with the increasing of molten salt inlet temperature. The maximum molten salt heat‐absorption power in carbon steel condition is significantly 23.39% higher than that of stainless steel conditions. Meanwhile, the maximum heating efficiency of molten salt in carbon steel conditions is 16.7% higher than that of stainless steel. The maximum overall heat utilizing efficiency at Ts‐i = 292°C under different working conditions is 90.12%, which is 3.38% higher than that at Ts‐i = 200°C.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Experimental and numerical study on induction heating performance of quaternary nitrate‐nitrite molten salt

Zhang

2020

Int J Energy Res

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“…When specifically speaking of domestic induction heating [2], induction heating provides significant advantages compared with resistive or gas heating, including faster cooking, safer and cleaner operation, because the cooking surface reaches much lower temperatures, as well as more accurate control and improved efficiency. Because of these advantages, induction heating is nowadays being applied to a wide range of applications including, but not limited to, industrial [3], vehicular [4], domestic [5], and biomedical applications [6]. A typical domestic induction heating appliance (FIGURE 2) is composed of the power electronic converter, the induction coil, a cooking surface, typically made of vitroceramic glass due to its excellent mechanical and aesthetical qualities, and the pan to be heated.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning-Based Magnetic Coupling Detection for Advanced Induction Heating Appliances

et al. 2019

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Induction heating has become the reference technology for domestic heating applications due to its benefits in terms of performance, efficiency and safety, among others. In this context, recent design trends aim at providing highly flexible cooking surfaces composed of multi-coil structures. As in many other wireless power transfer systems, one of the main challenges to face is the proper detection of the magnetic coupling with the induction heating load in order to provide improved thermal performance and safe power electronic converter operation. This is specially challenging due to the high variability in the materials used in cookware as well as the random pot placement in flexible induction heating appliances. This paper proposes the use of deep learning techniques in order to provide accurate area overlap estimation regardless of the used pot and its position. An experimental test-bench composed of a complete power converter, multi-coil system and real-time measurement system has been implemented and used in this study to characterize the parameter variation with overlapped area. Convolutional neural networks are then proposed as an effective method to estimate the covered area, and several implementations are studied and compared according to their computational cost and accuracy. As a conclusion, the presented deep learning-based technique is proposed as an effective tool to estimate the magnetic coupling between the coil and the induction heating load in advanced induction heating appliances.INDEX TERMS Inductive heating, resonant power conversion, wireless power transfer, deep learning, neural network, electromagnetic design, induction heating, home appliances.

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Influence of the deformation temperature on the formability of AA5083 during electromagnetic forming

Dong

Cao

et al. 2023

Int J Adv Manuf Technol

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Design and Experiments of Electromagnetic Heating Forming Technology

Cited by 8 publications

References 32 publications

Experimental and numerical study on induction heating performance of quaternary nitrate‐nitrite molten salt

Experimental and numerical study on induction heating performance of quaternary nitrate‐nitrite molten salt

Deep Learning-Based Magnetic Coupling Detection for Advanced Induction Heating Appliances

Influence of the deformation temperature on the formability of AA5083 during electromagnetic forming

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