Modelling and Simulation of Quasi-Resonant Inverter for Induction Heating under Variable Load

Spateri, Enrico; Ruiz, Fredy; Gruosso, Giambattista

doi:10.3390/electronics12030753

Cited by 5 publications

(3 citation statements)

References 23 publications

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“…where H 2 ±(0) * are known functions (values of function H 2 set on the surfaces x 1 = ±d). Considering non-homogeneous boundary conditions (20) imposed on functions H 2s (s = 1, 2), let us present the solution of the system (16) as:…”

Section: Building a Solution For The Problem Of Electrodynamicsmentioning

confidence: 99%

“…The study in [15] proposed the exact analytical solution for the general problem of conjugation of a three-dimensional quasi-stationary field at the flat border between a dielectric and conducting medium. In [16], a modeling strategy in the time domain was used to analyze the behavior of induction heating systems with a quasi-resonant single-cycle direct current inverter via frequency-pulse modulation and a variable load.…”

Section: Introductionmentioning

confidence: 99%

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Analysis of Varying Temperature Regimes in a Conductive Strip during Induction Heating under a Quasi-Steady Electromagnetic Field

Musii,

Lis,

Pukach

et al. 2024

Energies

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Transition processes in a steel conductive strip are analyzed during its induction heating under a quasi-steady electromagnetic field. In particular, the temperature field in the strip is studied. A method of solving corresponding initial boundary problems in a two-dimensional mathematical model for differential equations of electrodynamics and heat conduction is developed. The Joule heat and the temperature are determined with a high level of accuracy. The defining functions are the temperature and component of the magnetic field intensity vector tangent to the bases and end planes of the strip. To find them, we use cubic approximation of the defining functions’ distribution along the thickness coordinate. The original two-dimensional initial boundary value problems for the defining functions are reduced to one-dimensional initial boundary value problems on their integral characteristics. General solutions for these problems are obtained using the finite integral transformation by the transverse variable and the Laplace transform of the integral by time. Integral characteristics’ expressions are represented as convolutions for functions that describe homogeneous solutions of one-dimensional initial boundary value problems and limiting values of defining functions on the bases and end planes of the strip. The change of temperature under a varying regime in the dimensionless Fourier time and temperature distribution over the strip cross-section in a steady state depending on the parameters of induction heating and the Biot number are numerically analyzed. Varying and constant temperature regimes of the strip under conditions of the near-surface and continuous induction heating are studied.

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Section: Building a Solution For The Problem Of Electrodynamicsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Analysis of Varying Temperature Regimes in a Conductive Strip during Induction Heating under a Quasi-Steady Electromagnetic Field

Musii,

Lis,

Pukach

et al. 2024

Energies

View full text Add to dashboard Cite

show abstract

“…Additionally, these values are subject to variations based on factors such as the operating frequency of the resonant circuit, ambient temperature, and air gap between the pan and the coil. As a result, there exists a wide range of academic research focusing on pan and load recognition [11,29,[33][34][35][36]. However, the design of the coil itself necessitates a comprehensive academic investigation.…”

Section: Introductionmentioning

confidence: 99%

A Simplified Design Method for Quasi-Resonant Inverter Used in Induction Hob

Ozturk

2023

Electronics

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Induction heating (IH) technology is widely recognized and utilized in residential applications due to its high efficiency and safe operating characteristics. Resonant inverter circuits are widely used in IH systems because of their high efficiency and ability to perform soft switching. Among the various resonant inverters used in IH systems, the single-switch quasi-resonant (SSQR) inverter topology is typically preferred for low-cost and low-output-power applications. Despite its cost advantage, the SSQR topology has a relatively narrow soft-switching range, which can be unstable depending on the electrical parameters of the load and the resonant converter circuit. Accurately determining the capacitance value of the resonant capacitor and the inductance value of the induction coil, which are the key circuit elements of the SSQR induction cooker, is crucial for designing a reliable, efficient, and durable cooking system. In other words, there exists a critical relationship between the resonant converter circuit parameters, load characteristics, and safe operating conditions. Additionally, when considering closed-loop control methods used for power control and safety, selecting appropriate resonant circuit elements becomes vital in ensuring both reliable and efficient operation. This paper focuses on a novel and simplified design method for the SSQR inverter utilized in household appliances. The proposed method and its advantages in terms of the safe operating area of the switch are theoretically investigated and verified through simulations and prototype circuits.

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Efficient Multiobjective Optimization Framework for Induction Heating Systems Design

Spateri,

Sabug,

Ruiz

et al. 2024

IEEE Access

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Modelling and Simulation of Quasi-Resonant Inverter for Induction Heating under Variable Load

Cited by 5 publications

References 23 publications

Analysis of Varying Temperature Regimes in a Conductive Strip during Induction Heating under a Quasi-Steady Electromagnetic Field

Analysis of Varying Temperature Regimes in a Conductive Strip during Induction Heating under a Quasi-Steady Electromagnetic Field

A Simplified Design Method for Quasi-Resonant Inverter Used in Induction Hob

Efficient Multiobjective Optimization Framework for Induction Heating Systems Design

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