The power dissipated in a flat non-magnetic workpiece during induction heating depends on coil current, excitation frequency and workpiece conductivity. The attached report studies how power dissipation is affected by these properties.

Consider a thin flat plate with in-plane dimensions significantly larger than its thickness. Locally, the plate is subjected to a uniform but changing magnetic field as is illustrated in the figure below. Eddy currents will develop around the changing magnetic field, as a result of which power is dissipated. Here, we assume the plate is a non-magnetic conductor, which means power dissipation depends on Joule heating only.

We have asked ourselves the question how the dissipated power depends on the coil current (amplitude and frequency), and on the workpiece conductivity. This question has been answered for regimes, namely:

1. the regime where the plate is very thin compared to the penetration depth, and
2. the regime where the plate is very thick compared to the penetration depth.

In summary, we found that for the first regime, thus in case the plate is thin compared to the penetration depth, the dissipated power depends on coil current amplitude , frequency , and conductivity as:

while for the second regime these dependencies change to:

The dependencies found for both regimes can be understood from the underlying physics, i.e. from Ampère's, Faraday's, and Joule's Law. In addition, the analytical derivation was supported by numerical analysis for a slightly more realistic case.

If you want to replicate the simulations presented in the report, or simply play a bit with the model, feel free to clone the repository to your folder of choice using git:

git clone https://github.com/wjbg/ih_power.git

The model was implemented in Comsol Multiphysics (v5.6). The data for graphs in the report were generated by running multiple simulations through Matlab. The full dataset can be generated by running the file simulation_data.m.

In case you make use of this work for scientific publications of any kind, please cite it as:

@misc{Grouve2022_ih_power,
  author =       {Grouve, Wouter J.B.},
  title =        {Induction Heating - Influence of Current, Frequency, and Workpiece Conductivity},
  year =         {2022},
  publisher =    {Technical Report, University of Twente},
  journal =      {GitHub},
  howpublished = {\url{https://github.com/wjbg/ih_power}}}

Free as defined in the MIT license.