High-frequency transformers are an essential component of many electronic devices, including power supplies, inverters, and converters. They are used to convert high-frequency electrical signals to low-frequency signals and vice versa, and their efficiency and performance are critical to the overall functioning of the electronic device.
One common type of transformer construction is the laminated transformer, which uses thin sheets of metal (usually steel) stacked together and insulated with an insulating material. However, when it comes to high-frequency transformers, laminated cores may not always be the best choice.
3 Reason why laminated steel cores may not be suitable for high-frequency transformers
- The high-frequency signals induce eddy currents in the metal core, which can cause energy losses and reduce the efficiency of the transformer. Laminated cores are designed to reduce eddy currents by creating small insulated air gaps between each sheet of metal. However, at high frequencies, these air gaps become less effective, and the eddy currents become more significant.
- The insulation material used to separate the sheets in a laminated transformer can break down at high frequencies. This breakdown can cause the transformer to fail, resulting in an electrical short circuit.
- The magnetic properties of laminated cores can change at high frequencies. These changes can cause the transformer to exhibit nonlinear behavior and result in distortion of the output waveform. To overcome these issues, alternative materials and construction methods can be used for high-frequency transformers. One option is to use powdered iron cores, which have lower eddy current losses and can operate at higher frequencies. Another option is to use ferrite cores, which have high permeability and low core losses at high frequencies.
- Transformers with low frequency use silicon steel sheets, and the primary and secondary stages are tightly coupled. Iron cores must have a high magnetic permeability and a small eddy current. The magnetic permeability of magnetic cores under high-frequency characteristics is much greater than that of silicon steel sheet iron cores in high-frequency transformers. In order to suppress magnetic saturation and achieve a good match with the high-frequency circuit, the inductance of the primary coil needs to be adjusted to adjust the coupling degree between the magnetic cores. Therefore, the structures and parameters of the two are different. If silicon steel sheet is used as high-frequency transformer, the silicon steel sheet has slow response to high-frequency current, large eddy current loss, high cost, low efficiency and no practical value.
In conclusion, while laminated cores are a popular choice for low-frequency transformers, they may not always be suitable for high-frequency transformers. Engineers designing high-frequency transformers need to consider the specific requirements of their application and select the appropriate materials and construction methods to achieve the desired performance and efficiency.