Abstract
Research on the transformer oil-based nanofluids (NFs) has been raised expeditiously over the past decade. Although, there is discrepancy in the stated results and inadequate understanding of the mechanisms of improvement of dielectric nanofluids, these nanofluids have emerged as a potential substitute of mineral oils as insulating and heat removal fluids for high voltage equipment. The transformer oil (TO) based magnetic fluids (ferrofluids) may be regarded as the posterity insulation fluids as they propose inspiring unique prospectus to improve dielectric breakdown strength, as well as heat transfer efficiency, as compared to pure transformer oils. In this work, transformer oil-based magnetic nanofluids (MNFs) are prepared by dispersal of Fe3O4 nanoparticles (MNPs) into mineral oil as base oil, with various NPs loading from 5 to 80% w/v. The lightning impulse breakdown voltages (BDV) measurement was conducted in accordance with IEC 60897 by using needle to sphere electrodes geometry. The test results showed that dispersion of magnetic NPs may improve the insulation strength of MO. With the increment of NPs concentrations, the positive lightning impulse (LI) breakdown strength of TO is first raised, up to the highest value at 40% loading, and then tends to decrease at higher concentrations. The outcomes of negative LI breakdown showed that BDV of MNFs, with numerous loadings, were inferior to the breakdown strength of pure MO. The 40% concentration of nanoparticles (optimum concentration) was selected, and positive and negative LI breakdown strength was also further studied at different sizes (10 nm, 20 nm, 30 nm and 40 nm) of NPs and different electrode gap distances. Augmentation in the BDV of the ferrofluids (FFs) is primarily because of dielectric and magnetic features of Fe3O4 nanoaprticles, which act as electron scavengers and decrease the rate of free electrons produced in the ionization process. Research challenges and technical difficulties associated with ferrofluids for practical applications are mentioned. The advantages and disadvantages linked with magnetic fluids are also presented.
Highlights
The evolution of prospective high voltage systems and smart grids has placed significant demands on the reliability and conduct of insulating materials applied in electric power networks to cope with vital and volatile operating conditions [1]
The high voltage (HV) machinery collapse statistics illustrated that usual service life of transformers, which collapse due to insulation complications, is 17.8 years, which is half of their anticipated life of 35 to 40 years [4] and 75% of transformer failures are mainly caused by insulation issues [5]
The positive lightning impulse (LI) breakdown voltages (BDV) test was conducted for both oil and developed NFs with multiple loadings of compared to mineral oils (MOs)
Summary
The evolution of prospective high voltage systems and smart grids has placed significant demands on the reliability and conduct of insulating materials applied in electric power networks to cope with vital and volatile operating conditions [1]. An essential component of electrical networks which alters voltage levels and transforms energy is called a transformer [2]. The high voltage (HV) machinery collapse statistics illustrated that usual service life of transformers, which collapse due to insulation complications, is 17.8 years, which is half of their anticipated life of 35 to 40 years [4] and 75% of transformer failures are mainly caused by insulation issues [5]. The status and properties of insulation materials are very important for the functional reliability and lifetime of transformers [5,6,7,8].
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