Abstract
Thermal stress and moisture absorption can cause a synergetic negative impact on kraft paper. Among various approaches for improving the dielectric properties of kraft paper, nanotechnology has had promising results. However, the hydrophilicity of most metal oxide nanoparticles renders nanomodified kraft paper more vulnerable to thermal stress and moisture, thereby inducing degradation. In nanomodified kraft paper research, the use of TiO2 nanoparticles has yielded the most promising results. The major shortfall, however, is the hydrophilicity of TiO2. This work investigated surface modifications of rutile-TiO2 nanoparticles (NPs) for improved hydrophobicity and thermal stability. Rutile-TiO2 NPs is a nontoxic metal oxide that can withstand high temperature and is stable in chemical reactions. Two cases of surfactants were used—alkyl ketene dimer (AKD) and alkenyl succinic anhydride (ASA). The intention was to increase heat resistance and reduce the surface free energy of the rutile-TiO2 NPs. The impacts of the surface modifiers on the rutile-TiO2 NPs were characterised using FT-IR, muffle furnace, analytical weight balance, and TGA. It was discovered that new functional groups were formed on the modified NPs examined through FT-IR spectra. This indicates new chemical bonds, introduced through the surface modification. The unmodified rutile-TiO2 NPs absorbed moisture, increasing their mass by 3.88%, compared with the modified nanoparticles, which released moisture instead. TGA analysis revealed that AKD- and ASA-modified rutile-TiO2 needed higher temperatures than the unmodified rutile-TiO2 to markedly decompose. AKD, however, gave better performance than ASA in that regard. As an example, those modified with 5% AKD sustained a 45% higher temperature than the pure TiO2 nanoparticles. Furthermore, in both cases of the surfactants, the higher the percent of surfactant content was, the more thermally stable the nanoparticles became. This work demonstrates the possibility of fabricating rutile-TiO2 NPs to give improved hydrophobicity and thermal stability for possible dielectric applications such as in kraft paper for power transformer insulation.
Highlights
Temperature rise in power transformers can cause thermal-induced degradation of kraft paper insulation
This paper presents a fabrication procedure that produced rutile-TiO2 NPs with improved hydrophobicity and thermal stability
It was further demonstrated that the moisture absorption characteristics, as well as thermal stability of the nanoparticles, can be improved through surface modification of the rutile-TiO2 NPs
Summary
Temperature rise in power transformers can cause thermal-induced degradation of kraft paper insulation. There is a possibility of discharge of highly toxic degradation by-products during thermal ageing, coupled with the displacement of hydrogen bonds, resulting in a decrease in mechanical strength These setbacks are mainly due to cyanoethylation of kraft paper and the discharge of ammonia due to amino compounds. According to a CIGRE working group A2.18 [24], migration of moisture from kraft paper to oil for extraction depends on temperature, and this process could take months It follows, that moisture management in power transformers requires mitigating the rate of moisture absorption of kraft paper. Kraft paper modified with nanoparticles has been reported to contain more hydrogen bonds, as more traps within cellulose structure are filled with the particles; this improves the bonding strength and the dielectric properties [26]. This paper presents a fabrication procedure that produced rutile-TiO2 NPs with improved hydrophobicity and thermal stability
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