Citation
Farade, Rizwan A. and Abdul Wahab, Noor Izzri and Selvaraj, Jeyraj and Samkari, Husam S. and Allehyani, Mohammed F. and Shah, Nehad Ali and Kumar, Maddina Dinesh and Zeeshan
(2026)
Dielectric nanofluids for transformer cooling: Performance, challenges, and towards smart and sustainable thermal management.
Materials Today Sustainability, 34.
art. no. 101361.
pp. 1-31.
ISSN 2589-2347
Abstract
Transformers encounter increasing thermal stress due to rising power densities and the integration of renewable energy. This makes it harder for traditional cooling fluids to work. This review's goal is to critically compare empirical studies of dielectric nanofluids as thermal media for power transformers. It integrates reported thermal performance of dielectric nanofluids in different nanoparticle and base fluid systems. Enhancements include thermal conductivity of 0.9-210%, flash point of 44%, fire point of 9%, and pour point of −45%, and reduced gassing tendency. These enhancements come with trade-offs such as specific heat reductions and viscosity increase. The mechanisms that control heat transport are analysed, with focus on nanoscale interfacial phenomena, percolation networks, and phonon transport. The review identifies and reconciles critical knowledge gaps, focussing on long-term stability and interfacial compatibility under thermal cycling. The novel contribution consists of the integration of interfacial physics, performance trade-offs, sustainability considerations, and intelligent monitoring into a cohesive framework. Sustainability is addressed through the exploration of nanoparticle green synthesis pathways. This article extends earlier reviews by adding nanofluids to smart cooling systems driven by Internet of Things (IoT) and artificial intelligence (AI). The main findings suggest that nanoparticle surface chemistry is necessary for thermal enhancement, AI-driven systems boost performance, and green synthesis supports sustainability in next-generation applications. Finally, it points out key areas of research, such as accelerated ageing protocols, standardised evaluation, and renewable-grid integration, to turn laboratory results into practical, sustainable transformer cooling solutions.
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