Authors: Siming Wang, Qing Ni, Yu Wu, Ruihai Xu, Hong Ye

Abstract:

Porous electric heaters, compared to conventional electric heaters, exhibit excellent heating performance due to their large specific surface area. Porous electric heaters employ porous metallic materials or conductive porous ceramics as the heating element. The former attains a low heating power with a fixed current due to the low electrical resistivity of metal. Although the latter can bypass the inherent challenges of porous metallic materials, the fabrication process of the conductive porous ceramics is complicated and high cost. This work proposed a porous ceramic electric heater with dielectric honeycomb ceramic as a substrate and surface conductive coating as a heating element. The conductive coating was prepared by the sol-gel method using silica sol and methyl trimethoxysilane as raw materials and graphite powder as conductive fillers. The conductive mechanism and degradation reason of the conductive coating was studied by electrical resistivity and thermal stability analysis. The heating performance of the proposed heater was experimentally investigated by heating air and deionized water. The results indicate that the electron transfer is achieved by forming the conductive network through the contact of the graphite flakes. With 30 wt% of graphite, the electrical resistivity of the conductive coating can be as low as 0.88 Ω∙cm. The conductive coating exhibits good electrical stability up to 500 °C but degrades beyond 600 °C due to the formation of many cracks in the coating caused by the weight loss and thermal expansion. The results also show that the working medium has a great influence on the volume power density of the heater. With air under natural convection as the working medium, the volume power density attains 640.85 kW/m3, which can be increased by 5 times when using deionized water as the working medium. The proposed honeycomb ceramic electric heater has the advantages of the simple fabrication method, low cost, and high-volume power density, demonstrating great potential in the fluid heating field.

Keywords: Conductive coating, honeycomb ceramic electric heater, high specific surface area, high volume power density.

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 348

References:

[1] H. Gu, Y. Chen, J. Wu, F. Fei and B. Sundén 2021 Performance investigation on the novel anti-leakage and easy-to-manufacture trisection helical baffle electric heaters International Journal of Heat and Mass Transfer 172 121142.
[2] A.A. Rezwan, S. Hossain, S.A. Rahman and M. Islam 2013 Heat transfer enhancement in an air process heater using semi-circular hollow baffles Procedia Engineering 56 357-362.
[3] S.Z. Movassag, F.N. Taher, K. Razmi and R.T. Azar 2013 Tube bundle replacement for segmental and helical shell and tube heat exchangers: Performance comparison and fouling investigation on the shell side Applied Thermal Engineering 51 1162-1169.
[4] R.T. Azar, S. Khalilarya and S. Jafarmadar 2014 Tube bundle replacement for segmental and helical shell and tube heat exchangers: Experimental test and economic analysis Applied thermal engineering 62 622-632.
[5] M. Wang, Y. Chen, J. Wu and C. Dong 2016 Heat transfer enhancement of folded helical baffle electric heaters with one-plus-two U-tube units Applied Thermal Engineering 102 586-595.
[6] A. Banerjee, R.B. Chandran and J.H. Davidson 2015 Experimental investigation of a reticulated porous alumina heat exchanger for high temperature gas heat recovery Applied Thermal Engineering 75 889-895.
[7] M. Alkam, M. Al-Nimr and M. Hamdan 2001 Enhancing heat transfer in parallel-plate channels by using porous inserts International Journal of Heat and Mass Transfer 44 931-938.
[8] K. Chen and C. Wang 2015 Performance improvement of high power liquid-cooled heat sink via non-uniform metal foam arrangement Applied Thermal Engineering 87 41-46.
[9] A. Hamadouche, R. Nebbali, H. Benahmed, A. Kouidri and A. Bousri 2016 Experimental investigation of convective heat transfer in an open-cell aluminum foams Experimental Thermal and Fluid Science 71 86-94.
[10] H.I. Mohammed, P. Talebizadehsardari, J.M. Mahdi, A. Arshad, A. Sciacovelli and D. Giddings 2020 Improved melting of latent heat storage via porous medium and uniform Joule heat generation Journal of Energy Storage 31 101747.
[11] K.E. Amori and H.A. Laibi 2011 Experimental and numerical analysis of electrical metal foam heater Energy 36 4524-4530.
[12] Y. Wang, F. Bai, Y. Jian, C. Xu and Z. Wang 2012 Heat transfer enhancement of an electric air heating furnace by inserting silicon carbide ceramic foam panels Experimental Thermal and Fluid Science 38 127-133.
[13] M. Naji and M. Al-Nimr 2002 Thermal behavior of a porous electric heater Applied thermal engineering 22 449-457.
[14] E.J. Cookson, D.E. Floyd and A.J. Shih 2006 Design, manufacture, and analysis of metal foam electrical resistance heater International Journal of Mechanical Sciences 48 1314-1322.
[15] I. Zahmatkesh and M. Yaghoubi 2006 Studies on thermal performance of electrical heaters by using porous materials International Communications in Heat and Mass Transfer 33 259-267.
[16] S. Gianella, D. Gaia and A. Ortona 2012 High Temperature Applications of Si-SiC Cellular Ceramics Advanced Engineering Materials 14 1074-1081.
[17] L. Wang 2006 Process and application study of electron-heating porous SIC ceramic M.A. Thesis, Xi'an University of Science and Technology (in Chinese).
[18] Z. Fan 2004 Study on preparation and properties of electroheating porous silicon carbide ceramics M.A. Thesis, Xi'an University of Science and Technology (in Chinese).
[19] X. Zhang, W. Lin, J. Zheng, Y. Sun, B. Xia, L. Yan and B. Jiang 2018 Insight into the organic-inorganic hybrid and microstructure tailor mechanism of sol-gel ORMOSIL antireflective coatings The Journal of Physical Chemistry C 122 596-603.
[20] C. Tao, K. Yang, X. Zou, H. Yan, X. Yuan, L. Zhang and B. Jiang 2018 Double-layer tri-wavelength hydrophobic antireflective coatings derived from methylated silica nanoparticles and hybrid silica nanoparticles Journal of Sol-Gel Science and Technology 86 285-292.
[21] A. Zanurin, N. Johari, J. Alias, H.M. Ayu, N. Redzuan and S. Izman 2021 Research progress of sol-gel ceramic coating: A review Materials Today: Proceedings 48 1849-1854.
[22] S. Chen, L. Chen, Y. Liang, X. Zeng and C. Fan 2021 Preparation and properties of ceramic-based conductive coatings Journal of Adhesion Science and Technology 35 777-790.