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Research Article

Thermal performance assessment of lauric acid and palmitic acid based multi-transformation phase change material and exfoliated graphite composites

Anju NirwanHeat management group, Defence Laboratory, Jodhpur, IndiaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-5003-8408View further author information
ORCID Icon,
Rohitash KumarHeat management group, Defence Laboratory, Jodhpur, IndiaView further author information
,
Bobin MondalHeat management group, Defence Laboratory, Jodhpur, IndiaView further author information
,
Jeetendra KumarHeat management group, Defence Laboratory, Jodhpur, IndiaView further author information
,
Anuradha BeraHeat management group, Defence Laboratory, Jodhpur, IndiaView further author information
&
Ravindra KumarHeat management group, Defence Laboratory, Jodhpur, IndiaView further author information
Received 18 Mar 2020, Accepted 23 Jul 2020, Published online: 17 Sep 2020

References

  • Akeiber, H. J., P. Nejat, M. Z. Majid, M. A. Wahid, F. Jomehzadeh, I. Z. Famileh, J. K. Calautit, B. R. Hughes, and S. A. Zaki. 2016. A review on phase change material (PCM) for sustainable passive cooling in building envelops. Renewable and Sustainable Energy Review 60:1470–97.
  • Amundin, K., C. Brunius, and A. Brand-Persson, “Heat stress, heat strain and risk of heat disorder” Proceedings international conference on protective clothing systems (1981)167–75. Lotens W.A., Stockholm National Defence Administration, Stockholm , Sweden.
  • Arici, M., F. Bilgin, S. Nizetic, and H. Karabay. 2019. PCM integrated to external building walls: An optimization study on maximum activation of latent heat. Applied Thermal Engineering 1359-4311 (19): 33615–4. https://doi.org/10.1016/j.applthermaleng.2019.114560
  • Bell, C. R., and K. A. Provins. 1962. Effects of high temperature environmental conditions on human performance. Occupational Medicine 4:202–11.
  • Cabeza, L. F., A. Castell, C. D. Barreneche, A. De Gracia, and A. I. Fernández. 2011. Materials used as PCM in thermal energy storage in buildings. A Review, Renewable and Sustainable Energy Reviews 15:1675–95.
  • Cabeza, L. F., H. Mehling, S. Hiebler, and F. Ziegler. 2002. Heat transfer enhancement in water when used as PCM in thermal energy storage. Applied Thermal Engineering 22:1141–51.
  • Choi, B. K., J. K. Ko, S. J. Park, and M. K. Seo. 2016. Influence of expanded graphite on thermal characterizations of erythritol, paraffin, and stearic acid for low-temperature phase change material composites. Nternational Journal Of Engineering Sciences & Research Technology 5 (9):796–807.
  • Chuyuan, M., Y. Zhang, and X. Chen. 2020. Xiande Song and Kaixuan Tang, Experimental study of an enhanced phase hange material of paraffin/expanded graphite/nano-metal particles for a personal cooling system. Material 13:980. doi:10.3390/ma13040980.
  • Cui, Y., C. Liu, S. Hu, and X. Yu. 2011. The experimental exploration of carbon nanofiber and carbon nanotube additives on thermal behavior of phase change materials. Solar Energy Materials and Solar Cells 95:1208–12.
  • He, Y. 2005. Rapid thermal conductivity measurement with a hot disk sensor: Part 1. Theoretical considerations. Thermochimica acta 436:122–29.
  • JianShe, H., Y. Chao, Z. Xu, Z. Jiao, and D. JinXing. 2019. Structure and thermal properties of expanded graphite/paraffin composite phase change material. Journal Energy Source, Part A: Recovery, Utilization and Environment Effect 41:86–93.
  • Kumar, R., R. Kumar, M. K. Mishra, B. B. Tak, P. K. Sharma, and P. K. Khatri, Passive temperature moderation using multi transformation Phase Change materials in tropical desert climate, Paper presented at 11th International Conference on Thermal Energy Storage, Effstock, Stockholm, Sweden, (2009) 14–17.
  • Kumar, R., M. MK, R. Kumar, D. Gupta, P. K. Sharma, B. B. Tak, and S. R. Meena, Multiple Transformation Phase Change Material (MTPCM) for passive temperature regulations, Indian Patent No. 259779 (2014).
  • Lee, S. Y., H. K. Shin, M. R. Park, K. Y. Rhee, and S. J. Park. 2014. Thermal characterization of erythritol/expanded graphite composite for high thermal storage capacity. Carbon 68:67–72.
  • Ling, Z., J. Chen, T. Xu, X. Fang, X. Gao, and Z. Zhang. 2015a. Thermal conductivity of an organic phase change material/expanded graphite composite across the phase change temperature range and a novel thermal conductivity model. Energy Conversion and Management 102:202–08.
  • Ling, Z., J. Chen, T. Xu, X. Fang, X. Gao, and Z. Zhang. 2015b. Thermal conductivity of an organic phase change material/expanded graphite composite across the phase change temperature range and a novel thermal conductivity model. Energy Conversion and Management 102:202–08.
  • Mill STD- 810F Method 501.4.
  • Oya, T., T. Nomura, N. Okinaka, and T. Akiyama. 2012. Phase change composite based on porous nickel and erythritol. Applied Thermal Engineering 40:373–77.
  • Pang, X. I. U.-Y. A. 2012. Catalytic behavior of expansible graphite in the synthesis of butyl acetate. Journal of Chemistry 9 (4):1816–22.
  • Rajesh, D., K. A. Rahim, T. S. Senthil, and D. Kumaresh. 2016. Passive solar heating or cooling for residential building using PCM. Chemical Science 14 (S2):502–12.
  • Rao, Z. H., S. H. Wang, Y. L. Zhang, G. Q. Zhang, and J. Y. Zhang. 2014. Thermal properties of paraffin/nano AlN Phase Change Energy Storage Material. Journal Energy Source, Part A: Recovery, Utilization and Environment Effect 36:2281–86.
  • Roy, P. D., and A. K. Singhvi. 2016. Climate variation in the Thar Desert since the last glacial maximum and evaluation of the Indian Monsoon. TIP 19:32–44.
  • Sari, A., and A. Karaipekli. 2009. Preparation, thermal properties and thermal reliability of palmitic acid/expanded graphite composite as form-stable PCM for thermal energy storage. Solar Energy Materials & Solar Cells 93:571–76.
  • Senthilkumar, M., K. R. Balasubramanian, R. K. Kottala, S. P. Sivapirakasam, and L. Maheswari. 2020. Characterization of foam stable phase change material for solar photovoltainc cooling. Journal of Thermal Analysis and Calorimetry. doi:10.1007/s10973-020-09521-1.
  • Shengtao, Z. H., G. Anyan, G. Huanfang, and C. H. Xiangqian. 2011. Characterization of exfoliated graphite prepared with the method of secondary intervening. International Journal of Chemistry 2 (2):123–30.
  • Shi, J. N., M. D. Ger, Y. M. Liu, Y. C. Fan, N. T. Wen, C. K. Lin, and N. W. Pu. 2013. Improving the thermal conductivity and shape- stabilization of phase change material using nanographite additives. Carbon 51:365–72.
  • Sivasamy, P., A. Devaraju, and S. Harikrishnan. 2018. Review on heat transfer enhancement of phase change materials (PCMs). Materialstoday Proceeding 5:14423–1443.
  • Socaciu, L. G. 2012. Thermal energy storage with phase change material. Practices and Technologies 20:75–98.
  • Wang, J. F., H. Q. Xie, and Z. Xin. 2009. Thermal properties of paraffin based composites containing multi-walled carbon nanotubes. Thermochimica acta 488:39–42.
  • Wei, L., Y. Dong, X. Zhang, and X. Liu. 2019. Preparation and performance analysis of graphite additive/paraffin composite phase change materials. Processes 7:447. doi:10.3390/pr7070447.
  • Zhang, X., Z. Huang, Z. Yin, W. Zhang, Y. Huang, Y. Liu, M. Fang, X. Wu, and X. Min. 2017. Form stable composite phase change materials from palmitic-lauric acid eutectic mixture and carbonized abandoned rice: Preparation, characterization, and thermal conductivity enhancement. Energy and Buildings 157:46–54.
  • Zhang, Z., and X. Fang. 2006. Study on paraffin/expanded graphite composite phase change thermal energy storage material. Energy Conversion and Management 47:303–10.
  • Zhong, Y., S. Li, X. Wei, Z. Liu, Q. Guo, J. Shi, and L. Liu. 2010. Heat transfer enhancement of paraffin wax using compressed expanded natural graphite for thermal energy storage. Carbon 48:300–04.
  • Zhou, D., Y. Zhou, J. Yuan, and Y. Liu. 2020. Palmitic acid –stearic acid/expandable graphite as foam –stable composite phase change material for latent heat thermal energy storage. Journal of Nanomaterial 9. doi:10.1155/2020/1648080.

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