Youngmun Lee1,Daniel Hsieh1,Wuchen Fu1,Ho Chan Chang1,Sung Bum Kang1,Mayur Prabhudesai1,Jay Taylor1,Paul Braun1,Nenad Miljkovic1,Sanjiv Sinha1
University of Illinois at Urbana Champaign1
Youngmun Lee1,Daniel Hsieh1,Wuchen Fu1,Ho Chan Chang1,Sung Bum Kang1,Mayur Prabhudesai1,Jay Taylor1,Paul Braun1,Nenad Miljkovic1,Sanjiv Sinha1
University of Illinois at Urbana Champaign1
Phase change materials (PCMs) are promising materials for storing and discharging latent heat in buildings to regulate the thermal environment. Measurement of salt hydrate PCM thermal performance is often challenging because of supercooling and phase segregation. Though differential scanning calorimetry (DSC) has been widely used to measure thermal properties of various phase change materials, DSC uses milligrams of sample and is unrealistic for predicting large-scale materials performance. The T-history method [1], in contrast, handles higher volumes but the analysis typically requires a lumped capacitance assumption. Here, we report and analyze T-History data on a novel salt-hydrogel complex with high viscosity, that renders low Biot number sample preparation extremely challenging. We re-examine the standard T-history method and compared against DSC data in this complex material. We report details of an experimental setup, built with necessary additions to a controlled environmental chamber. We carefully examine the validity of the lumped capacitance assumption and suggest a modified analysis using a computational approach for reliable data. Experimental parameters such as ramp rate and temperature range of the environmental chamber are considered via computational modeling to understand the effect of ramp rate on supercooling [2]. Finally, we report thermal cycling experiments on the salt-hydrogel complex. Our modified approach to measuring supercooling and enthalpy of fusion at large scales is important in better understanding the performance of phase-change materials at scale for building thermal storage.<br/><br/><br/><u>References:</u><br/><br/>[1] Marin, Jose M, Belen Zalba, Luisa F Cabeza, and Harald Mehling. “Determination of Enthalpy Temperature Curves of Phase Change Materials with the Temperature-History Method: Improvement to Temperature Dependent Properties.” <i>Measurement Science and Technology</i> 14, no. 2 (February 1, 2003): 184–89. https://doi.org/10.1088/0957-0233/14/2/305.<br/>[2] Safari, A., R. Saidur, F.A. Sulaiman, Yan Xu, and Joe Dong. “A Review on Supercooling of Phase Change Materials in Thermal Energy Storage Systems.” <i>Renewable and Sustainable Energy Reviews</i> 70 (April 2017): 905–19. https://doi.org/10.1016/j.rser.2016.11.272.