Chinese

Journal of Thermal Science

热科学学报

Journal of Thermal Science >

2024 , Vol. 33 >Issue 3: 1026 - 1036

DOI: https://doi.org/10.1007/s11630-024-1946-8

Numerical Analysis on Charging Performance of the Macro-Encapsulating Combined Sensible-Latent Heat Storage System with Structural Parameters

  • WANG Wei ,
  • PAN Zhenfei ,
  • WANG Jingfu ,
  • WU Yuting ,
  • MA Chongfang
Expand
  • 1. Key Laboratory of Enhanced Heat Transfer and Energy Conservation, Ministry of Education, College of Energy and Power Engineering, Beijing University of Technology, Beijing 100124, China
    2. Key Laboratory of Heat Transfer and Energy Conversion, Beijing Municipality, College of Energy and Power Engineering, Beijing University of Technology, Beijing 100124, China

Online published: 2024-04-30

Supported by

This work was supported by National Key R&D Program of China (Grant numbers 2022YFB2405202).

Copyright

This work was supported by National Key R&D Program of China (Grant numbers 2022YFB2405202).
Fold

Abstract

For combined sensible-latent heat storage system (CSLHS) (termed as the hybrid configuration), macro encapsulation can effectively solve the leakage problem of PCMs. However, due to the poor thermal conductivity of PCMs, the charging performance of the hybrid configuration slightly increases compared to the solid structure (with only sensible materials). Meanwhile, the natural convection in the PCMs zone could improve the charging performance. So, how to improve natural convection intensity is a key issue for the CSLHS by macro encapsulating. It is found that adding fins can significantly enhance natural convection and accelerate the melting of PCM. In this paper, we proposed the hybrid configuration with fins built-in by macro encapsulation, and analyzed its charging performance with different fin structural parameters in the PCM zone by CFD simulation. In the case, the sensible heat storage material is high-temperature concrete and the PCM is a low-melting-point mixed molten salt. We analyzed the effects of fin number, fin length and fin thickness on the charging performance of the hybrid configuration respectively. From the result, the charging performance increases with the fin number, but the increase rate gradually decreases. When the fin number is 6, the charging performance increases by 20.18% compared to the situation without fin. The charging performance increases gradually with the fin length. Compared with the hybrid configuration without fin, for each 10 mm increase in fin length, its charging performances increase by 4.09%, 5.26%, 7.02%, 8.77%, 11.70%, and 15.79%, respectively. Different from number and length of fins, the effect of thickness on the charging performance is very small. When the fin thickness increased from 1 mm to 4 mm, the charging performance only increased by 2.3%. It indicates that the main reason for the improving the charging performance is to increase the natural convection intensity by dividing the PCM zone through fins. These results show that the charging performance of the CSLHS with macro encapsulation can be improved by optimizing fin structural parameters.

Key words: macro-encapsulation; hybrid configuration; natural convection; structural parameter; charging performance

Cite this article

WANG Wei , PAN Zhenfei , WANG Jingfu , WU Yuting , MA Chongfang . Numerical Analysis on Charging Performance of the Macro-Encapsulating Combined Sensible-Latent Heat Storage System with Structural Parameters[J]. Journal of Thermal Science, 2024 , 33(3) : 1026 -1036 . DOI: 10.1007/s11630-024-1946-8

References

[1] Statistical Bulletin on National Economic and Social Development of the People’s Republic of China in 2022.
http://www.stats.gov.cn/xxgk/sjfb/zxfb2020/202302/t20230228_1919001.html
[2] Kousksou T., Jamil A., Bruel P., Asymptotic behavior of a storage unit undergoing cyclic melting and solidification processes. Journal of Thermophysics & Heat Transfer, 2010, 24(2): 355–363.
[3] Feng P.H., Zhao B.C., Wang R.Z., Thermophysical heat storage for cooling, heating, and power generation: A review. Applied Thermal Engineering, 2020, 166: 114728.
[4] Shen Y.L., Liu S.L., Mazhar A.R., et al., A review of solar-driven short-term low temperature heat storage systems. Renewable and Sustainable Energy Reviews, 2021, 141: 110824.
[5] Tan F.L., Tso C.P., Cooling of mobile electronic devices using phase change materials. Applied Thermal Engineering, 2004, 24(2–3): 159–169.
[6] Sharma R.K., Ganesan P., Tyagi V.V., et al., Developments in organic solid liquid phase change materials and their applications in thermal energy storage. Energy Conversion and Management, 2015, 95(1): 193–228.
[7] Fraid M.M., Khudhair A.M., Razack S.A.K., et al., A review on phase change energy storage: Materials and applications. Energy Conversion and Management, 2004, 45(9/10): 1597–1615.
[8] Bradshaw R.W., Brosseau D., Low-melting point inorganic nitrate salt heat transfer fluid. US patent 7588694, 2009-9-15.
[9] Xu C., Li X., Wang Z.F., et al., Effects of solid particle properties on the thermal performance of a packed-bed molten-salt thermocline thermal storage system. Applied Thermal Engineering, 2013, 57: 69–80.
[10] Suresh C., Saini R.P., Experimental study on combined sensible-latent heat storage system for different volume fractions of PCM. Solar Energy, 2020, 212: 282–296.
[11] Shen Y., Liu S., Zeng C., et al., Experimental thermal study of a new PCM-concrete thermal storage block (PCM-CTSB). Construction and Building Materials, 2021, 293: 123540.
[12] Ahmed N., Elfeky K.E., Lu L., et al., Thermal and economic evaluation of thermocline combined sensible-latent heat thermal energy storage system for medium temperature applications. Energy Conversion and Management, 2019, 189: 14–23.
[13] Frazzica A., Manzan M., Sapienza A., et al., Experimental testing of a hybrid sensible-latent heat storage system for domestic hot water applications. Applied Energy, 2016, 183: 1157–1167.
[14] Okello D., Foong C.W., Nydal O.J., et al., An experimental investigation on the combined use of phase change material and rock particles for high temperature (~350°C) heat storage. Energy Conversion and Management, 2014, 79: 1–8.
[15] Xiao X., Zhang P., Li M., Thermal characterization of nitrates and nitrates/expanded graphite mixture phase change materials for solar energy storage. Energy Conversion and Management, 2013, 73: 86–94.
[16] Tian H.Q., Huang C.L., Ding J., et al., Preparation of binary eutectic chloride/expanded graphite as high-temperature thermal energy storage materials. Solar Energy Materials and Solar Cells, 2016, 149: 187–194.
[17] Ho M.X., Pan C., Optimal concentration of alumina nanoparticles in molten Hitec salt to maximize its specific heat capacity. International Journal of Heat and Mass Transfer, 2014, 70: 174–184.
[18] Yu Q., Lu Y., Zhang C., et al., Research on thermal properties of novel silica nanoparticle/binary nitrate/expanded graphite composite heat storage blocks. Solar Energy Materials and Solar Cells, 2019, 201: 110055.
[19] Wang W., Pan Z.F., Lei B., et al., Numerical simulation of charging performance of combined sensible-latent heat storage system with a macro-encapsulation method. Journal of Thermal Science, 2023, 32(6): 2008–2017. 
[20] Kamkari B., Shokouhmand H., Bruno F., Experimental investigation of the effect of inclination angle on convection-driven melting of phase change material in a rec-tangular enclosure. International Journal of Heat and Mass Transfer, 2014, 72: 186–200.
[21] Webb B.W.W., Viskanta R., Natural-convection- dominated melting heat transfer in an inclined rectangular enclosure. International Journal of Heat and Mass Transfer, 1986, 29: 183–192.
[22] Huang B.K, Yang S.M., Hu E.Y., et al., Theoretical study on melting of phase change material by natural convection. Case Studies in Thermal Engineering, 2021, 28: 101620.
[23] Bondareva N.S., Sheremet M.A., Flow and heat transfer evolution of PCM due to natural convection melting in a square cavity with a local heater. International Journal of Mechanical Sciences, 2017, 134: 610–619.
[24] Ye W., Guo H., Huang S., et al., Research on melting and solidification processes for enhanced double tubes with constant wall temperature/wall heat flux. Heat transfer Asian research, 2018, 47(3): 583–599.
[25] Ye W., Enhanced latent heat thermal energy storage in the double tubes using fins. Journal of Thermal Analysis and Calorimetry, 2017, 128(1): 533–540.
[26] Ji C.Z., Qin Z., Dubey S., et al., Simulation on PCM melting enhancement with double-fin length arrangements in a rectangular enclosure induced by natural convection. International Journal of Heat and Mass Transfer, 2018, 127: 255–265.
[27] Shafiq M.S., Khan M.M., Effects of fin length distribution functions and enclosure aspect ratio on latent thermal energy storage performance of dual-wall-heated unit. Journal of Energy Storage, 2022, 53: 105247.
[28] Barthwal M., Rakshit D., No fins attached? Numerical analysis of internal-external fins coupled PCM melting for solar applications. Applied Thermal Engineering, 2022, 215: 118911.
[29] Yildiz C., Arici M., Nizetic S., et al., Numerical investigation of natural convection behavior of molten PCM in an enclosure having rectangular and tree-like branching fins. Energy, 2020, 207: 118223.
[30] Ye W., Melting process in a rectangular thermal storage cavity heated from vertical walls. Journal of Thermal Analysis and Calorimetry, 2016, 123(1): 873–880.
[31] Ye W., Thermal and hydraulic performance of natural convection in a rectangular storage cavity. Applied Thermal Engineering, 2016, 93: 1114–1123.
[32] Mahdi M.S., Mahood H.B., Campbell A.N., et al., Natural convection improvement of PCM melting in partition latent heat energy storage: Numerical study with experimental validation. International Communications in Heat and Mass Transfer, 2021, 126: 105463.
[33] Morimoto T., Kumano H., Natural convection characteristics of phase-change material emulsions in a rectangular vessel with vertical heating/cooling walls. International Journal of Heat and Mass Transfer, 2022, 183: 122234.
[34] Zhu J.Q., Dong Q., Cheng X.M., et al., Numerical simulation on charge and discharge performance of high temperature concrete thermal storage module. Journal of Wuhan University of Technology, 2013, 12: 5. (in Chinese) 
DOI: 10.3963/j.issn.1671-4431.2013.12.001
[35] Ren N., Wu Y.T., Ma C.F., et al., Preparation and thermal properties of quaternary mixed nitrate with low melting point. Solar Energy Materials and Solar Cells, 2014, 127: 6–13.
[36] Soliman A.S., Zhu S., Xu L., et al., Numerical simulation and experimental verification of constrained melting of phase change material in cylindrical enclosure subjected to a constant heat flux. The Journal of Energy Storage, 2021, 35: 102312.
[37] Mahdi M.S., Mahood H.B., Campbell A.N., et al., Natural convection improvement of PCM melting in partition latent heat energy storage: Numerical study with experimental validation. International Communications in Heat and Mass Transfer, 2021, 126: 105423.
[38] Dhaidan N.S., Khodadadi J.M., Al-Hattab T.A., et al., Experimental and numerical study of constrained melting of n-octadecane with CuO nanoparticle dispersions in a horizontal cylindrical capsule subjected to a constant heat flux. International Journal of Heat and Mass Transfer, 2013, 67: 523–534.
Options
Outlines

/

Wechat

Sponsored by: Institute of Engineering Thermophysics, Chinese Academy of Sciences Publisher: Science Press

Copyright © 2023 Journal of Thermal Science