Effect of Charging and Discharging Process of PCM with Paraffin and Al2O3 Additive Subjected to Three Point Temperature Locations

Kumar, Sunil K.; Muniamuthu, Sumathy; Mohan, A.; Amirthalingam, P.; Anbu Muthuraja, M.

doi:10.12911/22998993/144691

Artykuł - szczegóły

Tytuł artykułu

Effect of Charging and Discharging Process of PCM with Paraffin and Al2O3 Additive Subjected to Three Point Temperature Locations

Autorzy

Kumar Sunil K. , Muniamuthu Sumathy , Mohan A. , Amirthalingam P. , Anbu Muthuraja M.

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.12911/22998993/144691

Warianty tytułu

Języki publikacji

Abstrakty

This analysis focused on investigating thermal storage behaviour on phase change material along with Al₂O₃ as an additive. The experimental investigation was performed by three set temperature points, i.e. 40 °C, 50 °C and 60 °C with the mass circulation rate through the tank of 5 kg/min, 3 kg/min and 2 kg/min. The forced circulation method was used to circulate the liquid, water was used as a working medium and Al₂O₃ as nano particle. Paraffin acts a phase change material to conduct the experimental procedure. The combination of paraffin with Al₂O₃ improves the latent heat storage of the material. The performance, with respect to charging and discharging of the material, was investigated and it was observed that the temperature location point of 50 °C shows the best results in terms of charging and discharging phenomena, compared to other two temperature location points. During the process of charging, the maximum rate of heat transfer can be achieved by Al₂O₃ nanofluids. Paraffin along with Al₂O₃ are characterized by the best thermal storage behaviour during the latent heat storage at charging process and dissipation of heat during discharge process. The rapid cooling comparison for three set location points has been studied and best solidification was achieved at the point of 60 °C; this is due to the rapid cooling at higher elevation temperatures. The energy that was stored in thermal form is to be transferred with the aid of heat exchanger, a special type heat exchanger employed in this analysis to transfer the heat. From this analysis it is concluded that paraffin with Al₂O₃ are characterized by the best performance in terms of the charging and discharging phenomenon.

Słowa kluczowe

PCM material behavior paraffin wax charging discharging solar heater three point locations Al2O3

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2022

Tom

Vol. 23, nr 2

Strony

34--42

Opis fizyczny

Bibliogr. 30 poz., rys., tab.

Twórcy

autor

Kumar Sunil K.

sunilkumark@veltech.edu.in

Department of Mechanical Engineering, Vel Tech Rangarajan Dr. Sagunthala R&D Institute of Science and Technology, Chennai, India

https://orcid.org/0000-0002-5093-7307

autor

Muniamuthu Sumathy

Department of Mechanical Engineering, Vel Tech Rangarajan Dr. Sagunthala R&D Institute of Science and Technology, Chennai, India

https://orcid.org/0000-0002-3895-9386

autor

Mohan A.

Department of Mechanical Engineering, Vel Tech Rangarajan Dr. Sagunthala R&D Institute of Science and Technology, Chennai, India

autor

Amirthalingam P.

Department of Mechanical Engineering, Prathyusha Engineering College, Chennai, India

autor

Anbu Muthuraja M.

Department of Mechanical Engineering, Prathyusha Engineering College, Chennai, India

Bibliografia

1. Bejan A.S., Labihi A., Croitoru C.V., Catalina T., Chehouani H., Benhamou B. 2018. Experimental investigation of the charge/discharge process for an organic PCM macroencapsulated in an aluminium rectangular cavity. In E3S Web of Conferences. EDP Sciences, 32, 01004.
2. Belessiotis G.V., Papadokostaki K.G., Favvas E.P., Efthimiadou E.K., Karellas S. 2018. Preparation and investigation of distinct and shape stable paraffin/SiO2 composite PCM nanospheres. Energy Conversion and Management, 168, 382–394.
3. Bruch A., Molina S., Esence T., Fourmigué J.F., Couturier R. 2017. Experimental investigation of cycling behaviour of pilot-scale thermal oil packed-bed thermal storage system. Renewable Energy, 103, 277–285.
4. Chen C., Ling H., Zhai Z.J., Li Y., Yang F., Han F., Wei S. 2018. Thermal performance of an activepassive ventilation wall with phase change material in solar greenhouses. Applied energy, 216, 602–612.
5. Diani A., Campanale M. 2019. Transient melting of paraffin waxes embedded in aluminum foams: Experimental results and modeling. International Journal of Thermal Sciences, 144, 119–128.
6. Hosseinizadeh S.F., Tan F.L., Moosania S.M. 2011. Experimental and numerical studies on performance of PCM-based heat sink with different configurations of internal fins. Applied Thermal Engineering, 31(17–18), 3827–3838.
7. Jiang Y., Bahrami M., Bagherzadeh S.A., Abdollahi A., Sulgani M.T., Karimipour A., Goodarzi M., Bach Q.V. 2019. Propose a new approach of fuzzy lookup table method to predict Al2O3/deionized water nanofluid thermal conductivity based on achieved empirical data. Physica A: Statistical Mechanics and Its Applications, 527, 121177.
8. Karthikeyan S., Prathima A., Periyasamy M. 2020. Characteristics studies on Stoechospermum marginatum, brown marine algae with Al2O3 nanofluid. Materials Today: Proceedings, 33, 3746–3750.
9. Khanna S., Reddy K.S., Mallick T.K. 2018. Optimization of solar photovoltaic system integrated with phase change material. Solar Energy, 163, 591–599.
10. Krishnakumar T.S., Viswanath S.P., Varghese S.M. 2018. Experimental studies on thermal and rheological properties of Al2O3–ethylene glycol nanofluid. International Journal of Refrigeration, 89, 122–130.
11. Kumar N., Gupta S.K. 2021. Progress and application of phase change material in solar thermal energy: An overview. Materials Today: Proceedings, 44, 271–281.
12. Long J.Y., Zhu D.S. 2008. Numerical and experimental study on heat pump water heater with PCM for thermal storage. Energy and Buildings, 40(4), 666–672.
13. Maddah H., Aghayari R., Mirzaee M., Ahmadi M.H., Sadeghzadeh M., Chamkha A.J. 2018. Factorial experimental design for the thermal performance of a double pipe heat exchanger using Al2O3-TiO2 hybrid nanofluid. International Communications in Heat and Mass Transfer, 97, 92–102.
14. Manoj Kumar P., Mylsamy K., Alagar K., Sudhakar K. 2020. Investigations on an evacuated tube solar water heater using hybrid-nano based organic phase change material. International Journal of Green Energy, 17(13), 872–883.
15. McKenna P., Turner W.J.N., Finn D.P. 2021. Thermal energy storage using phase change material: Analysis of partial tank charging and discharging on system performance in a building cooling application. Applied Thermal Engineering, 198, 117437.
16. Pielichowska K., Pielichowski K. 2014. Phase change materials for thermal energy storage. Progress in materials science, 65, 67–123.
17. Qu Y., Wang S., Tian Y., Zhou D. 2019. Comprehensive evaluation of Paraffin-HDPE shape stabilized PCM with hybrid carbon nano-additives. Applied Thermal Engineering, 163, 114404.
18. Rai A.K., Kumar A. 2012. A review on phase change materials & their applications. International Journal of Advanced Research in Engineering & Technology (IJARET), 3(2), 214–225.
19. Ren X., Shen H., Yang Y., Yang J. 2019. Study on the properties of a novel shape-stable epoxy resin sealed expanded graphite/paraffin composite PCM and its application in buildings. Phase Transitions, 92(6), 581–594.
20. Safaei M.R., Goshayeshi H.R., Chaer I. 2019. Solar still efficiency enhancement by using Graphene oxide/paraffin nano-PCM. Energies, 12(10), 2002.
21. Sajawal M., Rehman T.U., Ali H.M., Sajjad U., Raza A., Bhatti M.S. 2019. Experimental thermal performance analysis of finned tube-phase change material based double pass solar air heater. Case Studies in Thermal Engineering, 15, 100543.
22. Sheikholeslami M., Gerdroodbary M.B., Moradi R., Shafee A., Li Z. 2019. Application of Neural Network for estimation of heat transfer treatment of Al2O3-H2O nanofluid through a channel. Computer Methods in Applied Mechanics and Engineering, 344, 1–12.
23. Suraparaju S.K., Natarajan S.K. 2021. Experimental investigation of single-basin solar still using solid staggered fins inserted in paraffin wax PCM bed for enhancing productivity. Environmental Science and Pollution Research, 28(16), 20330–20343.
24. Tay N.S., Bruno F., Belusko M. 2012. Experimental validation of a cfd and a ε-ntu model for tubes in a large pcm tank.
25. Wang Y., Xu J., Liu Q., Chen Y., Liu H. 2016. Performance analysis of a parabolic trough solar collector using Al2O3/synthetic oil nanofluid. Applied Thermal Engineering, 107, 469–478.
26. Xu C., Xu S., Eticha R.D. 2021. Experimental investigation of thermal performance for pulsating flow in a microchannel heat sink filled with PCM (paraffin/CNT composite). Energy Conversion and Management, 236, 114071.
27. Yang T., King W.P., Miljkovic N. 2021. Phase change material-based thermal energy storage. Cell Reports Physical Science, 2(8), 100540.
28. Zhang S., Zhang L., Yang X., Yu X., Duan F., Jin L., Meng X. 2017. Experimental investigation of a spiral tube embedded latent thermal energy storage tank using paraffin as PCM. Energy Procedia, 105, 4543–4548.
29. Zhang Y., Liu S., Yang L., Yang X., Shen Y., Han X. 2020. Experimental Study on the Strengthen Heat Transfer Performance of PCM by Active Stirring. Energies, 13(9), 2238.
30. Zhou D., Zhao C.Y., Tian Y. 2012. Review on thermal energy storage with phase change materials (PCMs) in building applications. Applied energy, 92, 593–605.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-63015069-5a25-45c6-8b59-319751c667ea