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Accelerated solidification of PCM via Al2O3/CuO hybrid nanoparticles in triplex tube heat storage

Yıl 2024, Cilt: 10 Sayı: 4, 880 - 903, 29.07.2024

Öz

The thermal performance and heat transfer augmentation of paraffin wax as a phase change material (PCM) throughout discharging process within a triplex tube heat storage have been examined using a combined experimental and numerical analysis. The efforts of this research are focused on using a blend of two different types of highly conductive nanoparticles (Al2O3/CuO hybrid nano additives) to enhance the thermal characteristics of paraffin and improve the overall performance of TTHS, which is the originality of this study. Various volume concentrations (0.4, 0.8, 1.6, 3.2%) of hybrid nanoparticles were explored. Besides that, A set of tests were carried out to evaluate the impact of changing inlet temperature and mass flow rate of the heat transfer fluid (HTF) on the phase change phenomenon of the paraffin. The mass flow rates of HTF ranges from 3 kg/min to 12 kg/min while the temperatures of HTF varies from 30 °C to 40 °C. The calculations are included an iterative, finite-volume numerical technique that involves a domain enthalpy porosity model to simulate the phase transition process. The agreement between the experimental data and the numerical simulation is good. According to the results, reducing inlet temperature and/or increase the inlet mass flow rate of HTF speed up solidification rate. However, HTF inlet temperature has more impact on solidification rate than inlet mass flow rate. Moreover, the reduction in freezing duration caused by implementing hybrid nanoparticles has been observed for all volume concentrations investigated. However, adding 3.2% volume percentage of hybrid nanoparticles results in the highest overall freezing time reduction (about 23%).

Kaynakça

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Yıl 2024, Cilt: 10 Sayı: 4, 880 - 903, 29.07.2024

Öz

Kaynakça

  • [1] Dincer I, Rosen MA. Thermal Energy Storage: Systems and Applications. John Wiley & Sons; 2021. [CrossRef]
  • [2] Afsharpanah F, Pakzad K, Ajarostaghi SSM, Arıcı M. Assessment of the charging performance in a cold thermal energy storage container with two rows of serpentine tubes and extended surfaces. J Energy Storage 2022;51:104464. [CrossRef]
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  • [4] Abed AH. Thermal storage efficiency enhancement for solar air heater using a combined SHSm and PCM cylindrical capsules system: Experimental investigation. Eng Technol J 2016;34:9991011. [CrossRef]
  • [5] Tawalbeh M, Khan HA, Al-Othman A, Almomani F, Ajith S. A comprehensive review on the recent advances in materials for thermal energy storage applications. Int J Thermofluids 2023;18:100326. [CrossRef]
  • [6] Aljabair S, Alesbe I, Ibrahim SH. Review on latent thermal energy storage using phase change material. J Therm Eng. 2021;9:247256. [CrossRef]
  • [7] Sadr AN, Shekaramiz M, Zarinfar M, Esmaily A, Khoshtarash H, Toghraie D. Simulation of mixed-convection of water and nano-encapsulated phase change material inside a square cavity with a rotating hot cylinder. J Energy Storage 2022;47:103606. [CrossRef]
  • [8] Modi N, Wang X, Negnevitsky M. Solar hot water systems using latent heat thermal energy storage: perspectives and challenges. Energies 2023;16:1969. [CrossRef]
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  • [12] Yang S, Shao XF, Luo JH, Oskouei SB, Bayer Ö, Fan LW. A novel cascade latent heat thermal energy storage system consisting of erythritol and paraffin wax for deep recovery of medium-temperature industrial waste heat. Energy 2023;265:126359. [CrossRef]
  • [13] Sadr AK, Sivan S, Midhun V, Behera SR. Experimental and numerical investigation of solid-solid phase change material assisted heat sink with integrated heat pipe for electronic cooling. J Energy Storage 2023;59:106494. [CrossRef]
  • [14] Rathore PKS, Gupta NK, Yadav D, Shukla SK, Kaul S. Thermal performance of the building envelope integrated with phase change material for thermal energy storage: An updated review. Sustain Cities Soc 2022;79:103690. [CrossRef]
  • [15] Paul J, Pandey A, Mishra YN, Said Z, Mishra YK, Ma Z, et al. Nano-enhanced organic form stable PCMs for medium temperature solar thermal energy harvesting: Recent progresses, challenges, and opportunities. Renew Sustain Energy Rev 2022;161:112321. [CrossRef]
  • [16] Chang Y, Yao X, Chen Y, Zou D. Review on ceramic-based composite phase change materials: preparation, characterization and application. Compos Part B Engineer 2023;110584. [CrossRef]
  • [17] Safari V, Abolghasemi H, Darvishvand L, Kamkari B. Thermal performance investigation of concentric and eccentric shell and tube heat exchangers with different fin configurations containing phase change material. J Energy Storage 2021;37:117. [CrossRef]
  • [18] Sodhi GS, Muthukumar P. Compound charging and discharging enhancement in multi-PCM system using non-uniform fin distribution. Renew Energy 2021;171:299314. [CrossRef]
  • [19] Ebrahimi A, Hosseini MJ, Ranjbar AA, Rahimi M, Bahrampoury R. Melting process investigation of phase change materials in a shell and tube heat exchanger enhanced with heat pipe. Renew Energy 2019;138:378394. [CrossRef]
  • [20] Ling YZ, Zhang XS, Wang F, She XH. Performance study of phase change materials coupled with three-dimensional oscillating heat pipes with different structures for electronic cooling. Renew Energy 2020;154:636649. [CrossRef]
  • [21] Haddad Z, Iachachene F, Sheremet MA, Abu-Nada E. Numerical investigation and optimization of melting performance for thermal energy storage system partially filled with metal foam layer: New design configurations. Appl Therm Engineer 2023;223:119809.
  • [22] Righetti G, Zilio C, Longo GA, Hooman K, Mancin S. Experimental study on the effect of metal foams pore size in a phase change material based thermal energy storage tube. Appl Therm Engineer 2022;217:119163. [CrossRef]
  • [23] Singh SK, Verma SK, Kumar R. Thermal performance and behavior analysis of SiO2, Al2O3 and MgO based nano-enhanced phase-changing materials, latent heat thermal energy storage system. J Energy Storage 2022;48:103977. [CrossRef]
  • [24] Nie C, Deng S, Liu J, Rao Z. Performance evaluation of shell-tube latent heat storage unit using nanoparticles with cascaded concentration. J Energy Storage 2023;62:106892. [CrossRef]
  • [25] Yu X, Tao Y. Improvement of thermal cycle stability of paraffin/expanded graphite composite phase change materials and its application in thermal management. J Energy Storage 2023;63:107019. [CrossRef]
  • [26] Tang X, Zhang J, Wang J, Xu T, Du Y, Fan G, et al. Preparation and application of paraffin/expanded graphite-based phase change material floor for solar-heat pump combined radiant heating systems. ACS Sustain Chem Engineer 2023;11:28712884. [CrossRef]
  • [27] Fikri MA, Pandey A, Samykano M, Kadirgama K, George M, Saidur R, et al. Thermal conductivity, reliability, and stability assessment of phase change material (PCM) doped with functionalized multi-wall carbon nanotubes (FMWCNTs). J Energy Storage 2022;50:104676. [CrossRef]
  • [28] Li X, Zhao Y, Min X, Xiao J, Wu X, Mi R, et al. Carbon nanotubes modified graphene hybrid aerogel-based composite phase change materials for efficient thermal storage. Energy Build 2022;273:112384. [CrossRef]
  • [29] Cabeza LF, Zsembinszki G, Martín M. Evaluation of volume change in phase change materials during their phase transition. J Energy Storage 2020;28:101206. [CrossRef]
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  • [31] Mahdi JM, Nsofor EC. Solidification enhancement of PCM in a triplex-tube thermal energy storage system with nanoparticles and fins. Appl Energy 2018;211:975986. [CrossRef]
  • [32] Liu MJ, Fan LW, Zhu ZQ, Feng B, Zhang HC, Zeng Y. A volume-shrinkage-based method for quantifying the inward solidification heat transfer of a phase change material filled in spherical capsules. Appl Therm Engineer 2016;108:12001205. [CrossRef]
  • [33] Ismail M, Alkhazaleh AH, Masri J, Ali AM, Ali M. Experimental and numerical analysis of paraffin waxes during solidification inside spherical capsules. Therm Sci Engineer Prog 2021;26:101095. [CrossRef]
  • [34] Chen L, Wang L, Wang Y, Chen H, Lin X. Influence of phase change material volume shrinkage on the cyclic process of thermal energy storage: A visualization study. Appl Therm Engineer 2022;203:117776. [CrossRef]
  • [35] Abdulateef AM, Mat S, Abdulateef J, Sopian K, Al-Abidi AA. Geometric and design parameters of fins employed for enhancing thermal energy storage systems: A review. Renew Sustain Energy Rev 2018;82:16201635. [CrossRef]
  • [36] Karami R, Kamkari B. Experimental investigation of the effect of perforated fins on thermal performance enhancement of vertical shell and tube latent heat energy storage systems. Energy Conver Manage 2020;210:112679. [CrossRef]
  • [37] Khan LA, Khan MM. Role of orientation of fins in performance enhancement of a latent thermal energy storage unit. Appl Therm Engineer 2020;175:115408. [CrossRef]
  • [38] Yousef MS, Hassan H, Kodama S, Sekiguchi H. An experimental study on the performance of single slope solar still integrated with a PCM-based pin-finned heat sink. Energy Procedia 2019;156:100104. [CrossRef]
  • [39] Liu Z, Liu Z, Guo J, Wang F, Yang X, Yan J. Innovative ladder-shaped fin design on a latent heat storage device for waste heat recovery. Appl Energy 2022;321:119300. [CrossRef]
  • [40] Wu J, Li N, Wu Z. Experimental investigation of latent energy storage systems with the tree-pin-shaped fin. Appl Therm Engineer 2023;227:120370. [CrossRef]
  • [41] Mahdi JM, Nsofor EC. Multiple-segment metal foam application in the shell-and-tube PCM thermal energy storage system. J Energy Storage 2018;20:529541. [CrossRef]
  • [42] Hamza N, Aljabair S. Review of heat transfer enhancement using hybrid nanofluid or twisted tape insert. J Mech Engineer Res Dev 2021;44:345357.
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Toplam 80 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Termodinamik ve İstatistiksel Fizik
Bölüm Makaleler
Yazarlar

Ibrahim E. Sadiq Bu kişi benim 0009-0009-0072-8118

Sattar Aljabair Bu kişi benim 0000-0002-0528-8651

Abdulhassan A. Karamallah Bu kişi benim 0000-0002-9035-6611

Yayımlanma Tarihi 29 Temmuz 2024
Gönderilme Tarihi 27 Mayıs 2023
Yayımlandığı Sayı Yıl 2024 Cilt: 10 Sayı: 4

Kaynak Göster

APA Sadiq, I. E., Aljabair, S., & Karamallah, A. A. (2024). Accelerated solidification of PCM via Al2O3/CuO hybrid nanoparticles in triplex tube heat storage. Journal of Thermal Engineering, 10(4), 880-903.
AMA Sadiq IE, Aljabair S, Karamallah AA. Accelerated solidification of PCM via Al2O3/CuO hybrid nanoparticles in triplex tube heat storage. Journal of Thermal Engineering. Temmuz 2024;10(4):880-903.
Chicago Sadiq, Ibrahim E., Sattar Aljabair, ve Abdulhassan A. Karamallah. “Accelerated Solidification of PCM via Al2O3/CuO Hybrid Nanoparticles in Triplex Tube Heat Storage”. Journal of Thermal Engineering 10, sy. 4 (Temmuz 2024): 880-903.
EndNote Sadiq IE, Aljabair S, Karamallah AA (01 Temmuz 2024) Accelerated solidification of PCM via Al2O3/CuO hybrid nanoparticles in triplex tube heat storage. Journal of Thermal Engineering 10 4 880–903.
IEEE I. E. Sadiq, S. Aljabair, ve A. A. Karamallah, “Accelerated solidification of PCM via Al2O3/CuO hybrid nanoparticles in triplex tube heat storage”, Journal of Thermal Engineering, c. 10, sy. 4, ss. 880–903, 2024.
ISNAD Sadiq, Ibrahim E. vd. “Accelerated Solidification of PCM via Al2O3/CuO Hybrid Nanoparticles in Triplex Tube Heat Storage”. Journal of Thermal Engineering 10/4 (Temmuz 2024), 880-903.
JAMA Sadiq IE, Aljabair S, Karamallah AA. Accelerated solidification of PCM via Al2O3/CuO hybrid nanoparticles in triplex tube heat storage. Journal of Thermal Engineering. 2024;10:880–903.
MLA Sadiq, Ibrahim E. vd. “Accelerated Solidification of PCM via Al2O3/CuO Hybrid Nanoparticles in Triplex Tube Heat Storage”. Journal of Thermal Engineering, c. 10, sy. 4, 2024, ss. 880-03.
Vancouver Sadiq IE, Aljabair S, Karamallah AA. Accelerated solidification of PCM via Al2O3/CuO hybrid nanoparticles in triplex tube heat storage. Journal of Thermal Engineering. 2024;10(4):880-903.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering