PDF Publication Title:
Text from PDF Page: 037
M.M. Kenisarin, et al. Journal of Energy Storage 27 (2020) 101082 [34] M.J. Li, B. Jin, Z. Ma, F. Yuan, Experimental and numerical study on the perfor- mance of a new high-temperature packed-bed thermal energy storage system with macroencapsulation of molten salt phase change material, Appl. Energy 221 (2018 Jul 1) 1–5. [35] E. Alptekin, M. Özer, M. Top, F.E. Yavuz, M.A. Ezan, A numerical study on phase change inside a spherical capsule, Exergetic Energetic Environ. Dimensions (2018) 613–625. [36] Cristopia Energy Systems – The STL Technology. Available at http://www.cris- topia.com/EN/la-technologie-stl.html. [37] M.N. Fard, H.T. Jokari, Experimental and numerical simulation of phase change material melting and solidification inside sphere capsule for thermal energy sto- rage, 9th International Conference on Electrical, Computer, Mechanical and Mechatronics Engineering, Istanbul, Turkey, ICE-2018, 2018September 6-7. [38] M. Bechiri, K. Mansouri, N. Hamlet, S Amirat, Numerical solution of NEPCM melting inside spherical enclosure, 3rd International Conference on Control, Engineering & Information Technology (CEIT), IEEE, 2015 May 25, pp. 1–4. [39] K. Rachedi, A.I. Korti, Numerical simulation of melting and solidification of dif- ferent kinds of phase change materials (pcm) encapsulated in spherical nodules in a water flow, Comput. Therm. Sci. 9 (4) (2017) 297–310. [40] W. Li, Y.H. Wang, C.C. Kong, Experimental study on melting/solidification and thermal conductivity enhancement of phase change material inside a sphere, Int. Commun. Heat Mass Transf. 68 (2015) 276–282. [41] M. Hlimi, S. Hamdaoui, M. Mahdaoui, T. Kousksou, A.A. Msaad, A. Jamil, A. El Bouardi, Melting inside a horizontal cylindrical capsule, Case Stud. Therm. Eng. 8 (2016 Sep 1) 359–369. [42] R. Prabakaran, J.P. Kumar, D.M. Lal, C. Selvam, S. Harish, Constrained melting of graphene-based phase change nanocomposites inside a sphere, J. Therm. Anal. Calorim. (2019) In Press. Available at https://link.springer.com/article/10.1007/ s10973-019-08458-4. [43] H. Yang, J. Song, B. He, G Ding, Numerical study on charging characteristics of heat pipe-assisted cylindrical capsule for enhancing latent thermal energy storage, Solar Energy 190 (2019 Sep 15) 147–155. [44] L.M Jiji, Heat Conduction, Third ed., Springer Verlag Berlin Heidelberg, 2009. [45] E.M. Sparrow, R.R. Schmidt, J.T. Ramsey, Experiments on the role of natural convection in the melting of solids, J. Heat Transf. 100 (1) (1978 Feb 1) 11–16. [46] N.W. Hale Jr, R. Viskanta, Photographic observation of the solid-liquid interface motion during melting of a solid heated from an isothermal vertical wall, Lett. Heat Mass Transf. 5 (6) (1978 Nov 1) 329–337. [47] J.M. Khodadadi, Y. Zhang, Effects of buoyancy-driven convection on melting within spherical containers, Int. J. Heat Mass Transf. 44 (8) (2001 Apr 1) 1605–1618. [48] F.L. Tan, Constrained and unconstrained melting inside a sphere, Int. Commun. Heat Mass Transf. 35 (4) (2008 Apr 1) 466–475. [49] F.L. Tan, S.F. Hosseinizadeh, J.M. Khodadadi, L. Fan, Experimental and compu- tational study of constrained melting of phase change materials (PCM) inside a spherical capsule, Int. J. Heat Mass Transf. 52 (15–16) (2009 Jul 1) 3464–3472. [50] S.A. Khot, N.K. Sane, B.S. Gawali, Experimental investigation of phase change phenomena of paraffin wax inside a capsule, Int. J. Eng. Trends Technol. 2 (2) (2011). [51] P.A. Galione, O. Lehmkuhl, J. Rigola, A. Oliva, Fixed-grid numerical modeling of melting and solidification using variable thermo-physical properties–application to the melting of n-octadecane inside a spherical capsule, Int. J. Heat Mass Transf. 86 (2015) 721–743. [52] W. Li, S.G. Li, S. Guan, Y. Wang, X. Zhang, X. Liu, Numerical study on melt fraction during melting of phase change material inside a sphere, Int. J. Hydrogen Energy 42 (29) (2017 Jul 20) 18232–18239. [53] H. Sattari, A. Mohebbi, M.M. Afsahi, A.A. Yancheshme, CFD simulation of melting process of phase change materials (PCMs) in a spherical capsule, Int. J. Refrig. 73 (2017) 209–218. [54] V. Soni, A. Kumar, V.K. Jain, Modeling of PCM melting: analysis of discrepancy between numerical and experimental results and energy storage performance, Energy 150 (2018) 190–204. [55] F.E. Moore, Y. Bayazitoglu, Melting within a spherical enclosure, J. Heat Transf. 104 (1) (1982 Feb 1) 19–23. [56] P.A. Bahrami, T.G. Wang, Analysis of gravity and conduction-driven melting in a sphere, J. Heat Transf. 109 (3) (1987 Aug 1) 806–809. [57] S.K. Roy, S. Sengupta, The melting process within spherical enclosures, J. Heat Transf. 109 (1987) 460–462. [58] M. Bareiss, H. Beer, An analytical solution of the heat transfer process during melting of an unfixed solid phase change material inside a horizontal tube, Int. J. Heat Mass Transf. 27 (5) (1984 May 1) 739–746. [59] F.E. Moore, Melting within a Spherical Enclosure, M. S. thesis Rice University, 1981. [60] M. Toksoy, B.Z İlken, Melting in a spherical enclosure: an experimental study, in: B. Kılkış, S. Kakaç (Eds.), Energy Storage Systems, Kluwer Academic Publishers, 1989, pp. 735–742. [61] B. Carlsson, G. Wettermark, Heat-transfer properties of a heat-of-fusion store based on CaCl2•6H2O, Solar Energy 24 (3) (1980 Jan 1) 239–247. [62] A.D. Solomon, Melt time and heat flux for a simple PCM body, Solar Energy 22 (3) (1979 Jan 1) 251–257. [63] T.S. Saitoh, H. Kato, H Hoshina, Theoretical analysis for combined close-contact and natural convection melting in ice storage spherical capsule, IECEC 96. Proceedings of the 31st Intersociety Energy Conversion Engineering Conference, 3 IEEE, 1996 Aug 11, pp. 2104–2108. [64] Y. Hu, M. Shi, Close-contact melting in a spherical enclosure, Sci. China Ser. E 41 (1) (1998 Feb 1) 82–87. [65] S.A. Fomin, T.S. Saitoh, Melting of unfixed material in spherical capsule with non- isothermal wall, Int. J. Heat Mass Transf. 42 (22) (1999 Nov 1) 4197–4205. [66] I.W. Eames, K.T. Adref, Freezing and melting of water in spherical enclosures of the type used in thermal (ice) storage systems, Appl. Therm. Eng. 22 (7) (2002 May 1) 733–745. [67] K.T. Adref, I.W. Eames, Experiments on charging and discharging of spherical thermal (ice) storage elements, Int. J. Energy Res. 26 (11) (2002 Sep 1) 949–964. [68] H. Ettouney, H. El-Dessouky, A. Al-Ali, Heat transfer during phase change of paraffin wax stored in spherical shells, J. Solar Energy Eng. 127 (3) (2005 Aug 1) 357–365. [69] A. Regin, S.C. Solanki, J.S Saini, Experimental and numerical analysis of melting of PCM inside a spherical capsule, 9th AIAA/ASME Joint Thermophysics and Heat Transfer Conference, 2006, p. 3618. [70] B. Bulunti, C. Arslanturk, Analysis of inward melting of spheres subject to con- vection and radiation, J. Therm. Sci. Techonology. 26 (2) (2006) 11–16. [71] E. Assis, L. Katsman, G. Ziskind, R. Letan, Numerical and experimental study of melting in a spherical shell, Int. J. Heat Mass Transf. 50 (9–10) (2007 May 1) 1790–1804. [72] M. Veerappan, S. Kalaiselvam, S. Iniyan, R Goic, Phase change characteristic study of spherical PCMs in solar energy storage, Solar Energy 83 (8) (2009 Aug 1) 1245–1252. [73] H. Koizumi, Time and spatial heat transfer performance around an isothermally heated sphere placed in a uniform, downwardly directed flow (in relation to the enhancement of latent heat storage rate in a spherical capsule), Appl. Therm. Eng. 24 (17–18) (2004) 2583–2600. [74] A.R. Archibold, M.M. Rahman, D.Y. Goswami, E.L Stefanakos, Parametric in- vestigation of the melting and solidification process in an encapsulated spherical container, ASME 2012 6th International Conference on Energy Sustainability collocated with the ASME 2012 10th International Conference on Fuel Cell Science, Engineering and Technology, 2012 Jul 23, pp. 573–584. American Society of Mechanical Engineers. [75] M.Z. Rizan, F.L. Tan, C.P. Tso, An experimental study of n-octadecane melting inside a sphere subjected to constant heat rate at surface, Int. Commun. Heat Mass Transf. 39 (10) (2012 Dec 1) 1624–1630. [76] S.F. Hosseinizadeh, A.R. Darzi, F.L. Tan, J.M. Khodadadi, Unconstrained melting inside a sphere, Int. J. Therm. Sci. 63 (2013 Jan 1) 55–64. [77] S.F. Hosseinizadeh, A.R. Darzi, F.L. Tan, Numerical investigations of un- constrained melting of nano-enhanced phase change material (NEPCM) inside a spherical container, Int. J. Therm. Sci. 51 (2012 Jan 1) 77–83. [78] A.R. Archibold, J. Gonzalez-Aguilar, M.M. Rahman, D.Y. Goswami, M. Romero, E.K. Stefanakos, The melting process of storage materials with relatively high phase change temperatures in partially filled spherical shells, Appl. Energy 116 (2014 Mar 1) 243–252. [79] A.R. Archibold, M.M. Rahman, D.Y. Goswami, E.K. Stefanakos, Analysis of heat transfer and fluid flow during melting inside a spherical container for thermal energy storage, Appl. Therm. Eng. 64 (1–2) (2014 Mar 1) 396–407. [80] L.W. Fan, Z.Q. Zhu, Y. Zeng, Q. Ding, M.J. Liu, Unconstrained melting heat transfer in a spherical container revisited in the presence of nano-enhanced phase change materials (NePCM), Int. J. Heat Mass Transf. 95 (2016 Apr 1) 1057–1069. [81] K. Hariharan, G.S. Kumar, G. Kumaresan, R. Velraj, Investigation on phase change behavior of paraffin phase change material in a spherical capsule for solar thermal storage units, Heat Transf. Eng. 39 (9) (2018 May 28) 775–783. [82] D. Ghosh, C. Guha, Numerical and experimental investigation of paraffin wax melting in spherical cavity, Heat Mass Transf. 55 (5) (2019 May 1) 1427–1437. [83] Z. Gao, Y. Yao, H. Wu, A visualization study on the unconstrained melting of paraffin in spherical container, Appl. Therm. Eng. 155 (2019 Jun 5) 428–436. [84] T.G. Lago, K.A. Ismail, F.A. Lino, A Arabkoohsar, Experimental correlations for the solidification and fusion times of PCM encapsulated in spherical shells, Experimental Heat Transfer (2019 Aug 31) 1–15, https://doi.org/10.1080/ 08916152.2019.1656301. [85] A.L. London, R.A. Seban, Rate of ice formation, Trans. ASME 65 (7) (1943 Oct) 771–779. [86] L.C. Tao, Generalized numerical solutions of freezing a saturated liquid in cylin- ders and spheres, AIChE J. 13 (1) (1967 Jan 1) 165–169. [87] Y.P. Shih, T.C. Chou, Analytical solutions for freezing a saturated liquid inside or outside spheres, Chem. Eng. Sci. 26 (11) (1971 Nov 1) 1787–1793. [88] R.I. Pedroso, G.A. Domoto, Inward spherical solidification—solution by the method of strained coordinates, Int. J. Heat Mass Transf. 16 (5) (1973 May 1) 1037–1043. [89] R.I. Pedroso, G.A. Domoto, Perturbation solutions for spherical solidification of saturated liquids, J. Heat Transf. 95 (1) (1973 Feb 1) 42–46. [90] D.S. Riley, F.T. Smith, G. Poots, The inward solidification of spheres and circular cylinders, Int. J. Heat Mass Transf. 17 (12) (1974 Dec 1) 1507–1516. [91] J. Kern, G.L. Wells, Simple analysis and working equations for the solidification of cylinders and spheres, Metall. Trans. B 8 (1) (1977 Mar 1) 99–105. [92] J.M. Hill, A. Kucera, Freezing a saturated liquid inside a sphere, Int. J. Heat Mass Transf. 26 (11) (1983 Nov 1) 1631–1637. [93] L.F. Milanez, K.A. Ismail, Solidification in spheres, theoretical and experimental investigation, Multi-Phase 3rd International Conference on Multi-Phase and Heat Transfer, Miami, 1984. [94] J. Caldwell, C.C. Chan, Spherical solidification by the enthalpy method and the heat balance integral method, Appl. Math. Modell. 24 (1) (2000 Jan 1) 45–53. [95] K.A. Ismail, J.R. Henrıquez, Solidification of PCM inside a spherical capsule, Energy Convers. Manage. 41 (2) (2000 Jan 1) 173–187. [96] K.A. Ismail, J.R. Henriquez, T.M. Da Silva, A parametric study on ice formation inside a spherical capsule, Int. J. Therm. Sci. 42 (9) (2003 Sep 1) 881–887. 37PDF Image | Journal of Energy Storage 27
PDF Search Title:
Journal of Energy Storage 27Original File Name Searched:
tes-spherical-ball-storage-paraffin.pdfDIY PDF Search: Google It | Yahoo | Bing
Turbine and System Plans CAD CAM: Special for this month, any plans are $10,000 for complete Cad/Cam blueprints. License is for one build. Try before you buy a production license. More Info
Waste Heat Power Technology: Organic Rankine Cycle uses waste heat to make electricity, shaft horsepower and cooling. More Info
All Turbine and System Products: Infinity Turbine ORD systems, turbine generator sets, build plans and more to use your waste heat from 30C to 100C. More Info
CO2 Phase Change Demonstrator: CO2 goes supercritical at 30 C. This is a experimental platform which you can use to demonstrate phase change with low heat. Includes integration area for small CO2 turbine, static generator, and more. This can also be used for a GTL Gas to Liquids experimental platform. More Info
Introducing the Infinity Turbine Products Infinity Turbine develops and builds systems for making power from waste heat. It also is working on innovative strategies for storing, making, and deploying energy. More Info
Need Strategy? Use our Consulting and analyst services Infinity Turbine LLC is pleased to announce its consulting and analyst services. We have worked in the renewable energy industry as a researcher, developing sales and markets, along with may inventions and innovations. More Info
Made in USA with Global Energy Millennial Web Engine These pages were made with the Global Energy Web PDF Engine using Filemaker (Claris) software.
Sand Battery Sand and Paraffin for TES Thermo Energy Storage More Info
| CONTACT TEL: 608-238-6001 Email: greg@infinityturbine.com | RSS | AMP |