Experimental investigation of PCM thermal energy storage charge and discharge process with aperiodic (ramp) temperature inputs

Jarosław Karwacki; Roman Kwidziński

doi:10.1051/e3sconf/20187003005

All issues

Volume 70 (2018)

E3S Web Conf., 70 (2018) 03005

References

Open Access

Issue		E3S Web Conf. Volume 70, 2018 17^th International Conference Heat Transfer and Renewable Sources of Energy (HTRSE-2018)


Article Number		03005
Number of page(s)		8
Section		Chosen Energetical Problems
DOI		https://doi.org/10.1051/e3sconf/20187003005
Published online		03 December 2018

Y. Sun, S. Wang, F. Xiao, D. Gao, Peak load shifting control using different cold thermal energy storage facilities in commercial buildings: A review. Energy Conversion and Management 71(2013), 102–114 [Google Scholar]
J. Karwacki, R. Kwidziński, A. Tomaszewski, A. Cenian, J. Großman, S. Matthes, M. Lackowski, Usage of PCM thermal energy storage in the temperature stabilizaton system of bioreactor for algae cultivation [in Polish]. Proc. XLIX Dni Chłodnictwa (2017), 107–125 [Google Scholar]
J. Karwacki, R. Kwidziński, Theoretical analysis of a latent thermal energy storage system with an adsorption chiller. Polska Energetyka Słoneczna, No 1-4/2016, 59–64 [Google Scholar]
J. Bony, S. Citherlet, Numerical model and experimental validation of heat storage with phase change material. Energy and Buildings 39(2007), 1065–1072 [CrossRef] [Google Scholar]
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L.F. Cabeza, C. Barreneche, I. Martorell, L. Miró, S. Seri-Bey, M. Fois, H.O. Paksoy, N. Sahan, R. Weber, M. Constantinescu, E.M. Anghel, M. Malikowa, I. Krupa, M. Delgado, P. Dolado, P. Furmanski, M. Jaworski, T. Haussmann, S. Gschwander, A.I. Fernández, Unconventional experimental technologies available for phase change materials (PCM) characterisation. Part 1. Thermophysics properties. Renewable and Sustainable Energy Reviews 43(2015), 1399–1414 [CrossRef] [Google Scholar]
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M. Medrano, M.O. Yilmaz, M. Nogués, I. Martorell, J. Roce, L.F. Cabeza, Experimental evaluation of commercial heat exchangers for use as PCM thermal storage systems. Applied Energy 86(2009), 2047–2055 [CrossRef] [Google Scholar]
A. Gil, E. Oró, L. Miró, G. Peiró, A. Ruiz, J.M. Salmerón, L.F. Cabeza, Experimental analysis of hydroquinone used as phase change material (PCM) to be applied in solar cooling refrigeration. International Journal of Refrigeration 39(2014), 95–103 [CrossRef] [Google Scholar]
M. Grozdek, B. Halasz, T. Ćurko, V. Soldo, Experimental investigation of an ice-bank system performance. 3rd IIR Conference on Thermophysical Properties and Transfer Processes of Refrigeration, (2009) [Google Scholar]
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[1] Y. Sun, S. Wang, F. Xiao, D. Gao, Peak load shifting control using different cold thermal energy storage facilities in commercial buildings: A review. Energy Conversion and Management 71(2013), 102–114 [Google Scholar]

[2] J. Karwacki, R. Kwidziński, A. Tomaszewski, A. Cenian, J. Großman, S. Matthes, M. Lackowski, Usage of PCM thermal energy storage in the temperature stabilizaton system of bioreactor for algae cultivation [in Polish]. Proc. XLIX Dni Chłodnictwa (2017), 107–125 [Google Scholar]

[3] J. Karwacki, R. Kwidziński, Theoretical analysis of a latent thermal energy storage system with an adsorption chiller. Polska Energetyka Słoneczna, No 1-4/2016, 59–64 [Google Scholar]

[4] J. Bony, S. Citherlet, Numerical model and experimental validation of heat storage with phase change material. Energy and Buildings 39(2007), 1065–1072 [CrossRef] [Google Scholar]

[5] R. Isermann, M. Münchhof, Identification of Dynamic Systems. An Introduction with Applications (Springer, Berlin, 2011) [Google Scholar]

[6] L.F. Cabeza, C. Barreneche, I. Martorell, L. Miró, S. Seri-Bey, M. Fois, H.O. Paksoy, N. Sahan, R. Weber, M. Constantinescu, E.M. Anghel, M. Malikowa, I. Krupa, M. Delgado, P. Dolado, P. Furmanski, M. Jaworski, T. Haussmann, S. Gschwander, A.I. Fernández, Unconventional experimental technologies available for phase change materials (PCM) characterisation. Part 1. Thermophysics properties. Renewable and Sustainable Energy Reviews 43(2015), 1399–1414 [CrossRef] [Google Scholar]

[7] T. Nuytten, P. Moreno, D. Vanhoudt, L. Jespers, A. Solé, L.F. Cabeza, Comparative analysis of latent thermal energy storage tanks for micro-CHP systems. Applied Thermal Engineering 59(2013), 542–549 [CrossRef] [Google Scholar]

[8] M. Medrano, M.O. Yilmaz, M. Nogués, I. Martorell, J. Roce, L.F. Cabeza, Experimental evaluation of commercial heat exchangers for use as PCM thermal storage systems. Applied Energy 86(2009), 2047–2055 [CrossRef] [Google Scholar]

[9] A. Gil, E. Oró, L. Miró, G. Peiró, A. Ruiz, J.M. Salmerón, L.F. Cabeza, Experimental analysis of hydroquinone used as phase change material (PCM) to be applied in solar cooling refrigeration. International Journal of Refrigeration 39(2014), 95–103 [CrossRef] [Google Scholar]

[10] M. Grozdek, B. Halasz, T. Ćurko, V. Soldo, Experimental investigation of an ice-bank system performance. 3rd IIR Conference on Thermophysical Properties and Transfer Processes of Refrigeration, (2009) [Google Scholar]

[11] H.D. Baehr, K. Stephan, Heat and Mass Transfer (Springer, Berlin, 2006) [CrossRef] [Google Scholar]