AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Building Simulation Article
Article Link
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Research Article

Hysteresis effects on the thermal performance of building envelope PCM-walls

Efraín Moreles1( )Guadalupe Huelsz2Guillermo Barrios2
Programa de Doctorado en Ingeniería, Universidad Nacional Autónoma de México, Instituto de Energías Renovables, 62580, Temixco, Morelos, Mexico
Instituto de Energías Renovables,Universidad Nacional Autónoma de México, 62580, Temixco, Morelos, Mexico
Show Author Information

Abstract

This work presents a numerical study of the combined effects of the hysteresis temperature difference, peak melting temperature, and thickness of a building envelope PCM-wall on its thermal performance in air-conditioning and non-air-conditioning conditions. The study was carried out considering complete melting-freezing daily cycles of the PCM in a climate exhibiting both hot and cold thermal discomfort. A time-dependent one-dimensional heat conduction code, which uses the effective specific heat method to simulate the heat transfer through the PCM was developed. Insights into the effects of the hysteresis phenomenon were obtained; it was found that hysteresis improves the thermal performance of PCM-walls. The higher the hysteresis temperature difference the better the thermal performance, but there is a limit in the improvement of the thermal performance, which is achieved when the entire phase change process takes place at temperatures outside of the thermal comfort zone. Maximum improvements from 4% to 29% for air-conditioning and from 4% to 30% for non-air-conditioning, for a BioPCM wall with thicknesses from 6 mm to 18 mm, were found. Suggested criteria to achieve the maximum possible thermal performance of PCM-walls given a thickness and use condition were obtained. This work proposes the basis of a methodology to optimize simultaneously any pair of variables of a PCM-wall for different use conditions (AC, nAC, or a combined use of AC and nAC).

Keywords

optimizationhysteresisthermal performancetime-dependentPCM-wall

Electronic Supplementary Material

Download File(s)
12273_2017_426_MOESM1_ESM.pdf (967.7 KB)

References

 
H Akeiber, P Nejat, MZA Majid, MA Wahid, F Jomehzadeh, IZ Famileh, JK Calautit, BR Hughes, SA Zaki (2016). A review on phase change material (PCM) for sustainable passive cooling in building envelopes. Renewable and Sustainable Energy Reviews, 60: 1470–1497.
Crossref Google Scholar
 
SN AL-Saadi, ZJ Zhai (2013). Modeling phase change materials embedded in building enclosure: A review. Renewable and Sustainable Energy Reviews, 21: 659–673.
Crossref Google Scholar
 
F Ascione, N Bianco, RF de Masi, F de Rossi, GP Vanoli (2014). Energy refurbishment of existing buildings through the use of phase change materials: Energy savings and indoor comfort in the cooling season. Applied Energy, 113: 990–1007.
Crossref Google Scholar
 
ASHRAE (2005). ASHRAE Handbook: Fundamentals. Atlanta, GA, USA: American Society of Heating, Refrigerating and Air- Conditioning Engineers.
 
G Barrios, G Huelsz, J Rojas, JM Ochoa, I Marincic (2012). Envelope wall/roof thermal performance parameters for non air-conditioned buildings. Energy and Buildings, 50: 120–127.
Crossref Google Scholar
 
G Barrios, JM Casas, G Huelsz, J Rojas (2016). Ener-Habitat: An online numerical tool to evaluate the thermal performance of homogeneous and non-homogeneous envelope walls/roofs. Solar Energy, 131: 296–304.
Crossref Google Scholar
 
J Belaunzarán-Zamudio (2015). Estudios de un sistema constructivo con cambio de fase. Master’s Thesis, Universidad Nacional Autónoma de México, Instituto de Energías Renovables, Mexico.
 
BioPCM. Phase Change Energy Solutions. www.phasechange.com and by personal communication.
Crossref
 
J Bony, S Citherlet (2007). Numerical model and experimental validation of heat storage with phase change materials. Energy and Buildings, 39: 1065–1072.
Crossref Google Scholar
 
R Chandrasekharan, ES Lee, DE Fisher, PS Deokar (2013). An enhanced simulation model for building envelopes with phase change materials. ASHRAE Transactions, 119(2): 1–10.
Crossref Google Scholar
 
C Chen, H Guo, Y Liu, H Yue, C Wang (2008). A new kind of phase change material (PCM) for energy-storing wallboard. Energy and Buildings, 40: 882–890.
Crossref Google Scholar
 
DHC Chow, GJ Levermore (2007). New algorithm for generating hourly temperature values using daily maximum, minimum and average values from climate models. Building Services Engineering Research and Technology, 28: 237–248.
Crossref Google Scholar
 
B Delcroix, M Kummert, A Daoud (2015a). Thermal behavior mapping of a phase change material between the heating and cooling enthalpy-temperature curves. Energy Procedia, 78: 225–230.
Crossref Google Scholar
 
B Delcroix, M Kummert, A Daoud, J Bouchard (2015b). Influence of experimental conditions on measured thermal properties used to model phase change materials. Building Simulation, 8: 637–650.
Crossref Google Scholar
 
J Dulac, M LaFrance, N Trudeau, H Yamada (2013). Transition to sustainable buildings: Strategies and opportunities to 2050. Technical Report, International Energy Agency Directorate of Sustainable Energy Policy and Technology (SPT).
Crossref
 
EnergyPlus. EnergyPlus Energy Simulation Software. U.S. Department of Energy. Available at https://energyplus.net.
Crossref
 
EnerHabitat. Ener-Habitat Evaluación térmica de la envolvente arquitectónica. Available at http://www.enerhabitat.unam.mx/Cie2.
Crossref
 
BL Gowreesunker, SA Tassou, M Kolokotroni (2012). Improved simulation of phase change processes in applications where conduction is the dominant heat transfer mode. Energy and Buildings, 47: 353–359.
Crossref Google Scholar
 
BL Gowreesunker, SA Tassou (2013). Effectiveness of CFD simulation for the performance prediction of phase change building boards in the thermal environment control of indoor spaces. Building and Environment, 59: 612–625.
Crossref Google Scholar
 
C Halford, R Boehm (2007). Modeling of phase change material peak load shifting. Energy and Buildings, 39: 298–305.
Crossref Google Scholar
 
D Heim, JA Clarke (2004). Numerical modelling and thermal simulation of PCM-gypsum composites with ESP-r. Energy and Buildings, 36: 795–805.
Crossref Google Scholar
 
MA Humphreys, JF Nicol (2000). Outdoor temperature and indoor thermal comfort-raising the precision of the relationship for the 1998 ASHRAE database fields studies. ASHRAE Transactions, 106(2): 485–492.
Crossref Google Scholar
 
F Jiang, X Wang, Y Zhang (2011). A new method to estimate optimal phase change material characteristics in a passive solar room. Energy Conversion and Management, 52: 2437–2441.
Crossref Google Scholar
 
X Jin, MA Medina, X Zhang (2013). On the importance of the location of PCMs in building walls for enhanced thermal performance. Applied Energy, 106: 72–78.
Crossref Google Scholar
 
J Kośny (2015). PCM-Enhanced Building Components—An Application of Phase Change Materials in Building Envelopes and Internal Structures. Cham, Switzerland: Springer International Publishing.
Crossref
 
F Kuznik, J Virgone (2009). Experimental investigation of wallboard containing phase change material: Data for validation of numerical modeling. Energy and Buildings, 41: 561–570.
Crossref Google Scholar
 
KO Lee, MA Medina, E Raith, X Sun (2015). Assessing the integration of a thin phase change material (PCM) layer in a residential building wall for heat transfer reduction and management. Applied Energy, 137: 699–706.
Crossref Google Scholar
 
J Lei, J Yang, E-H Yang (2016). Energy performance of building envelopes integrated with phase change materials for cooling load reduction in tropical Singapore. Applied Energy, 162: 207–217.
Google Scholar
 
Meteonorm. Irradiation data for every place on Earth. Available at http://meteonorm.com.
 
E Moreles, G Huelsz (2015a). Hysteresis effect on the thermal performance of lightweight walls of the building envelope with phase change materials. In: Poster session at the 3rd International Symposium on Renewable Energy and Sustainability (ISRES), Morelos, Mexico.
 
E Moreles, G Huelsz (2015b). Thermal performance of lightweight walls with phase change materials. In: Proceedings of the 10th Conference on Advanced Building Skins, Bern, Switzerland.
Crossref
 
E Moreles (2017). Thermal performance evaluation of constructive systems with phase change materials. PhD Thesis, Universidad Nacional Autónoma de México, Mexico.
Crossref
 
K Morgan, RW Lewis, OC Zienkiewicz (1978). An improved algorithm for heat conduction problems with phase change. International Journal for Numerical Methods in Engineering, 12: 1191–1195.
Crossref Google Scholar
 
D Morillón-Gálvez, R Saldaña-Flores, A Tejeda-Martínez (2004). Human bioclimatic atlas for Mexico. Solar Energy, 76: 781–792.
Crossref Google Scholar
 
K Muruganantham (2010). Application of phase change material in buildings: Field data vs. EnergyPlus simulation. Master Thesis, Arizona State University, USA.
Crossref
 
DA Neeper (2000). Thermal dynamics of wallboard with latent heat storage. Solar Energy, 68: 393–403.
Crossref Google Scholar
 
SV Patankar (1980). Numerical Heat Transfer and Fluid Flow. Washington DC: Taylor and Francis.
Crossref
 
K Peippo, P Kauranen, P Lund (1991). A multicomponent PCM wall optimized for passive solar heating. Energy and Buildings, 17: 259–270.
Crossref Google Scholar
 
S Ramakrishnan, X Wang, J Sanjayan, J Wilson (2017). Thermal performance of buildings integrated with phase change materials to reduce heat stress risks during extreme heatwave events. Applied Energy, 194: 410–421.
Crossref Google Scholar
 
JS Sage-Lauck, DJ Sailor (2014). Evaluation of phase change materials for improving thermal comfort in a super-insulated residential building. Energy and Buildings, 79: 32–40.
Google Scholar
 
AA Samarskii, PN Vabishchevich (1995). Computational Heat Transfer—Mathematical Modelling. Chichester, UK: John Wiley & Sons.
 
SENER (2011). SENER Norma oficial Mexicana NOM-020-ENER-2011 para eficiencia energética en edificaciones - Envolvente de edificios para uso habitacional. Diario Oficial de la Federación, 44-89.
Crossref
 
N Soares, AR Gaspar, P Santos, JJ Costa (2014). Multi-dimensional optimization of the incorporation of PCM-drywalls in lightweight steel-framed residential buildings in different climates. Energy and Buildings, 70: 411–421.
Crossref Google Scholar
 
N Soares, CF Reinhart, A Hajiah (2017). Simulation-based analysis of the use of PCM-wallboards to reduce cooling energy demand and peak-loads in low-rise residential heavyweight buildings in Kuwait. Building Simulation, 10: 481–495.
Crossref Google Scholar
 
U Stritih, P Novak (1996). Solar heat storage wall for building ventilation. Renewable Energy, 8: 268–271.
Crossref Google Scholar
 
G Zhou, Y Zhang, X Wang, K Lin, W Xiao (2007). An assessment of mixed type PCM-gypsum and shape-stabilized PCM plates in a building for passive solar heating. Solar Energy, 81: 1351–1360.
Google Scholar
Building Simulation
Volume 11 Issue 3,
June 2018
Pages 519-531
DOI: 10.1007/s12273-017-0426-4
Cite this article:
Moreles E, Huelsz G, Barrios G. Hysteresis effects on the thermal performance of building envelope PCM-walls. Building Simulation, 2018, 11(3): 519-531. https://doi.org/10.1007/s12273-017-0426-4

605

Views

34

Crossref

N/A

Web of Science

34

Scopus

2

CSCD

Altmetrics
Received: 02 June 2017
Revised: 19 November 2017
Accepted: 13 December 2017
Published: 02 January 2018
© Tsinghua University Press and Springer-Verlag GmbH Germany, part of Springer Nature 2018
Return