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The Use of Phase Change Materials to Improve the External Walls' Thermal Parameters of Heated Buildings

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Currently, it is estimated that the construction sector consumes over 40% of the energy produced and about 50% of the mass of processed materials. As a consequence, there is a challenge to look for alternative material solutions allowing for the storage and conversion of energy. Phase change materials give us such opportunities. Their introduction leads to additional benefits related to thermal parameters. The work presents a short overview of PCMs along with the possibility of their application. Then, as part of the research, the selected phase change material was applied to the internal plaster layer of an external wall to check its activity. The obtained results were compared to the values of reference samples (without PCM). The proposed solution leads to the improvement of the analyzed partitions' thermal parameters.
Rocznik
Strony
63--72
Opis fizyczny
Bibliogr. 35 poz., il., tab.
Twórcy
  • University of Science and Technology, Faculty of Civil and Environmental Engineering and Architecture, Bydgoszcz, Poland
  • University of Science and Technology, Faculty of Civil and Environmental Engineering and Architecture, Bydgoszcz, Poland
Bibliografia
  • 1. Kumar, D, Alam, M, Zou, PXW, Sanjayan, JG and Memon, RA 2020. Comparative Analysis of Building Insulation Material Properties and Performance. Renewable and Sustainable Energy Reviews 131, 110038.
  • 2. Garbaliska, H and Bochenek, M 2012. [Methods of incorporating phase change materials into wall elements] Materiały Budowlane 2, 36-38.
  • 3. Delgado J M P Q, Martinho, JC, Vaz Sá A, Guimarães, AS and Abrantes, V 2019. Thermal Energy Storage with Phase Change Materials: Literature Review of Applications for Buildings Materials; Springer Briefs in Applied Sciences and Technology; Springer International, Publishing: Cham, Switzerland; ISBN 978-3-319-97498-9.
  • 4. Sivanathan, A, Dou, Q, Wang Y, Li Y, Corker, J, Zhou, Y and Fan, M 2020. Phase Change Materials for Building Construction: An Overview of Nano-/Micro-Encapsulation. Nanotechnol. Rev. 9, 896-921.
  • 5. Kulkarni, P and Muthadhi, A 2021. Thermal Energy Storage Cement Mortar with Direct Incorporation of Organic and Inorganic Phase Change Materials. Innovative Infrastructure Solutions 6, 30.
  • 6. Witthohn, M and Klemm, R 2007. Verfahren zur Erhöhung der Wärmespeicherkapazität von Bausteinen aus einem Kalzium-Silikat Material sowie Baustein aus einem Kalzium Silikat-Material. Patent description EP 1752509 A1 (14.02.2007).
  • 7. Zhang YP, Lin K. P, Yang R, Di H F and Jiang, Y 2006. Preparation, thermal performance and application of shape-stabilized PCM in energy efficient buildings. Energy and Buildings 38, 1262-1269.
  • 8. Jeong S-G, Wi S, Chang SJ, Lee, J and Kim, S 2019. An Experimental Study on Applying Organic PCMs to Gypsum-Cement Board for Improving Thermal Performance of Buildings in Different Climates. Energy and Buildings 190, 183-194.
  • 9. Nakielska, M and Kaczmarek, A 2022. Impact of the phase-change material additive on the thermal parameters improvement of the primer for external plaster, Materiały Budowlane 11 (603) ISSN 0137-2971, e-ISSN 2449-951X.
  • 10. Ben Romdhane, S, Amamou, A, Ben Khalifa, R, Saïd, NM, Younsi, Z and Jemni, A 2020. A Review on Thermal Energy Storage Using, Phase Change Materials in Passive Building Applications. Journal of Building Engineering 32, 101563.
  • 11. Belén Zalba, José M Marín, Luisa F Cabeza and Harald Mehling 2003. Review on thermal energy storage with phase change: materials, heat transfer analysis and applications. Applied Thermal Engineering 23, 251-283.
  • 12. Baetensa, R, Jelle, BP and Gustavsend, A 2010. Phase change materials for building applications: A state-of-the-art review. Energy and Buildings 42, 1361-1368.
  • 13. Soares, N, Costa, JJ, Gaspar, AR and Santosa, P 2013. Review of passive PCM latent heat thermal energy storage systems towards buildings’ energy efficiency. Energy and Buildings 59, 82-103.
  • 14. Karthik Muruganantham 2010. Application of Phase Change Material in Buildings: Field Data vs. Energy Plus Simulation.
  • 15. Cunha, S, Leite, P and Aguiar, J 2020. Characterization of Innovative Mortars with Direct Incorporation of Phase Change Materials. Journal of Energy Storage 30, 101439.
  • 16. Lamrani, B, Johannes, K and Kuznik, F 2021. Phase Change Materials Integrated into Building Walls: An Updated Review. Renewable and Sustainable Energy Reviews 140, 110751.
  • 17. Wcisło-Kucharek, P, Ryms, M, Klugmann-Radziemska, E and Denda, H 2017. [Phase change materials used in construction to ensure thermal comfort in rooms]. Ciepłownictwo Ogrzewnictwo Wentylacja 48/5, 196-201.
  • 18. Al-Yasiri, Q and Szabó, M 2021. Incorporation of Phase Change Materials into Building Envelope for Thermal Comfort and Energy Saving: A Comprehensive Analysis. Journal of Building Engineering 36, 102122.
  • 19. Kabrońska, J 2010. [Construction technologies in the process of improving the energy quality of Buildings]. Czasopismo Techniczne Architektura 18, 147-153.
  • 20. Muthuvel, S, Saravanasankar, S, Sudhakarapandianc, R and Muthukannan, M 2015. Passive cooling by phase change material usage in construction. Building Services Engineering Research & Technology 36/4, 411-421.
  • 21. Bake, M, Shukla, A and Liu, S 2021. Development of Gypsum Plasterboard Embodied with Microencapsulated Phase Change Material for Energy Efficient Buildings. Materials Science for Energy Technologies 4, 166-176.
  • 22. Melcer, A, Klugmann-Radziemska, E and Lewandowski, WM 2012. [Phase change materials. Properties, classification, advantages and disadvantages]. Przemysł Chemiczny 7, 1000-1011.
  • 23. Chwieduk, D 2010. [Demand for heat and cold in attic rooms]. Technical Transactions Civil Engineering 4, 41-48.
  • 24. Li C, Yu H and Song, Y 2019. Experimental Investigation of Thermal Performance of Microencapsulated PCM-Contained Wallboard by Two Measurement Modes. Energy and Buildings 184, 34-43.
  • 25. Kabrońska, J 2010. Building technologies in the process of improvement of buildings. energy performance. Czasopismo Techniczne Architektura 18, 147-153.
  • 26. Pasupathy, A and Velraj, R 2008. Effect of double layer phase change material in building roof for year round thermal management. Energy and Buildings 40/3, 193-203.
  • 27. Hawes, DW, Banu, D and Feldman, D 1992. The stability of phase change materials in concreto. Solar Energy Materials and Solar Cells 27/2, 103-118.
  • 28. PN-EN 1015-18:2003 [Test methods for masonry mortars - Part 18: Determination of the water absorption coefficient caused by capillary action of hardened mortar].
  • 29. PN-EN 1015-10:2001 [Test methods for masonry mortars - Part 10: Determination of the density of dried hardened mortar].
  • 30. PN-EN 196-1:2016-07 [Cement testing methods - Part 1: Determination of strength]
  • 31. EN ISO 13786 Thermal performance of building components - Dynamic thermal characteristics - Calculation methods.
  • 32. PN-EN 12667:2002 [Thermal properties of construction materials and products - Determination of thermal resistance using the methods of a covered heating plate and a heat flux sensor - Products with high and medium thermal resistance]
  • 33. Nowak, K, Kisielewicz, T, Berardi, U and Zastawna-Rumin, A 2023. Thermal performance evaluation of a PCM-integrated gypsum plaster board, 10th MATBUD’2023 Scientific Technical Conference: Building Materials Engineering and Innovative Sustainable Materials, 317-324.
  • 34. Baetens, R, Jelle, BP and Gustavsen, A 2010. Phase change materials for building applications: A state-of-the-art review. Energy and Buildings 42, 1361-1368.
  • 35. Kośny, J 2015. PCM- Enhanced Building Components: An application of Phase Change Materials in Building Envelopes and Internal Structures; Springer International Publishing: Cham, Switzerland. [CrossRef].
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9b1c7de6-a713-4aba-9d62-fda0bcd0918b
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