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APPLICATION OF PHASE CHANGE MATERIALS IN BUILDING STRUCTURES IN NORDIC CLIMATE

Post doc res. Mihkel Kiviste / Ralf Lindberg

First published: 2014-06-20https://doi.org/10.5593/sgem2014/b62/s26.007View metrics

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Publication details

Title
APPLICATION OF PHASE CHANGE MATERIALS IN BUILDING STRUCTURES IN NORDIC CLIMATE
Authors
Post doc res. Mihkel Kiviste / Ralf Lindberg
Proceedings
SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings; 14th SGEM GeoConference on NANO, BIO AND GREEN TECHNOLOGIES FOR A SUSTAINABLE FUTURE
Publisher
Stef92 Technology
Year
2014
Pages
Not available yet
ISSN
1314-2704
ISBN
978-619-7105-21-6
Language
en
Publication type
Conference Paper
References28
  1. Tekes tori website. PCM - Phase Changing Materials. (Source: Super Sustainable City), Tekes - the Finnish Funding Agency for Innovation. http://tekes.dicole.net/ blogs/show/482/0/14727/PCM_%2528Phase_Changing_Materials%2529_%2528Super _Sustainable_City%2529 . News added 02.08.2010 at 10:28, 2010.

  2. Minux website. http://www.minux.es/materiales-de-cambio-de-fase-pcm/ (San Juan de Ortega 16, 09007 Burgos, Spain, Phone 947 24 30 80, [email protected]), 2012.

  3. Farid, M. M.; Khudhair, A.M.; Razack, S.A.K.; Al-Hallaj, S. A review on phase change energy storage: materials and applications, Energy Conversion and Management, vol. 45, pp 1597–1615, 2004.

  4. Hasnain, S.M. Review on sustainable thermal energy storage technologies, Part I: heat storage materials and techniques. Energy Conversion and Management, vol. 39/issue 11, pp. 1127–1138, 1998.

  5. EPIC-HUB deliverable D1.1: Operational Scenarios Requirements. EPIC-HUB – Energy Positive Neighborhoods Infrastructure Middleware based on Energy-Hub concept. Collaborative project: FP7 NMP-ENV-ENERGY-ICT EeB. (http://www.epichub.eu/ documents/37010/37341 /D1.1+Operational+scenarios + requirements), 304 p., 2014.

  6. Lindberg R., Binamu A., Teikari M. Five-year data of measured weather, energy consumption, and time-dependent temperature variations within different exterior wall structures. Energy and Buildings, vol. 36, pp. 495-501, 2004. 14th SGEM GeoConference on Nano, Bio and Green – Technologies for a Sustainable Future

  7. Kiviste, M., Lindberg, R., Leivo, V. Improving the calculation of building energy consumption based on ten year measured data. In Malinovska, L., Osadcuks, V. (eds): Engineering for rural development. The 12th International Scientific Conference, vol. 12. Latvia University of Agriculture, Jelgava, pp. 451-455, 2013.

  8. Lindberg R., Keränen H., Teikari M. The influence of external wall structures to the energy consumption of a building. (Ulkoseinärakenteen vaikutus raken nuksen energiankulutuksen). Tampere University of Technology, p ublications 90, Tampere, 33 p. (in Finnish). 1998.

  9. Lindberg R., Korpi M., Vinha J. Factors affecting energy consumption of buildings. In: Building Enclosure Science and Technology. The BEST 1 conference, National Institute of Building Sciences, Canada, 8 p., 2008.

  10. Lindberg R., Leivo V. Building Energy Consumption and Thermal Performance of the Autoclaved Aerated Concrete (AAC) Exterior Walls, In: Limbachiya and Roberts (Eds.). Autoclaved Aerated Concrete. Taylor and Francis Group, London, pp. 519 -523, 2005.

  11. Lindberg, R.; Rantala, J.; Leivo, V.; Kiviste, M. Effect of massive outer leaf of an insulated cavity brick wall on heat loss. Journal of Building Physics, vol. 36/issue 2, pp. 198 – 211, 2012.

  12. Sharma, A.; Shukla, A.; Chen, C. R.; Dwivedi, S. Development of phase change materials for building applications. Energy and Buildings, vol. 64, pp. 403-407, 2013.

  13. Karaipekli, A.; Sari, A. Capric –myristic acid/expanded perlite composite as form- stable phase change material for latent heat thermal energy storage. Renewable Energy, vol. 33/issue 12, pp. 2599–2605, 2008.

  14. Masso, T. ABC of building physics (Ehitusfüüsika ABC), Ehitame publishing, Tallinn, 172 p. (in Estonian), 2012.

  15. Tekes tori website. PCM - Phase Changing Materials. (Source: Super Sustainable City), Tekes - the Finnish Funding Agency for Innovation. http://tekes.dicole.net/ blogs/show/482/0/14727/PCM_%2528Phase_Changing_Materials%2529_%2528Super _Sustainable_City%2529 . News added 02.08.2010 at 10:28, 2010.

  16. Minux website. http://www.minux.es/materiales-de-cambio-de-fase-pcm/ (San Juan de Ortega 16, 09007 Burgos, Spain, Phone 947 24 30 80, [email protected]), 2012.

  17. Farid, M. M.; Khudhair, A.M.; Razack, S.A.K.; Al-Hallaj, S. A review on phase change energy storage: materials and applications, Energy Conversion and Management, vol. 45, pp 1597–1615, 2004.

  18. Hasnain, S.M. Review on sustainable thermal energy storage technologies, Part I: heat storage materials and techniques. Energy Conversion and Management, vol. 39/issue 11, pp. 1127–1138, 1998.

  19. EPIC-HUB deliverable D1.1: Operational Scenarios Requirements. EPIC-HUB – Energy Positive Neighborhoods Infrastructure Middleware based on Energy-Hub concept. Collaborative project: FP7 NMP-ENV-ENERGY-ICT EeB. (http://www.epichub.eu/ documents/37010/37341 /D1.1+Operational+scenarios + requirements), 304 p., 2014.

  20. Lindberg R., Binamu A., Teikari M. Five-year data of measured weather, energy consumption, and time-dependent temperature variations within different exterior wall structures. Energy and Buildings, vol. 36, pp. 495-501, 2004. 14th SGEM GeoConference on Nano, Bio and Green – Technologies for a Sustainable Future

  21. Kiviste, M., Lindberg, R., Leivo, V. Improving the calculation of building energy consumption based on ten year measured data. In Malinovska, L., Osadcuks, V. (eds): Engineering for rural development. The 12th International Scientific Conference, vol. 12. Latvia University of Agriculture, Jelgava, pp. 451-455, 2013.

  22. Lindberg R., Keränen H., Teikari M. The influence of external wall structures to the energy consumption of a building. (Ulkoseinärakenteen vaikutus raken nuksen energiankulutuksen). Tampere University of Technology, p ublications 90, Tampere, 33 p. (in Finnish). 1998.

  23. Lindberg R., Korpi M., Vinha J. Factors affecting energy consumption of buildings. In: Building Enclosure Science and Technology. The BEST 1 conference, National Institute of Building Sciences, Canada, 8 p., 2008.

  24. Lindberg R., Leivo V. Building Energy Consumption and Thermal Performance of the Autoclaved Aerated Concrete (AAC) Exterior Walls, In: Limbachiya and Roberts (Eds.). Autoclaved Aerated Concrete. Taylor and Francis Group, London, pp. 519 -523, 2005.

  25. Lindberg, R.; Rantala, J.; Leivo, V.; Kiviste, M. Effect of massive outer leaf of an insulated cavity brick wall on heat loss. Journal of Building Physics, vol. 36/issue 2, pp. 198 – 211, 2012.

  26. Sharma, A.; Shukla, A.; Chen, C. R.; Dwivedi, S. Development of phase change materials for building applications. Energy and Buildings, vol. 64, pp. 403-407, 2013.

  27. Karaipekli, A.; Sari, A. Capric –myristic acid/expanded perlite composite as form- stable phase change material for latent heat thermal energy storage. Renewable Energy, vol. 33/issue 12, pp. 2599–2605, 2008.

  28. Masso, T. ABC of building physics (Ehitusfüüsika ABC), Ehitame publishing, Tallinn, 172 p. (in Estonian), 2012.

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