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Erschienen in:
Reliability Importance Measures of Components for Stand-Alone Hybrid Renewable Energy Microgrid Kapitel lesen Erstes Kapitel lesen

2015 | OriginalPaper | Buchkapitel

Analysis of Electricity Usage for Domestic Heating Based on an Air-to-Water Heat Pump in a Real World Context

verfasst von : Seyed Amin Tabatabaei, Jan Treur

Erschienen in: 2nd International Congress on Energy Efficiency and Energy Related Materials (ENEFM2014)

Verlag: Springer International Publishing

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Abstract

In this paper a new computational model to estimate the performance of an air to water heat pump in relation to outdoor temperature is proposed and evaluated. This model is an extension and refinement of a model proposed in previous work. In the new model the following has been taken into account. Real empirical data for usage of a heat pump over a whole heating season have been used to obtain accurate parameter values. The energy which is used for heating sanitation water for the bathroom is taken into account in a separate submodel. According to some reports, around 15 % of domestic energy usage is for hot water. From the empirical data set, the fraction of energy which is consumed for this purpose is known, and it is used to model the usage for sanitation water heating as separate from the usage for heating. In this model the amount of energy which is used to keep the system working (active standby mode) is taken into account as well. The now available empirical data for the whole heating season have been used to estimate the parameter values for this model on the one hand and validation on the other hand.

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Vorheriges Kapitel Computational Screening of Dual Cation Metal Ammine Borohydrides
Nächstes Kapitel The Method of Determining Certain Parameters of Energy Absorption in Materials Under Complex Dynamic Excitations
Literatur
1.
B. Sanner, R. Kalf, A. Land, K. Mutka, P. Papillon, G. Stryi-Hipp, W. Weiss, 2020-2030-2050, Common Vision for the Renewable Heating and Cooling Sector in Europe (Publications Office of the European Union, Luxembourg, 2011)
2.
N. Aste, R.S. Adhikari, M. Manfren, Cost optimal analysis of heat pump technology adoption in residential reference buildings. Renew. Energy 60, 615–624 (2013)CrossRef
3.
R. Charron, A.K. Athienitis, Design and optimization of net-zero energy solar homes. ASHRAE Trans. 112(2), 285–295 (2006)
4.
R. Charron, A. Athienitis, in The use of genetic algorithms for a net-zero energy solar home design optimization tool. Proceedings of 23nd Conference on Passive and Low Energy Architecture (2006)
5.
M. Leckner, R. Zmeureanu, Life cycle cost and energy analysis of a net zero energy house with solar combisystem. Appl. Energy 88, 232–241 (2011)CrossRef
6.
S. Pogharian, J. Ayoub, J. A. Candanedo, A. K. Athienitis, in Getting to a net zero energy lifestyle in canada: the Alstonvale net zero energy house. Proceeding of the 3rd European PV Solar Energy Conference, pp. 3305–3311 (2008)
7.
E. Musall, T. Weiss, A. Lenoir, K. Voss, F. Garde, M. Donn, in Net zero energy solar buildings: an overview and analysis on worldwide building projects. Proceeding of EuroSun Conference (2010)
8.
J. Marszal, P. Heiselberg, J.S. Bourrelle, E. Musall, K. Voss, I. Sartori, A. Napolitano, Zero energy building—a review of definitions and calculation methodologies. Energy Build. 43, 971–979 (2011)CrossRef
9.
I. Sartori, A. Napolitano, K. Voss, Net zero energy buildings: a consistent definition framework. Energy Build. 48, 220–232 (2012)CrossRef
10.
S.A. Tabatabaei, D.J. Thilakarathne, J. Treur, in Agent-based analysis of annual energy usages for domestic heating based on a heat pump. Proceedings of the International Conference on ICT for Sustainability, ICT4S’14. Atlantis Press (2014)
11.
I. Staffell, D. Brett, N. Brandonc, A. Hawkesd, A review of domestic heat pumps. Energy Environ. Sci. 5, 9291–9306 (2012)CrossRef
12.
C. Maatouk, A. Zoughaib, D. Clodic, in New methodology of characterization of seasonal performance factor of an air-to-water heat pump. International Refrigeration and Air Conditioning Conference (2010)
13.
S.A. Tabatabaei, D.J. Thilakarathne, J. Treur, in An analytical model for mathematical analysis of smart daily energy management for air to water heat pumps. Proceedings of the International Conference on Technologies and Materials for Renewable Energy, Environment and Sustainability, TMREES’14. Energy Procedia, Elsevier (2014)
14.
A. Omar, S. Bo, Cold climates heat pump design optimization. ASHRAE Trans. 118(1), 34–41 (2012)
15.
J. Treur, in On the use of agent-based simulation for efficiency analysis of domestic heating using photovoltaic solar energy production combined with a heatpump. Proceedings of the International Conference on Energy Efficiency and Energy-Related Materials, ENEFM’13. Springer Proceedings in Physics, vol. 155 (2014)
16.
J. Treur, in A computational analysis of smart timing decisions for heating based on an air-to-water heatpump. Proceedings of the European Conference on Smart Energy Research at the Crossroads of Engineering, Economics and Computer Science, SmartER Europe 2014, E-World Energy and Water (2014)
17.
T.F. Coleman, Y. Li, An interior, trust region approach for nonlinear minimization subject to bounds. SIAM J. Optim. 6, 418–445 (1996)MATHMathSciNetCrossRef
18.
T.F. Coleman, Y. Li, On the convergence of reflective newton methods for large-scale nonlinear minimization subject to bounds. Math. Program. 67(2), 189–224 (1994)MATHMathSciNetCrossRef
Metadaten
Titel
Analysis of Electricity Usage for Domestic Heating Based on an Air-to-Water Heat Pump in a Real World Context
verfasst von
Seyed Amin Tabatabaei
Jan Treur
Copyright-Jahr
2015
Buch
2nd International Congress on Energy Efficiency and Energy Related Materials (ENEFM2014)

Print ISBN: 978-3-319-16900-2

Electronic ISBN: 978-3-319-16901-9

Copyright-Jahr: 2015

DOI
https://doi.org/10.1007/978-3-319-16901-9_72