Article | Proceedings of the 10<sup>th</sup> International Modelica Conference; March 10-12; 2014; Lund; Sweden | BuildSysPro: a Modelica library for modelling buildings and energy systems Linköping University Electronic Press Conference Proceedings
Göm menyn

Title:
BuildSysPro: a Modelica library for modelling buildings and energy systems
Author:
Gilles Plessis: EnerBaT – EDF R&D, Site des Renardières, Moret sur Loing CEDEX, FRANCE Aurélie Kæmmerlen: EnerBaT – EDF R&D, Site des Renardières, Moret sur Loing CEDEX, FRANCE Amy Lindsay: EnerBaT – EDF R&D, Site des Renardières, Moret sur Loing CEDEX, FRANCE
DOI:
10.3384/ecp140961161
Download:
Full text (pdf)
Year:
2014
Conference:
Proceedings of the 10th International Modelica Conference; March 10-12; 2014; Lund; Sweden
Issue:
096
Article no.:
122
Pages:
1161-1169
No. of pages:
9
Publication type:
Abstract and Fulltext
Published:
2014-03-10
ISBN:
978-91-7519-380-9
Series:
Linköping Electronic Conference Proceedings
ISSN (print):
1650-3686
ISSN (online):
1650-3740
Publisher:
Linköping University Electronic Press; Linköpings universitet


Export in BibTex, RIS or text

This paper presents the BuildSysPro Modelica library developed by the department of Energy in Buildings and Territories (EnerBaT) of EDF R&D. After a description of the library’s structure and content; BESTEST validation results and a use case are presented.

This library is designed to be used in several contexts including building physics research; global performance evaluation; technology development and impact assessment. It is also a basis for urban and building stock simulation. BuildSysPro is intended for a relatively large audience ranging from R&D scientists to building services engineers.

BuildSysPro contains classes to describe the whole building and its energy systems including envelope components; HVAC systems and other energy conversion devices (DHW; thermal and photovoltaic panels…) and boundary conditions models. The models are designed for static and dynamic use; and for the representation of 0D/1D pure thermal and fluid dynamics. BuildSysPro in its current version contains around 380 models and 130 functions.

Keywords: Modelica library; Building; Dynamic simulation; Numerical validations; Energy system

Proceedings of the 10th International Modelica Conference; March 10-12; 2014; Lund; Sweden

Author:
Gilles Plessis, Aurélie Kæmmerlen, Amy Lindsay
Title:
BuildSysPro: a Modelica library for modelling buildings and energy systems
DOI:
http://dx.doi.org/10.3384/ecp140961161
References:

[1] Blervaque, H., Filfli, S., Stabat, P., Schumann, M., Marchio, D., Comparative Analysis of Air-To-Air Heat Pump Models for Building Energy Simulation. Proceedings of SimBuild 2012.

[2] Lindsay, A., Energetic Evaluation of an Active Cooling System for Building Integrated Photovoltaics. Proceedings of EU PVSEC 2013.

[3] Bontemps, S., Kaemmerlen, A., Blatman G., Mora L., Reliability Of Dynamic Simulation Models For Building Energy In The Context Of Low-energy Buildings. Proceedings of IBPSA 2013.

[4] Kim, E., Plessis, G., Roux, JJ., Hubert JL., Reduction Of Building Models For Use In Urban Energy Analysis. Proceedings of IBPSA 2013.

[5] Roujol S., building energy simulation software package uncertainty and validation, PhD Thesis, Mines ParisTech, 2003.

[6] Murphy, K.M. and Deque, F., An open ended modular interface and controller library for CLIM2000, International Building Performance Simulation Association, 1997.

[7] Judkoff R. and Neymark J., Model validation and testing: the methodological foundation of ASHRAE Standard 140, ASHRAE Transactions 112(2). Atlanta: GA: American Society of Heating, Refrigerating and Air-Conditioning Engineers, 2006. 367-37.

[8] Judkoff, R., Neymark, J., International Energy Agency Building Energy Simulation Test (IEA BESTEST) and Diagnostic Method, NREL/TP-472-6231. Golden, CO: NREL, 1995

[9] Yuan S. and O’Neill Z., Testing and validating an equation-based dynamic building program with ASHRAE standard method of test. In: Proceedings of the 3rd SimBuild Conference, Berkeley, USA, 2008.

[10] Videla, J. I. and Lie, B., A New Energy Building Simulation Library. Proceedings of Modelica 2006

[11] Wetter M., Zuo W., Nouidu T. S., Recent Developments of the Modelica Buildings Library for Building Energy and Control Systems, Proceedings of the 8th International Modelica Conference, 2011.

[12] Covalet D., Woloszyn M. et Greffier V., Apport des vitrages actifs pour le confort d’été, Proceedings IBPSA France, 2006

[13] Felgner F., Agustina S., Cladera Bohiga R., Merz R., Litz L., Simulation of Thermal Building behaviour in Modelica, Proceedings of the 2nd International Modelica Conference, 2002

[14] Filfli, S., Bouia, H., Simulation avec Modelica du fonctionnement d’une PAC dans un bâtiment BBC : impact d’un pas de temps infrahoraire. Proceedings of the CIFQ 2013.

Proceedings of the 10th International Modelica Conference; March 10-12; 2014; Lund; Sweden

Author:
Gilles Plessis, Aurélie Kæmmerlen, Amy Lindsay
Title:
BuildSysPro: a Modelica library for modelling buildings and energy systems
DOI:
https://doi.org10.3384/ecp140961161
Note: the following are taken directly from CrossRef
Citations:
  • Marwan Abugabbara, Saqib Javed, Hans Bagg & Dennis Johansson (2020). Bibliographic analysis of the recent advancements in modeling and co-simulating the fifth-generation district heating and cooling systems. Energy and Buildings, 224: 110260. DOI: 10.1016/j.enbuild.2020.110260
  • Nicolas Lauzet, Auline Rodler, Marjorie Musy, Marie-Hélène Azam, Sihem Guernouti, Dasaraden Maure & Thibaut Colinart (2019). How building energy models take the local climate into account in an urban context – A review. Renewable and Sustainable Energy Reviews, 116: 109390. DOI: 10.1016/j.rser.2019.109390
  • Alberto Tejeda De La Cruz, Philippe Riviere, Dominique Marchio, Odile Caure & Anamaria Milu (2017). Hardware in the loop test bench using Modelica: A platform to test and improve the control of heating systems. Applied Energy, 188: 107. DOI: 10.1016/j.apenergy.2016.11.092
  • Loïc Frayssinet, Frédéric Kuznik, Jean-Luc Hubert, Maya Millie & Jean-Jacques Roux (2017). Adaptation of building envelope models for energy simulation at district scale. Energy Procedia, 122: 307. DOI: 10.1016/j.egypro.2017.07.327
  • Sascha Lindig, David Moser, Alan J. Curran, Kunal Rath, Arash Khalilnejad, Roger H. French, Magnus Herz, Björn Müller, George Makrides, George Georghiou, Andreas Livera, Mauricio Richter, Julián Ascencio‐Vásquez, Mike Iseghem, Mohammed Meftah, Dirk Jordan, Chris Deline, Wilfried Sark, Joshua S. Stein, Marios Theristis, Bennet Meyers, Franz Baumgartne & Wei Luo (2021). International collaboration framework for the calculation of performance loss rates: Data quality, benchmarks, and trends (towards a uniform methodology). Progress in Photovoltaics: Research and Applications, : . DOI: 10.1002/pip.3397
  • Lucie Merlier, Loïc Frayssinet, Kévyn Johanne & Frédéric Kuznik (2019). On the impact of local microclimate on building performance simulation. Part I: Prediction of building external conditions. Building Simulation, 12(5): 735. DOI: 10.1007/s12273-019-0507-7
  • Clément Ribault, Mathias Bouquerel, Adrien Brun, Mathieu Schumannb, Gilles Rusaouë & Etienne Wurtz (2017). Assessing tools relevance for energy simulation at the urban scale: towards decision-support tools for urban design and densification. Energy Procedia, 122: 871. DOI: 10.1016/j.egypro.2017.07.452
  • Lucie Merlier, Loïc Frayssinet, Kévyn Johanne & Frédéric Kuznik (2019). On the impact of local microclimate on building performance simulation. Part II: Effect of external conditions on the dynamic thermal behavior of buildings. Building Simulation, 12(5): 747. DOI: 10.1007/s12273-019-0508-6


  • Responsible for this page: Peter Berkesand
    Last updated: 2019-11-06