Modeling a Low-temperature Compressed Air Energy Storage with Modelica

Marcus Budt; Daniel Wolf; Roland Span

Title:

Author:

Marcus Budt: Fraunhofer Institute for Environmental, Safety, and Energy Technology UMSICHT, Oberhausen, Germany Daniel Wolf: Fraunhofer Institute for Environmental, Safety, and Energy Technology UMSICHT, Oberhausen, Germany Roland Span: Ruhr-University Bochum, Faculty for Mechanical Engineering, Bochum, Germany

DOI:

10.3384/ecp12076791

Download:

Full text (pdf)

Year:

2012

Conference:

Proceedings of the 9th International MODELICA Conference; September 3-5; 2012; Munich; Germany

Issue:

076

Article no.:

081

Pages:

791-800

No. of pages:

Publication type:

Abstract and Fulltext

Published:

2012-11-19

ISBN:

978-91-7519-826-2

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

The paper deals with the modeling of low-temperature compressed air energy storage. Aim of the modeling effort is to dynamically simulate the plant and analyzing the thermodynamics of the system. Here; off-design behavior regarding turbomachinery output temperatures; pressure losses and heat flows is of particular interest. Combined with an economical optimization tool; the presented model will be used to find an optimized plant layout.

Keywords: compressed air; energy storage; thermal storage; low-temperature; CAES; modeling; Modelica

Proceedings of the 9th International MODELICA Conference; September 3-5; 2012; Munich; Germany

Author:

Marcus Budt, Daniel Wolf, Roland Span

Title:

Modeling a Low-temperature Compressed Air Energy Storage with Modelica

DOI:

http://dx.doi.org/10.3384/ecp12076791

References:

[1] Wolf D.: Methods for Design and Application of Adiabatic Compressed Air Energy Storage Based on Dynamic Modeling. Bochum; Germany: PhD thesis; Ruhr-Universität Bochum; 2010; UMSICHTSchriftenreihe 65; urn:nbn:de:0011-n-1546519; 2011.

[2] Marquardt R.; Hoffmann S.; Pazzi S.; Klafki M.; Zunft S.: AA-CAES – Opportunities and challenges of advanced adiabatic compressed air energy storage technology as a balancing tool in interconnected grids. In: 40. Kraftwerkstechnisches Kolloquium 2008; Vol. 2; Technische Universität Dresden (Ed.); 2008.

[3] Budt M.; Wolf D.; Prümper H.-J.: A Low-temperature approach to Adiabatic Compressed Air Energy Storage. Proceedings of 12th International Conference on Energy Storage - INNOSTOCK; Lleida; Spain; 2012.

[4] Casella F.; Otter M.; Proelss K.; Richter Ch.; Tummescheit H.: The Modelica Fluid and Media library for modeling of incompressible and compressible thermo-fluid pipe networks. Proceedings of 5th International Modelica Conference; Vienna; Austria; 2006.

[5] Dassault Systèmes; Dymola 2012 FD01.

[6] Moustapha H.; Zelesky M.F.; Baines N.C.; Japikse D.: Axial and Radial Turbines. Concepts NREC (Ed.); 2003.

[7] Bloch H.; Soares C.: Turboexpanders and process application. Butterworth-Heinemann (Ed.); 2001.

[8] Wolf D.; Kanngießer A.; Budt M.; Dötsch Ch.: Adiabatic Compressed Air Energy Storage co-located with wind energy – multifunctional storage commitment optimization for the German market using GOMES. In: Energy Systems; Vol. 3; Issue 2; 2012.

Proceedings of the 9th International MODELICA Conference; September 3-5; 2012; Munich; Germany

Author:

Marcus Budt, Daniel Wolf, Roland Span

Title:

Modeling a Low-temperature Compressed Air Energy Storage with Modelica

DOI:

https://doi.org10.3384/ecp12076791

Note: the following are taken directly from CrossRef

Citations:

E. Jannelli, M. Minutillo, A. Lubrano Lavader & G. Falcucci (2014). A small-scale CAES (compressed air energy storage) system for stand-alone renewable energy power plant for a radio base station: A sizing-design methodology. Energy, 78: 313. DOI: 10.1016/j.energy.2014.10.016

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