Andreas Joos
Hamburg University of Technology, Institute of Thermo-Fluid Dynamics, Applied Thermodynamics, Germany
Karin Dietl
Hamburg University of Technology, Institute of Thermo-Fluid Dynamics, Applied Thermodynamics, Germany
Gerhard Schmitz
Hamburg University of Technology, Institute of Thermo-Fluid Dynamics, Applied Thermodynamics, Germany
Ladda ner artikel
http://dx.doi.org/10.3384/ecp09430102Ingår i: Proceedings of the 7th International Modelica Conference; Como; Italy; 20-22 September 2009
Linköping Electronic Conference Proceedings 43:95, s. 804-813
Publicerad: 2009-12-29
ISBN: 978-91-7393-513-5
ISSN: 1650-3686 (tryckt), 1650-3740 (online)
Due to its objected-oriented design Modelica is predestinated to describe chemical engineering unit operations. Still only few activity on this field is published. This paper introduces a library which covers three of four major thermal seperation processes: absorption; adsorption and rectification.
Additionally an extension of the ExternalMedia libraryis presented that allows the connection to thermodynamic and physical property packages for two phase mixtures. Also a possible forecast to an implementation of a CAPE-OPEN interface is made; allowing the use of a plurality of established chemical data packages.
[1] The CAPE-OPEN Laboratories Network. http://www.colan.org/; visited on August 2009.
[2] Casella; Francesco and Alberto Leva: Modelica open library for power plant simulation: design and experimental validation. In Proceedings Modelica Conference 2003; pages 41–50; 2003.
[3] Casella; Francesco; Martin Otter; Katrin Prölß; Christoph Richter; and Hubertus Tummescheit: The Modelica Fluid and Media library for modeling of incompressible and compressible thermo-fluid pipe networks. In Proceedings Modelica Conference 2006; pages 631–640; 2006.
[4] Casella; Francesco and Christoph Richter: ExternalMedia: A Library for Easy Re-Use of External Fluid Property Code in Modelica. In Proceedings Modelica Conference 2008; pages 157–161; 2008.
[5] COCO: cape open to cape open simulation environment. http://www.cocosimulator.org; visited on August 2009.
[6] FluidProp: Software for the calculation of thermophysical properties of fluids. http://fluidprop.tudelft.nl/; visited on January 2009.
[7] Goedecke; Ralf (editor): Fluid-Verfahrenstechnik. Wiley-VCH; 2006.
[8] Malzkorn; Rainer: Simulation eines Rauchgassprühwäschwers mit aufwärts gerichteten Düsen. PhD thesis; Ruhr-Universität Bochum; 1999.
[9] NIST Reference Fluid Thermodynamic and Transport Properties Database. http://www.nist.gov/srd/nist23.htm; visited on June 2009.
[10] Reid and Prausnitz: The Properties of Gases & Liquids. McGraw-Hill; 4th edition; 1987.
[11] Sandrock; Carl and Philip L. de Vaal: Dynamic simulation of Chemical Engineering systems using OpenModelica and CAPE-OPEN. In Jezowski; J. and J. Thullie (editors): 19th European Symposium on Computer Aided Process Engineering - ESCAPE19. Elsevier B.V./Ltd.; 2009.
[12] Stichlmair; Johann: Grundlagen der Dimensionierung des Gas/Flüssigkeits-Kontaktapparates Bodenkolonne. Verlag Chemie; 1978.
[13] Swaaij; W.P.M. van and G.F. Versteeg: Mass Transfer Accompanied With Complex Reversible Chemical Reactions In Gas-Liquid Systems: An Overview. Chemical Engineering Science; 47:3181–3195; 1992.
doi: 10.1016/0009-2509(92)85028-A.
