Martin Ryhl Kærn
Technical University of Denmark, Department of Mechanical Engineering, Ljungby, Denmark
Brian Elmegaard
Technical University of Denmark, Department of Mechanical Engineering, Ljungby, Denmark
Ladda ner artikel
http://dx.doi.org/10.3384/ecp12076713Ingår i: Proceedings of the 9th International MODELICA Conference; September 3-5; 2012; Munich; Germany
Linköping Electronic Conference Proceedings 76:73, s. 713-726
Publicerad: 2012-11-19
ISBN: 978-91-7519-826-2
ISSN: 1650-3686 (tryckt), 1650-3740 (online)
In this paper a working principle based upon the novel expansion and distributor device EcoFlow(TM) is analyzed. The device enables compensation of flow maldistribution by control of individual channel superheat. The working principle is discontinuous liquid injection (pulsating flow) into each individual channels during a specified cycle time. Moreover; the influence of the injection cycle time is investigated together with an optional secondary flow into the other channels with regards to cooling capacity; overall UA-value and COP.
The results showed spurious fluctuations in pressure when simulating the pulsating flow; thus the dynamic behavior in the mixture two-phase flow model is insufficient to model the discontinuous liquid injection principle. Despite; the fluctuations and imperfections of the model we found that the cycle time should be kept as low as possible and that the optional secondary flow increases performance. Moreover; the paper reports on the applicability of Modelica developed models to analyze and optimize the working principle and design of expansion devices such that Modelica may be used in future development of novel discontinuous expansion devices.
refrigeration; air-conditioning; evaporator; two-phase flow; liquid injection; pulsation; transient; dynamic; modeling; simulation; Modelica
[1] W. V. Payne; P. A. Domanski; Potential benefits of smart refrigerant distributors; Final report No. ARTI-21CR/610-20050-01; Air-Conditioning and Refrigeration Technology Institute; Arlington; VA; USA (2003).
[2] J.-H. Kim; J. E. Braun; E. A. Groll; Evaluation of a hybrid method for refrigerant flow balancing in multi-circuit evaporators; International Journal of Refrigeration 32 (2009) 1283 – 1292.
doi: 10.1016/j.ijrefrig.2009.01.016.
[3] M. R. Kærn; Analysis of flow maldistribution in fin-and-tube evaporators for residential airconditioning systems; Ph.D. thesis; Technical University of Denmark; Department of Mechanical Engineering; Kgs. Lyngby; Denmark (2011).
[4] P. A. Domanski; D. Yashar; Application of an evolution program for refrigerant circuitry optimization; in: ACRECONF "Challenges To Sustainability"; New Delhi; India; 2007.
[5] T. Funder-Kristensen; H. Nicolaisen; J. Holst; M. H. Rasmussen; J. H. Nissen; Refrigeration system; US Patent; Pub. No.: US 2009/0217687 A1 (2009).
[6] G. Mader; C. Thybo; An electronic expansion valve with automatic refrigerant distribution control; in: Deutsche Kälte-Klima-Tagung; Magdeburg; Germany; 2010.
[7] R. W. Fox; A. T. McDonald; P. J. Pritchard; Introduction to fluid mechanics; Wiley; New York; 2004.
[8] C. Park; H. Cho; Y. Lee; Y. Kim; Mass flow characteristics and empirical modeling of R22 and R410A flowing through electronic expansion valves; International Journal of Refrigeration 30 (8) (2007) 1401–1407.
doi: 10.1016/j.ijrefrig.2007.03.011.
[9] L. Chen; J. Liu; J. Chen; Z. Chen; A new model of mass flow characteristics in electronic expansion valves considering metastability; International Journal of Thermal Sciences 48 (6) (2009) 1235 – 1242.
doi: 10.1016/j.ijthermalsci.2008.10.002.
[10] C. C. Richter; Proposal of new object-oriented equation-based model libraries for thermodynamic systems; Ph.D. thesis; Technische Universität Carolo-Wilhelmina zu Braunschweig; Fakultät für Maschinenbau (2008).
[11] M. R. Kærn; B. Elmegaard; L. F. S. Larsen; Experimental comparison of the dynamic evaporator response using homogeneous and slip flow modelling; in: 8th International Modelica Conference; Dresden; Germany; 2011.
[12] Dynasim AB; Research Park Ideon SE-223 70; Lund; Sweden; Dynamic Modeling Laboratory; Dymola User’s Manual; version 7.4 (2010).
[13] J. Eborn; H. Tummescheit; K. Prölss; Airconditioning - a modelica library for dynamic simulation of ac systems; in: 4th International Modelica Conference; Hamburg; Germany; 2005; pp. 185 – 192.
[14] M. J. Skovrup; Thermodynamic and thermophysical properties of refrigerants; Department of Energy Engineering; Technical University of Denmark; Nils Koppels Allé; Building 402; DK-2800 Lyngby; Denmark (2009).
[15] W.-J. Zhang; C.-L. Zhang; A generalized moving-boundary model for transient simulation of dry-expansion evaporators under larger disturbances; International Journal of Refrigeration 29 (2006) 1119 – 1127.
doi: 10.1016/j.ijrefrig.2006.03.002.
[16] O. Bauer; Modelling of two-phase flows with modelica; Master’s thesis; Lund University; Department of Automatic Control (1999).
[17] S. M. Ghiaasiaan; Two-phase flow: Boiling and Condensation in Conventional and Miniature Systems; 1st Edition; Cambridge University Press; 2008.
[18] S. V. Patankar; Numerical heat transfer and fluid flow; Taylor & Francis; 1980.
[19] A. F. Mills; Heat Transfer; 2nd Edition; Prentice Hall; 1999.
