Exergetic sustainability indicators as a tool in commercial aircraft: A case study for a turbofan engine

International Journal of Green Energy

Volumn 12, Issue 1, 2015, Pages 28-40

  Aydin, Hakan ^a   Turan, Onder ^b   Karakoc, T Hikmet ^b   Midilli, Adnan ^c  

^a Department of Aeronautical Engineer TUSAS Engine Industry ^*  (Turkey)

^b ANADOLU UNIVERSITY   (Turkey)

^c RECEP TAYYIP ERDOGAN UNIVERSITY   (Turkey)

Author keywords

Commercial aircraft; Environment; Sustainability indicator; Turbofan Exergy

Indexed keywords

COMMERCIAL AIRCRAFT; ENVIRONMENT; EXERGETIC; SUSTAINABILITY INDICATORS;

AIRCRAFT; ENERGY EFFICIENCY; ENGINE; EXERGY; SUSTAINABILITY;

EID: 84908375210     PISSN: 15435075     EISSN: 15435083     Source Type: Journal    
DOI: 10.1080/15435075.2014.889004     Document Type: Conference Paper

References (50)

1. Airbus. 2008. Airbus Socio Economic Report 2008.
2. Ao, Y., L. Gunnewiek, and M. A. Rosen. 2008. Critical review of exergy- based indicators for the environmental impact of emissions, International Journal of Green Energy, 5:(1-2):87-104
3. ATAG. 2010. Beginner's Guide to Aviation Efficiency Reference version.
4. Aydin, H. 2011. PhD thesis evaluation report. Turkey, Applied and Natural Sciences of Anadolu University.
5. Balkan, F., N. Colak, and A. Hepbasli. 2005. Performance evaluation of a triple effect evaporator with forward feed using exergy analysis; International Journal of Energy Research 29:455-70.
6. Balli, O., H. Aras, and A. Hepbasli. 2008. Exergetic and exergoeconomic analysis of an aircraft Jet Engine (AJE). International Journal of Exergy 5(6):567-81.
7. Bejan, A., G. Tsatsaronis, and M. J. Moran. 1996. Thermal design and optimization, Wiley, New York, USA.
8. Bejan, A. 2003. Constructal theory: tree-shaped flows and energy systems for aircraft, Journal of Aircraft 40(1):43-8.
9. Bejan, A. and D. L. Siems. 2001 The need for exergy analysis and thermodynamic optimization in aircraft development. International Journal of Exergy 1(1):14-24.
10. Boeing. 2011. The Boeing Company. Available at: www.boeing.com.
11. Brilliant, H. M. 1995a. Second law analysis of present and future turbine engines, AIAA Paper, 95-3030, July.
12. Cengel, Y. A. and M. A. Boles. 2008. Termodinamik: Muhendislik Yaklasimiyla, In Turkish, Literatur press, Turkey.
13. Cfm56. 2011. The CFM56-7B Turbofan Engine - CFM International. Available at: http://www.cfm56.com/products/cfm56-7b.
14. Dincer, I. and M. A. Rosen. 1998. Worldwide perspective on energy, environment and sustainable development. International Journal of Energy Research 22:1305-21.
15. Dincer, I. and M. A. Rosen. 2004. Exergy as a Driver for Achieving Sustainability, International Journal of Green Energy; 1: 1, 1-19.
16. Dincer, I. and M. A. Rosen. 2007. Exergy: energy, environment and sustainable development, Elsevier, Oxford, UK.
17. Ebadi, M. J. and M. Gorji-Bandpy. 2005. Exergetic analysis of gas turbine plants, International Journal of Exergy 2(1):31-9.
18. Edgerton, R. H. 1992. Available Energy and Environmental Economics. D.C. Heath, Toronto.
19. Edwards, C. F. 2004. Development of low-irreversibility engines, Energy Research at Stanford Report; 36.
20. Enviro. 2011. Aviation and the Environment. Available at: http://www.enviro.aero/Content/Upload/File/BeginnersGuide-Biofuels-Web.
21. Etele, J. and M. A. Rosen. 2001. Sensitivity of exergy efficiencies of aerospace engines to reference environmental selection. International Journal of Exergy 1(2):91-9.
22. Figliola, R. S., R. Tipton, and H. Li. 2003. Exergy approach to decisionbased design of integrated aircraft thermal systems. Journal of Aircraft 40(1):49-55.
23. Genoud, S. and J. B. Lesourd. 2009. Characterization of sustainable development indicators for various power generation technologies. International Journal of Green Energy, 6(3):257-67.
24. IATA. 2011. Boeing: Commercial Airplanes. Available at: http://www.boeing.com/commercial/cmo/forecast-summary.html.
25. Koroneos, C., A. Dompros, G. Roumbas, and N. Moussiopoulos. 2005. Advantages of use of hydrogen fuel as compared to kerosene. Resources, Conservation and Recycling 44(2):99-113.
26. Kotas, T. J. 1995. The Exergy method of thermal plant analysis, Reprint ed., Krieger, Malabar, Florida.
27. Leea, J., J. Ian, A. Waitz, Y. Brian, C. Kim, G. Gregg, L. Fleming, M. Curtis, and A. Holsclaw. 2007. System for assessing aviation's global emissions (SAGE), Part 2: Uncertainty assessment. Transportation Research Part D, 12:381-95.
28. Midilli, A. and I. Dincer. 2009. Development of some exergetic parameters for PEM fuel cells for measuring environmental impact and sustainability International Journal of Hyrdogen Energy 34:3858-72.
29. Midilli, A. and I. Dincer. 2010. Effects of some micro-level exergetic parameters of a PEMFC on the environment and sustainability. International Journal of Global Warming 2(1):65-80.
30. MIT, 2011. Global Airline Industry Program - MIT. Available at: http://web.mit.edu/airlines/analysis/analysis-airline-industry.html.
31. Moorhouse, D. J. 2003. Proposed system-level multidisciplinary analysis technique based on exergy methods. Journal of Aircraft 40(1):11-5.
32. Moran, M. J. 1989. Availability analysis: a guide to efficient energy use, revised ed. ASME, New York.
33. Moran, M. J. and E. Sciubba. 1994. Exergy analysis: principles and practice. Journal of Engineering for Gas Turbines and Power 116:285-90.
34. Muñoz, J. R., and M. R. Von Spakovsky. 2003. Decomposition in energy system synthesis/design optimization for stationary and aerospace applications. Journal of Aircraft 40(1):35-42.
35. Norberg, S., G. Tamm, J. Highley, M. Rounds, D. Boettner, and O. Arnas. 2009. Teaching thermodynamics via analysis of the west point power plant. International Journal of Green Energy 6(3):230-44.
36. Peeters, P. M., J. Middel, and A. Hoolhorst. 2005. Fuel efficiency of commercial aircraft: An overview of historical and future trends, NLR-CR-2005-669.
37. Riggins, D. W. 1996. High-speed engine/component performance assessment using exergy and thrust-based methods, NASA-CR-198271, January.
38. Rosen, M. A., I. Dincer, and M. Kanoglu. 2008. Role of exergy in increasing efficiency and sustainability and reducing environmental impact. Energy Policy 36:128-37.
39. Rosen, M. A. and J. Etele. 2004. Aerospace systems and exergy analysis: applications and methodology development needs. International Journal of Exergy 1(4):411-25.
40. Roth, B. and D. Mavris. 2001. A work availability perspective of turbofan engine performance. American Institute of Aeronautics and Astronautics; AIAA publication, No. 0391.
41. Roth, B. A. and D. N. Mavris. 2000. A comparison of thermodynamic loss models applied to the J79 Turbojet Engine; Joint Propulsion Conference and Exhibit, 36th, Huntsville, July, AL, pp.16-19.
42. Song, T. W., J. L. Sohn, J. H. Kim, T. S. Kim, and S. T. Ro. 2002. Exergy-based performance analysis of the heavy-duty gas turbine in part-load operating conditions. Exergy, An International Journal 2(2): 105-12.
43. Szargut, J. 1980. International progress in second law analysis. Energy 5:709-18.
44. Szargut, J. M., D. R. Morris, and F. R. Steward. 1988. Exergy analysis of thermal, chemical and metallurgical processes, Hemisphere, New York.
45. Turgut, E. T., T. H. Karakoc, and A. Hepbasli. 2007. Exergetic analysis of an aircraft turbofan engine. International Journal of Energy Research 31(14):1383-97.
46. Turgut, E. T., T. H. Karakoc, and A. Hepbasli. (2009a). Exergoeconomic analysis of an aircraft turbofan engine. International Journal of Exergy 6(3):277-94.
47. Turgut, E. T., T. H. Karakoc, A. Hepbasli, and M. A. Rosen. 2009b. Exergy analysis of a turbofan aircraft engine. International Journal of Exergy 6(2);181-99.
48. USHP. 2006. Transportation Committee, U.S. House of Representatives. Available at: http://www.house.gov/transportation/aviation/02-15-06/02-15-06memo.html.
49. Xiang, J. Y., M. Cali, and M. Santarelli. 2004. Calculation for physical and chemical exergy of flows in systems elaborating mixed-phase flows and a case study in an IRSOFC plant. International Journal of Energy Research 28:101-15.
50. Van Gool, W. 1997. Energy policy: fairly tales and factualities. in innovation and technology-strategies and policies. Dordrecht: Kluwer, 93-105.