تعداد نشریات | 161 |
تعداد شمارهها | 6,532 |
تعداد مقالات | 70,500 |
تعداد مشاهده مقاله | 124,085,812 |
تعداد دریافت فایل اصل مقاله | 97,189,379 |
A feasibility study and economic analysis for application of nanofluids in waste heat recovery | ||
Energy Equipment and Systems | ||
مقاله 11، دوره 4، شماره 2، اسفند 2016، صفحه 205-214 اصل مقاله (1.17 M) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22059/ees.2016.59555 | ||
نویسندگان | ||
Mahyar Ebrahimi* 1؛ Marzieh Akhoundi2 | ||
1Department of Materials Science and Engineering of Sharif University of Technology, Tehran, Iran | ||
2Faculty of Aerospace Engineering K.N.Toosi University of Technology, Tehran, Iran | ||
چکیده | ||
This paper presents a comprehensive theoretical, experimental, and economic study on the application of nanofluids as heat transfer fluid in waste heat recovery systems. The research work was conducted in a steel-making complex in which a plate heat exchanger had been used to recover heat from hot process water. The system was theoretically modelled and the effects of using nanofluids as heat transfer fluid were investigated. Nanofluids with ZnO, Al2O3, SiO2, and CuO as nanoparticles and water as base fluid were used in the analysis. It was found that the best performance is obtained with Al2O3 nanofluid. This can increase the effectiveness of the plate heat exchanger by up to four per cent. Based on this analysis, the existing heat transfer fluid (demineralized water) was replaced by Al2O3 nanofluid. The experiment confirmed the theoretically predicted increase of the heat exchanger’s effectiveness but this increase was a little lower than what was expected. Finally, an economic analysis was done using the net present value method. This economic analysis was performed twice: once with local market prices and once with global market prices. The results show that the project is economical based on global market prices. | ||
کلیدواژهها | ||
Economic Analysis؛ Net Present Value؛ Heat Recovery Nanofluid؛ Case study؛ Nanofluid | ||
مراجع | ||
[1] Murshed S. M. S., Leong K. C., Yang C., Enhanced Thermal Conductivity of TiO2—water Based Nanofluids, International Journal of Thermal Sciences (2005) 44(4): 367-373.
[2] Patel H. E., Sundararajan T., Das S. K., An Experimental Investigation into the Thermal Conductivity Enhancement in Oxide and Metallic Nanofluids, Journal of Nanoparticle Research, (2010) 12(3): 1015-1031.
[3] Chandrasekar M., Suresh S., Chandra Bose A., Experimental Investigations and Theoretical Determination of Thermal Conductivity and Viscosity of Al2O3/Water Nanofluid, Experimental Thermal and Fluid Science (2010)34(2): 210-216.
[4] Vajjha R. S., Das D. K., Namburu P. K., Numerical Study of Fluid Dynamic and Heat Transfer Performance of Al2O3 and CuO Nanofluids in the Flat Tubes of a Radiator, International Journal of Heat and Fluid Flow (2010) 31(4): 613-621.
[5] Duangthongsuk W., Wongwises S., Measurement of Temperature-Dependent Thermal Conductivity and Viscosity of TiO2-Water Nanofluids, Experimental Thermal and Fluid Science (2009)33(4): 706-714.
[6] Sundar L. S., Singh M. K., Sousa A., Enhanced Heat Transfer and Friction Factor of MWCNT–Fe3O4/Water Hybrid Nanofluids, International Communications in Heat and Mass Transfer (2014) 52: 73-83.
[7] Hussain S. H., Hussein A. K., Natural Convection Heat Transfer Enhancement in a Differentially Heated Parallelogrammic Enclosure Filled With Copper-Water Nanofluid. Journal of Heat Transfer (2014) 136(8): 082502.
[8] Wen D., Ding Y., Experimental Investigation into Convective Heat Transfer of Nanofluids at the Entrance Region under Laminar Flow Conditions, International Journal of Heat and Mass Transfer (2004) 47(24): 5181-5188.
[9] Rea U., McKrell T., Hu L. W., Buongiorno J., Laminar Convective Heat Transfer and Viscous Pressure Loss of Alumina–Water and Zirconia–Water Nanofluids, International Journal of Heat and Mass Transfer (2009) 52(7): 2042-2048.
[10] Kulkarni D. P., Das D. K., Vajjha R. S., Application of Nanofluids in Heating Buildings and Reducing Pollution, Applied Energy (2009) 86(12): 2566-2573.
[11] Rennie T. J., Raghavan V. G., Numerical Studies of a Double-Pipe Helical Heat Exchanger, Applied Thermal Engineering (2006) 26(11): 1266-1273.
[12] Kazemi-Beydokhti A., Zeinali Heris S., Thermal Optimization of Combined Heat and Power (CHP) Systems Using Nanofluids, Energy (2012) 44(1): 241-247.
[13] Wang L., Sundén B., Manglik R. M., Plate Heat Exchangers, Design, Applications and Performance (Eds.), (2007) 11.
[14] Hesselgreaves J. E., Compact Heat Exchangers, Selection, Design and Operation. Gulf Professional Publishing (2001).
[15] Shah R. K., Sekulic D. P. Fundamentals of Heat Exchanger Design, John Wiley & Sons (2003).
[16] Wang L., Sunden B., Optimal Design of Plate Heat Exchangers with and without Pressure Drop Specifications, Applied Thermal Engineering (2003) 23(3): 295-311.
[17] Guo Z. Y., Liu X. B., Tao W. Q., Shah R. K., Effectiveness–Thermal Resistance Method for Heat Exchanger Design and Analysis, International Journal of Heat and Mass Transfer (2010) 53(13): 2877-2884.
[18] Vlasogiannis P., Karagiannis G., Argyropoulos P., Bontozoglou V., Air–Water Two-Phase Flow and Heat Transfer in a Plate Heat Exchanger, International Journal of Multiphase Flow (2002) 28(5):757-772.
[19] Galeazzo F. C., Miura R. Y., Gut J. A., Tadini C. C., Experimental and Numerical Heat Transfer in a Plate Heat Exchanger. Chemical Engineering Science (2006) 61(21): 7133-7138.
[20] Bassiouny M. K., Martin H., Flow Distribution and Pressure Drop in Plate Heat Exchangers—I U-Type Arrangement, Chemical Engineering Science (1984) 39(4): 693-700.
[21] Bassiouny M. K., Martin H., Flow Distribution and Pressure Drop in Plate Heat Exchangers—II Z-Type Arrangement. Chemical Engineering Science (1984) 39(4):701-704.
[22] Tsai Y. C., Liu F. B., Shen P. T., Investigations of the Pressure Drop and Flow Distribution in a Chevron-Type Plate Heat Exchanger, International Communications in Heat and Mass Transfer (2009) 36(6): 574-578.
[23] Zhang Z., Li Y., CFD Simulation on Inlet Configuration of Plate-Fin Heat Exchangers, Cryogenics (2003) 43(12): 673-678.
[24] Prabhakara Rao B., Krishna Kumar P., Das S. K., Effect of Flow Distribution to the Channels on the Thermal Performance of a Plate Heat Exchanger, Chemical Engineering and Processing, Process Intensification (2002) 41(1): 49-58.
[25] Li X. W., Meng J. A., Li Z. X., An Experimental Study of the Flow and Heat Transfer between Enhanced Heat Transfer Plates for PHEs, Experimental Thermal and Fluid Science (2010) 34(8): 1194-1204.
[26] Durmuş A., Benli H., Kurtbaş İ., Gül H., Investigation of Heat Transfer and Pressure Drop in Plate Heat Exchangers Having Different Surface Profiles, International Journal of Heat and Mass Transfer (2009) 52(5):1451-1457.
[27] Muley A., Manglik R. M., Experimental Study of Turbulent Flow Heat Transfer and Pressure Drop in a Plate Heat Exchanger with Chevron Plates, Journal of Heat Transfer (1999) 121(1): 110-117.
[28] Dović D., Palm B., Švaić S., Generalized Correlations for Predicting Heat Transfer and Pressure Drop in Plate Heat Exchanger Channels of Arbitrary Geometry, International Journal of Heat and Mass Transfer (2009) 52(19): 4553-4563.
[29] Khan T. S., Khan M. S., Chyu M. C., Ayub Z. H. Experimental Investigation of Single Phase Convective Heat Transfer Coefficient in a Corrugated Plate Heat Exchanger for Multiple Plate Configurations, Applied Thermal Engineering (2010) 30(8): 1058-1065.
[30] Tinaut F. V., Melgar A., Ali A. A. Correlations for Heat Transfer and Flow Friction Characteristics of Compact Plate-Type Heat Exchangers, International Journal of Heat and Mass Transfer (1992) 35(7): 1659-1665.
[31] http://www.alfalaval.com/campaigns/waste-heat-recovery/heat-exchangers/pages/heat-exchangers.aspx
[32] Choi S. U., Zhang Z. G., Keblinski P. Nanofluids, In Encyclopedia of Nanoscience and Nanotechnology (2004) 6 (773):757-773.
[33] Pak B. C., Cho Y. I. Hydrodynamic and Heat Transfer Study of Dispersed Fluids with Submicron Metallic Oxide Particles, Experimental Heat Transfer an International Journal (1998) 11(2): 151-170.
[34] Corcione M. Heat Transfer Features of Buoyancy-Driven Nanofluids inside Rectangular Enclosures Differentially Heated at the Sidewalls, International Journal of Thermal Sciences (2010) 49(9): 1536-1546.
[35] Xuan Y., Roetzel W. Conceptions for Heat Transfer Correlation of Nanofluids, International Journal of Heat and Mass Transfer (2000) 43(19): 3701-3707.
[36] Patel H. E., Sundararajan T., Das S. K., An Experimental Investigation into the Thermal Conductivity Enhancement in Oxide and Metallic Nanofluids, Journal of Nanoparticle Research (2010)12(3): 1015-1031.
[37] Xuan Y., Li Q., Investigation on Convective Heat Transfer and Flow Features of Nanofluids, Journal of Heat Transfer (2003) 125(1): 151-155. | ||
آمار تعداد مشاهده مقاله: 418 تعداد دریافت فایل اصل مقاله: 368 |