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EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW

Year 2018, Volume: 4 Issue: 5, 2371 - 2380, 25.06.2018
https://doi.org/10.18186/thermal.439274

Abstract

With the increase of energy demand, many researchers tried to develop scientific approaches in order to design more efficient and environmentally friendly energy systems. Exergo-economic (thermoeconomic) analysis of a system or device is an efficient tool for evaluating the system in terms of the thermodynamic and economic aspects. In this parametric study, exergo-economic analysis of rectangular copper plain microchannels under single-phase flow conditions were investigated using de-ionised water. The exergo-economic performance was evaluated based on the relative cost difference and unit cost per product exergy tools. The channel aspect ratio effect on the unit cost per product exergy and relative cost difference was examined using three microchannel test sections with the same channel hydraulic diameter (Dh = 0.56 mm) and length (L = 62 mm) but different aspect ratios (β = 0.5, 2.56 and 4.94) under single-phase flow conditions. The results showed that the exergo-economic performances of the three microchannel test sections decreased as the net heat input increased over the experimental range. Moreover, the exergo-economic performance of test section 2 (β = 4.94) was found to be greater than the exergo-economic performances of test sections 1 and 3 (β = 0.5 and 2.56) at fixed flow rate and fixed net heat input case.

References

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  • [2] Ali, R. (2010). Phase Change Phenomena During Fluid Flow in Microchannels (Doctoral dissertation, KTH).
  • [3] Kadam, S. T., & Kumar, R. (2014). Twenty first century cooling solution: Microchannel heat sinks. International Journal of Thermal Sciences, 85, 73-92.
  • [4] Xu, S., Guo, Z., Hu, G., Chen, W., Lewis, R., Wong, C. N. (2014). Thermal and flow fields in single board computer cabin systems using CFD analysis. Engineering Applications of Computational Fluid Mechanics, 8(4), 574-585.
  • [5] Dix, J., Jokar, A., Martinsen, R. (2008). A microchannel heat exchanger for electronics cooling applications. In ASME 2008 6th International Conference on Nanochannels, Microchannels, and Minichannels (pp. 1935-1936). American Society of Mechanical Engineers.
  • [6] Bulut, M., Sozbir, N. (2015). Analytical investigation of a nanosatellite panel surface temperatures for different altitudes and panel combinations. Applied Thermal Engineering, 75, 1076-1083.
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  • [8] Tuckerman, D. B., & Pease, R. F. W. (1981). High-performance heat sinking for VLSI. IEEE Electron device letters, 2(5), 126-129.
  • [9] Kumar, R. (2016). A critical review on energy, exergy, exergoeconomic and economic (4-E) analysis of thermal power plants. Engineering Science and Technology, an International Journal.
  • [10] Pavelka, M., Klika, V., Vágner, P., Maršík, F. (2015). Generalization of exergy analysis. Applied Energy, 137, 158-172.
  • [11] Şöhret, Y. (2018). Exergo-sustainability analysis and ecological function of a simple gas turbine aero-engine. Journal of Thermal Engineering (JTEN), 4(4), 2083-2095.
  • [12] Koroglu, T., Sogut, O.S. (2017). Advanced exergy analysis of an organic rankine cycle waste heat recovery system of a marine power plant. Journal of Thermal Engineering (JTEN), 3(2), 1136-1148.
  • [13] Okure, M. A., Musinguzi, W. B., Sebbit, A., Løvås, T. (2014). Exergoeconomic analysis of a novel small‐scale CHP system for rural electrification in Uganda. International Conference on Heat Transfer, Fluid Mechanics and Thermodynamics.
  • [14] Villa, A. A. O., Dutra, J. C. C., Guerrero, J. R. H., dos Santos, C. A. C. (2016). Techno-economic and exergoeconomic analysis of a micro cogeneration system for a residential use. Acta Scientiarum. Technology, 1(1), 327-338.
  • [15] Fellah, G. M., Mgherbi, F. A., Aboghres, S. M. (2010). Exergoeconomic analysis for unit Gt14 of South Tripoli gas turbine power plant. Jordan Journal of Mechanical and Industrial Engineering, 4(4), 507-516.
  • [16] Gorji-Bandpy, M., Goodarzian, H. (2011). Exergoeconomic optimization of gas turbine power plants operating parameters using genetic algorithms: a case study. Thermal Science, 15(1), 43-54.
  • [17] Koşar, A. (2011). Exergo‐economic analysis of micro pin fin heat sinks. International Journal of Energy Research, 35(11), 1004-1013.
  • [18] Özdemir, M. R. (2016). Single-phase flow and flow boiling of water in rectangular metallic microchannels (Doctoral dissertation, Brunel University London).
  • [19] Invest in Turkey, Investment Support and Promotion Agency of Republic of Turkey. http://www.invest.gov.tr/en-US/investmentguide/investorsguide/Pages/BusinessPremises.as
Year 2018, Volume: 4 Issue: 5, 2371 - 2380, 25.06.2018
https://doi.org/10.18186/thermal.439274

Abstract

References

  • [1] Lee, J., Mudawar, I. (2009). Low-temperature two-phase microchannel cooling for high-heat-flux thermal management of defense electronics. IEEE transactions on components and packaging technologies, 32(2), 453-465.
  • [2] Ali, R. (2010). Phase Change Phenomena During Fluid Flow in Microchannels (Doctoral dissertation, KTH).
  • [3] Kadam, S. T., & Kumar, R. (2014). Twenty first century cooling solution: Microchannel heat sinks. International Journal of Thermal Sciences, 85, 73-92.
  • [4] Xu, S., Guo, Z., Hu, G., Chen, W., Lewis, R., Wong, C. N. (2014). Thermal and flow fields in single board computer cabin systems using CFD analysis. Engineering Applications of Computational Fluid Mechanics, 8(4), 574-585.
  • [5] Dix, J., Jokar, A., Martinsen, R. (2008). A microchannel heat exchanger for electronics cooling applications. In ASME 2008 6th International Conference on Nanochannels, Microchannels, and Minichannels (pp. 1935-1936). American Society of Mechanical Engineers.
  • [6] Bulut, M., Sozbir, N. (2015). Analytical investigation of a nanosatellite panel surface temperatures for different altitudes and panel combinations. Applied Thermal Engineering, 75, 1076-1083.
  • [7] Tabeling, P. (2007). Introduction to microfluidics. New York: Oxford University Press.
  • [8] Tuckerman, D. B., & Pease, R. F. W. (1981). High-performance heat sinking for VLSI. IEEE Electron device letters, 2(5), 126-129.
  • [9] Kumar, R. (2016). A critical review on energy, exergy, exergoeconomic and economic (4-E) analysis of thermal power plants. Engineering Science and Technology, an International Journal.
  • [10] Pavelka, M., Klika, V., Vágner, P., Maršík, F. (2015). Generalization of exergy analysis. Applied Energy, 137, 158-172.
  • [11] Şöhret, Y. (2018). Exergo-sustainability analysis and ecological function of a simple gas turbine aero-engine. Journal of Thermal Engineering (JTEN), 4(4), 2083-2095.
  • [12] Koroglu, T., Sogut, O.S. (2017). Advanced exergy analysis of an organic rankine cycle waste heat recovery system of a marine power plant. Journal of Thermal Engineering (JTEN), 3(2), 1136-1148.
  • [13] Okure, M. A., Musinguzi, W. B., Sebbit, A., Løvås, T. (2014). Exergoeconomic analysis of a novel small‐scale CHP system for rural electrification in Uganda. International Conference on Heat Transfer, Fluid Mechanics and Thermodynamics.
  • [14] Villa, A. A. O., Dutra, J. C. C., Guerrero, J. R. H., dos Santos, C. A. C. (2016). Techno-economic and exergoeconomic analysis of a micro cogeneration system for a residential use. Acta Scientiarum. Technology, 1(1), 327-338.
  • [15] Fellah, G. M., Mgherbi, F. A., Aboghres, S. M. (2010). Exergoeconomic analysis for unit Gt14 of South Tripoli gas turbine power plant. Jordan Journal of Mechanical and Industrial Engineering, 4(4), 507-516.
  • [16] Gorji-Bandpy, M., Goodarzian, H. (2011). Exergoeconomic optimization of gas turbine power plants operating parameters using genetic algorithms: a case study. Thermal Science, 15(1), 43-54.
  • [17] Koşar, A. (2011). Exergo‐economic analysis of micro pin fin heat sinks. International Journal of Energy Research, 35(11), 1004-1013.
  • [18] Özdemir, M. R. (2016). Single-phase flow and flow boiling of water in rectangular metallic microchannels (Doctoral dissertation, Brunel University London).
  • [19] Invest in Turkey, Investment Support and Promotion Agency of Republic of Turkey. http://www.invest.gov.tr/en-US/investmentguide/investorsguide/Pages/BusinessPremises.as
There are 19 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Mehmed Rafet Özdemir

Publication Date June 25, 2018
Submission Date May 28, 2017
Published in Issue Year 2018 Volume: 4 Issue: 5

Cite

APA Özdemir, M. R. (2018). EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW. Journal of Thermal Engineering, 4(5), 2371-2380. https://doi.org/10.18186/thermal.439274
AMA Özdemir MR. EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW. Journal of Thermal Engineering. June 2018;4(5):2371-2380. doi:10.18186/thermal.439274
Chicago Özdemir, Mehmed Rafet. “EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW”. Journal of Thermal Engineering 4, no. 5 (June 2018): 2371-80. https://doi.org/10.18186/thermal.439274.
EndNote Özdemir MR (June 1, 2018) EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW. Journal of Thermal Engineering 4 5 2371–2380.
IEEE M. R. Özdemir, “EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW”, Journal of Thermal Engineering, vol. 4, no. 5, pp. 2371–2380, 2018, doi: 10.18186/thermal.439274.
ISNAD Özdemir, Mehmed Rafet. “EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW”. Journal of Thermal Engineering 4/5 (June 2018), 2371-2380. https://doi.org/10.18186/thermal.439274.
JAMA Özdemir MR. EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW. Journal of Thermal Engineering. 2018;4:2371–2380.
MLA Özdemir, Mehmed Rafet. “EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW”. Journal of Thermal Engineering, vol. 4, no. 5, 2018, pp. 2371-80, doi:10.18186/thermal.439274.
Vancouver Özdemir MR. EXERGO-ECONOMIC ANALYSIS OF MICROCHANNELS IN SINGLE-PHASE FLOW. Journal of Thermal Engineering. 2018;4(5):2371-80.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering