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Year 2018, , 25 - 32, 07.09.2018
https://doi.org/10.17350/HJSE19030000116

Abstract

References

  • 1. Devrim Y, Erkan S, Baç N, Eroğlu, I. Improvement of PEMFC performance with Nafion /inorganic nanocomposite membrane electrode assembly prepared by ultrasonic coating technique. International Journal of Hydrogen Energy 37(21) (2012) 16748- 16758.
  • 2. Barbir F. PEM Fuel Cells: Theory and Practice, second ed. Academic Press, New York, 2012
  • 3. Araya SS, Zhou F, Liso V, Sahlin SL, Vang JR, Thomas S, Kær SK A Comprehensive Review of Pbi-Based High Temperature PEM Fuel Cells. International Journal of Hydrogen Energy 41(46) (2016) 21310-21344.
  • 4. Gosselin D., A Stack Cost Comparison of 100 kW Combined Heat and Power Fuel Cell Systems, Department of Energy 2014, Website: http://lma.berkeley.edu/research.html, last access: 01.10.2017
  • 5. Song T, Yi J, Kim J, Choi K. Challenges and Opportunities of Thermal Management for High –Temperature Proton Exchange Membrane Fuel Cells, 2010.
  • 6. Alejandro J, Arce A, Bordons C. Development and experimental validation of a PEM fuel cell dynamic model. Journal of power sources, 173(1) (2007) 310-324.

Investigation of Working Temperature Effect on Micro-Cogeneration Application of Proton Exchange Membrane Fuel Cells

Year 2018, , 25 - 32, 07.09.2018
https://doi.org/10.17350/HJSE19030000116

Abstract

İn this study, micro-cogeneration application is used to increase the efficiency of Proton Exchange Membrane Fuel Cell PEMFC systems and effect of different operation temperatures on system performance is observed. For this reason, two different PEMFC systems were comparatively studied operating at 70o C and 160o C, respectively. Micro-cogeneration system design has done considering experimentally determined current density, power and temperature values. Since the amount of heat extracted from each PEMFC system is different related to the operating temperatures, different heat transfer fluids have been used for the cooling systems. These systems are designed for utilization of electricity and hot water for Atılım University Hydrogen Energy Laboratory. Heat loss calculation is made for the laboratory and thermal energy needed for heating the laboratory is calculated. Parallel to the design calculations, simple payback times for PEMFCs with micro-cogeneration applications were determined. LT-PEMFC and HT-PEMFC systems have 402 W and 456 W thermal powers respectively and 87.4 % and 92.8 % total cogeneration efficiencies were calculated for each system respectively. For each system maximum water temperatures and flow rates are calculated as a result of micro-cogeneration application. HT-PEMFC system has found to be capable of higher amount of heating. Even LT-PEMFC system has a lower thermal power and efficiency; it is determined to be more economical and has a lower pay pack time then HT-PEMFC system. For both systems, necessary number of stacks to be used for laboratory heating is calculated as four.

References

  • 1. Devrim Y, Erkan S, Baç N, Eroğlu, I. Improvement of PEMFC performance with Nafion /inorganic nanocomposite membrane electrode assembly prepared by ultrasonic coating technique. International Journal of Hydrogen Energy 37(21) (2012) 16748- 16758.
  • 2. Barbir F. PEM Fuel Cells: Theory and Practice, second ed. Academic Press, New York, 2012
  • 3. Araya SS, Zhou F, Liso V, Sahlin SL, Vang JR, Thomas S, Kær SK A Comprehensive Review of Pbi-Based High Temperature PEM Fuel Cells. International Journal of Hydrogen Energy 41(46) (2016) 21310-21344.
  • 4. Gosselin D., A Stack Cost Comparison of 100 kW Combined Heat and Power Fuel Cell Systems, Department of Energy 2014, Website: http://lma.berkeley.edu/research.html, last access: 01.10.2017
  • 5. Song T, Yi J, Kim J, Choi K. Challenges and Opportunities of Thermal Management for High –Temperature Proton Exchange Membrane Fuel Cells, 2010.
  • 6. Alejandro J, Arce A, Bordons C. Development and experimental validation of a PEM fuel cell dynamic model. Journal of power sources, 173(1) (2007) 310-324.
There are 6 citations in total.

Details

Primary Language English
Journal Section Research Article
Authors

Yağmur Budak This is me

Ekin Özgirgin Yapıcı This is me

Yılser Devrim This is me

Publication Date September 7, 2018
Published in Issue Year 2018

Cite

Vancouver Budak Y, Yapıcı EÖ, Devrim Y. Investigation of Working Temperature Effect on Micro-Cogeneration Application of Proton Exchange Membrane Fuel Cells. Hittite J Sci Eng. 2018;5:25-32.

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