Research Article
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Organ Transportation Thermoelectric Cooling System Design and Application

Year 2021, , 110 - 115, 31.12.2021
https://doi.org/10.18100/ijamec.1031379

Abstract

Thermoelectric modules are used in medical devices, air conditioners, refrigeration cabinets, measuring devices, etc. widely used in the fields. Application areas of thermoelectric modules and efforts to increase efficiency are in continuous development. In this study, an organ transport device with the thermoelectric cooling feature, which can be used in the medical field, was designed and performed and performance analyzes were made. An animal kidney measuring 5x6x10 cm was placed in the designed and realized system, and performance analyzes of the system were made at ambient temperatures of 25ºC, 30ºC, 35ºC, 40ºC. Each experiment was repeated five times and the average was taken. It was seen that the system, whose performance analyzes were carried out at different temperatures, was usable. The system's small size, less weight and low cost compared to conventional cooling systems are among the important advantages of the system. It is possible to say that with the further development of the implemented system, larger organs can be cooled and transported and further studies can be carried out in this direction.

Project Number

10201150

References

  • Siddique, A.R.M., S. Mahmud, and B. Van Heyst, A comprehensive review on a passive (phase change materials) and an active (thermoelectric cooler) battery thermal management system and their limitations. Journal of Power Sources, 2018. 401: p. 224-237.
  • Yadav, H., Srivastav, D., Kumar, G., Yadav, A. K., & Goswami, A., Experimental Investigations and Analysis of Thermoelectric Refrigerator with Multiple Peltier Modules. Int. J. Trend Sci. Res. Dev., vol, 2019. 3: p. 1337-1340.
  • Chaudhari, V., Kulkarni, M., Sakpal, S., Ubale, A., & Sangale, A. Eco-Friendly Refrigerator Using Peltier Device. in 2018 International Conference on Communication and Signal Processing (ICCSP). 2018. IEEE.
  • Çağlar, A., Optimization of operational conditions for a thermoelectric refrigerator and its performance analysis at optimum conditions. International Journal of Refrigeration, 2018. 96: p. 70-77.
  • Alghanima, Y.A., O. Mesalhy, and A.F.A. Gawad, Effect Of Position and Design Parameters of a Fan-Cooled Cold Side Heat Sink of a Thermoelectric Cooling-Module on The Performance of a Hybrid Refrigerator. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2021. 85(2): p. 66-79.
  • Gastelo-Roque, J.A. and A. Morales-Acevedo. Design of a photovoltaic system using thermoelectric Peltier cooling for vaccines refrigeration. in 2017 IEEE MIT Undergraduate Research Technology Conference (URTC). 2017. IEEE.
  • Moria, H., Ahmed, M., Alghanmi, A., Mohamad, T. I., & Yaakob, Y., Experimental study of solar based refrigerator using thermoelectric effect. Energy Procedia, 2019. 158: p. 198-203.
  • Alghanima, Y.A., O. Mesalhy, and A.F. AbdelGawad, Experimental Analysis of a Thermoelectric-(Vapor Compression) Hybrid Domestic Refrigerator.
  • Burande, D. V., Patil, S., Shinde, V., & Talathi, M., Performance Analysis of Portable Heating & Cooling System. New Arch-International Journal Of Contemporary Architecture, 2021. 8(2): p. 940-945.
  • Lyu, Y., Siddique, A. R. M., Majid, S. H., Biglarbegian, M., Gadsden, S. A., & Mahmud, S., Electric vehicle battery thermal management system with thermoelectric cooling. Energy Reports, 2019. 5: p. 822-827.
  • Jiang, L., Zhang, H., Li, J., & Xia, P. Thermal performance of a cylindrical battery module impregnated with PCM composite based on thermoelectric cooling. Energy, 2019. 188: p. 116048.
  • Li, X., Zhong, Z., Luo, J., Wang, Z., Yuan, W., Zhang, G., ... & Yang, C., Experimental investigation on a thermoelectric cooler for thermal management of a lithium-ion battery module. International Journal of Photoenergy, 2019. 2019.
  • Sirikasemsuk, S., Wiriyasart, S., Naphon, P., & Naphon, N., Thermal cooling characteristics of Li‐ion battery pack with thermoelectric ferrofluid cooling module. International Journal of Energy Research, 2021. 45(6): p. 8824-8836.
  • Işık, H. and E. Saraçoğlu, Comparison of Proportional Control and Fuzzy Logic Control to Develop an Ideal Thermoelectric Renal Hypothermia System. International Journal of Mechanical and Mechatronics Engineering, 2010. 4(8): p. 1328-1335.
  • Liao, M., He, Z., Jiang, C., Li, Y., & Qi, F., A three-dimensional model for thermoelectric generator and the influence of Peltier effect on the performance and heat transfer. Applied Thermal Engineering, 2018. 133: p. 493-500.
  • Fabián-Mijangos, A., G. Min, and J. Alvarez-Quintana, Enhanced performance thermoelectric module having asymmetrical legs. Energy Conversion and Management, 2017. 148: p. 1372-1381.
  • Jood, P., Ohta, M., Yamamoto, A., & Kanatzidis, M. G., Excessively doped PbTe with Ge-induced nanostructures enables high-efficiency thermoelectric modules. Joule, 2018. 2(7): p. 1339-1355.
  • Luo, D., Wang, R., Yu, W., & Zhou, W., Parametric study of a thermoelectric module used for both power generation and cooling. Renewable Energy, 2020. 154: p. 542-552.
  • Lim, H. and J.-W. Jeong, Energy saving potential of thermoelectric modules integrated into liquid desiccant system for solution heating and cooling. Applied Thermal Engineering, 2018. 136: p. 49-62.
Year 2021, , 110 - 115, 31.12.2021
https://doi.org/10.18100/ijamec.1031379

Abstract

Supporting Institution

Selçuk Üniversitesi

Project Number

10201150

References

  • Siddique, A.R.M., S. Mahmud, and B. Van Heyst, A comprehensive review on a passive (phase change materials) and an active (thermoelectric cooler) battery thermal management system and their limitations. Journal of Power Sources, 2018. 401: p. 224-237.
  • Yadav, H., Srivastav, D., Kumar, G., Yadav, A. K., & Goswami, A., Experimental Investigations and Analysis of Thermoelectric Refrigerator with Multiple Peltier Modules. Int. J. Trend Sci. Res. Dev., vol, 2019. 3: p. 1337-1340.
  • Chaudhari, V., Kulkarni, M., Sakpal, S., Ubale, A., & Sangale, A. Eco-Friendly Refrigerator Using Peltier Device. in 2018 International Conference on Communication and Signal Processing (ICCSP). 2018. IEEE.
  • Çağlar, A., Optimization of operational conditions for a thermoelectric refrigerator and its performance analysis at optimum conditions. International Journal of Refrigeration, 2018. 96: p. 70-77.
  • Alghanima, Y.A., O. Mesalhy, and A.F.A. Gawad, Effect Of Position and Design Parameters of a Fan-Cooled Cold Side Heat Sink of a Thermoelectric Cooling-Module on The Performance of a Hybrid Refrigerator. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 2021. 85(2): p. 66-79.
  • Gastelo-Roque, J.A. and A. Morales-Acevedo. Design of a photovoltaic system using thermoelectric Peltier cooling for vaccines refrigeration. in 2017 IEEE MIT Undergraduate Research Technology Conference (URTC). 2017. IEEE.
  • Moria, H., Ahmed, M., Alghanmi, A., Mohamad, T. I., & Yaakob, Y., Experimental study of solar based refrigerator using thermoelectric effect. Energy Procedia, 2019. 158: p. 198-203.
  • Alghanima, Y.A., O. Mesalhy, and A.F. AbdelGawad, Experimental Analysis of a Thermoelectric-(Vapor Compression) Hybrid Domestic Refrigerator.
  • Burande, D. V., Patil, S., Shinde, V., & Talathi, M., Performance Analysis of Portable Heating & Cooling System. New Arch-International Journal Of Contemporary Architecture, 2021. 8(2): p. 940-945.
  • Lyu, Y., Siddique, A. R. M., Majid, S. H., Biglarbegian, M., Gadsden, S. A., & Mahmud, S., Electric vehicle battery thermal management system with thermoelectric cooling. Energy Reports, 2019. 5: p. 822-827.
  • Jiang, L., Zhang, H., Li, J., & Xia, P. Thermal performance of a cylindrical battery module impregnated with PCM composite based on thermoelectric cooling. Energy, 2019. 188: p. 116048.
  • Li, X., Zhong, Z., Luo, J., Wang, Z., Yuan, W., Zhang, G., ... & Yang, C., Experimental investigation on a thermoelectric cooler for thermal management of a lithium-ion battery module. International Journal of Photoenergy, 2019. 2019.
  • Sirikasemsuk, S., Wiriyasart, S., Naphon, P., & Naphon, N., Thermal cooling characteristics of Li‐ion battery pack with thermoelectric ferrofluid cooling module. International Journal of Energy Research, 2021. 45(6): p. 8824-8836.
  • Işık, H. and E. Saraçoğlu, Comparison of Proportional Control and Fuzzy Logic Control to Develop an Ideal Thermoelectric Renal Hypothermia System. International Journal of Mechanical and Mechatronics Engineering, 2010. 4(8): p. 1328-1335.
  • Liao, M., He, Z., Jiang, C., Li, Y., & Qi, F., A three-dimensional model for thermoelectric generator and the influence of Peltier effect on the performance and heat transfer. Applied Thermal Engineering, 2018. 133: p. 493-500.
  • Fabián-Mijangos, A., G. Min, and J. Alvarez-Quintana, Enhanced performance thermoelectric module having asymmetrical legs. Energy Conversion and Management, 2017. 148: p. 1372-1381.
  • Jood, P., Ohta, M., Yamamoto, A., & Kanatzidis, M. G., Excessively doped PbTe with Ge-induced nanostructures enables high-efficiency thermoelectric modules. Joule, 2018. 2(7): p. 1339-1355.
  • Luo, D., Wang, R., Yu, W., & Zhou, W., Parametric study of a thermoelectric module used for both power generation and cooling. Renewable Energy, 2020. 154: p. 542-552.
  • Lim, H. and J.-W. Jeong, Energy saving potential of thermoelectric modules integrated into liquid desiccant system for solution heating and cooling. Applied Thermal Engineering, 2018. 136: p. 49-62.
There are 19 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Article
Authors

Yavuz Selim Taspınar 0000-0002-7278-4241

Prof. Dr. Hakan Işık 0000-0001-7066-6287

Project Number 10201150
Publication Date December 31, 2021
Published in Issue Year 2021

Cite

APA Taspınar, Y. S., & Işık, P. D. H. (2021). Organ Transportation Thermoelectric Cooling System Design and Application. International Journal of Applied Mathematics Electronics and Computers, 9(4), 110-115. https://doi.org/10.18100/ijamec.1031379
AMA Taspınar YS, Işık PDH. Organ Transportation Thermoelectric Cooling System Design and Application. International Journal of Applied Mathematics Electronics and Computers. December 2021;9(4):110-115. doi:10.18100/ijamec.1031379
Chicago Taspınar, Yavuz Selim, and Prof. Dr. Hakan Işık. “Organ Transportation Thermoelectric Cooling System Design and Application”. International Journal of Applied Mathematics Electronics and Computers 9, no. 4 (December 2021): 110-15. https://doi.org/10.18100/ijamec.1031379.
EndNote Taspınar YS, Işık PDH (December 1, 2021) Organ Transportation Thermoelectric Cooling System Design and Application. International Journal of Applied Mathematics Electronics and Computers 9 4 110–115.
IEEE Y. S. Taspınar and P. D. H. Işık, “Organ Transportation Thermoelectric Cooling System Design and Application”, International Journal of Applied Mathematics Electronics and Computers, vol. 9, no. 4, pp. 110–115, 2021, doi: 10.18100/ijamec.1031379.
ISNAD Taspınar, Yavuz Selim - Işık, Prof. Dr. Hakan. “Organ Transportation Thermoelectric Cooling System Design and Application”. International Journal of Applied Mathematics Electronics and Computers 9/4 (December 2021), 110-115. https://doi.org/10.18100/ijamec.1031379.
JAMA Taspınar YS, Işık PDH. Organ Transportation Thermoelectric Cooling System Design and Application. International Journal of Applied Mathematics Electronics and Computers. 2021;9:110–115.
MLA Taspınar, Yavuz Selim and Prof. Dr. Hakan Işık. “Organ Transportation Thermoelectric Cooling System Design and Application”. International Journal of Applied Mathematics Electronics and Computers, vol. 9, no. 4, 2021, pp. 110-5, doi:10.18100/ijamec.1031379.
Vancouver Taspınar YS, Işık PDH. Organ Transportation Thermoelectric Cooling System Design and Application. International Journal of Applied Mathematics Electronics and Computers. 2021;9(4):110-5.