Numerical investigation of combined effect of nanofluids and impinging jets on heated surface

Mustafa Kılıç; Mahmut Yavuz; İbrahim Halil Yılmaz

Research Article

Year 2018, Volume: 2 Issue: 1, 14 - 19, 15.04.2018

Mustafa Kılıç Mahmut Yavuz İbrahim Halil Yılmaz

Abstract

References

1. Cakır, M.T, Alamüna içeren Nanoakışkan kullanarak ısı borularının performanslarının iyileştirilmesi, Journal of The Faculty of Engineering and Architecture of Gazi University, 2015. 30: p.547-556.
2. Sun, B., Qu, Y., Yang, D., Heat transfer of Single Impinging jet with Cu nonofluids, Applied Thermal Engineering, 2016.102: p.701-707. 3. Teamah, M.A., Dawood M.M., Shehata A., Numerical and experimental investigation of flow structure and behavior of nanofluids flow impingement on horizontal flat plate, Experimental Thermal and Fluid Science, 2016. 74: p.235-246.
4. Qu j., Wu H.Y., Cheng P.,Thermal performance of an oscillating heat pipe with Al2O3-water nanofluids, International Communication Heat and Mass Transfer, , 2010. 37:p.111-115.
5. Chien, H.T., Tsia C.Y., Chen P.H., Chen P.Y., Improvement on thermal performance of a disck-shape miniature heat pipe with nanofluid, Proceedings of the fifth International Conference on Electric Packaging Technology, 2003,17:p.389-391.
6. Kang S.W.,Wei,W.C., Tsia S.H., Yang S.H., Experimental Investigation of silver nano-Fluid on heat pipe thermal performance, Applied Thermal Engineering, 2006. 26: p.2377-2382.
7. Xuan Y., Li Q., Heat transfer enhancement of nanofluids, Int.Journal of Heat and Flouid Flow, 2000. 21:pp.58-64.
8. Shang F.M., Liu D.Y., Xian H.Z., Yang Y.P., Du X.Z., Flow and heat transfer characteristics of different forms of nanaometer particles in oscillating heat pipe, Journal of Chemical Industry, 2007. 58: p.2200-2204.
9. Manay E., Sahin B., Akyurek E.F., Comakli O. Mikro kanallarda nanaoakışkanalrın kullanımı, TMMOB MMO Mühendis ve Makina Dergisi, 2012. 53: p.38-42.
10. Naphon P., Asssdamongkol P., Borirak T., Experimental investigation of titanium nanofluids on the heat pipe thermal efficiency, International Communication Heat and Mass Transfer, 2008. 35: p.1316-1319.
11. Kilic, M., Çalışır, T., Başkaya, Ş, Experimental and numerical study of heat transfer from a heated flat plate in a rectangular channel with an impinging Jet, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2016. 48, p.1-16.
12. Kilic M., Experimental and numerical study of heat transfer fro a heated flat plate in a rectangular channel with an impinging Jet, PhD Thesis, Graduate School of Natural and Applied Science, Gazi Unıversity, Turkiye, Oct. 2013.
13. Corcione M., Empirical correlating equations for predicting te effective thermal conductivity and dynamic viscosity of nanofluids.Energy Convers. Manag, 2011. 52(1), p.789-793.
14. Abdulvahitoğlu A, Evaluation of the fuel quality values of bay laurel ol as a biodiesel feedstock/title, Biofuels, 2018, 9: p.95-100.
15. Abdulvahitoğlu A,Tüccar G., 2017, Dizel Motorlarda Alternatif Yakıt Olarak Karpuz Çekirdeği Biyodizelinin Değerlendirilmesi, Gazi Üniversitesi Mühendislik-Mimarlık Fakültesi Dergisi, 2017. 32:p.211-216, 10.17341/gazimmfd.300610.
16. Abdulvahitoğlu A., Aydın K., Performance and exhaust emission characteristics of a CI engine fueled with synthesized fuel blends, Energy Education Science and Technology Part A: Energy Science and Research, 2012.2:p. 699-710.

Numerical investigation of combined effect of nanofluids and impinging jets on heated surface

Year 2018, Volume: 2 Issue: 1, 14 - 19, 15.04.2018

Mustafa Kılıç Mahmut Yavuz İbrahim Halil Yılmaz

Abstract

Present study is focused on
numerical investigation of heat transfer and fluid flow from a heated surface
by using nanofluids and impinging jets. Effects of Reynolds number, different
particle diameter and different types of nanofluids (TiO₂-water,
CuO-water, NiO-water) on heat transfer and fluid flow were studied numerically.
TiO₂-water nanofluid was used as a base coolant. Three impinging
jets were used to cool the surface. It is obtained that increasing jet
velocities from Ren/Re1=1-1.33-1.67 to Ren/Re1=1-1.20-1.40 causes an increase
of 49.9% on average Nusselt number (ANN) but increasing jet velocities from
Ren/Re1=1-1.20-1.40 to Ren/Re1=1-1.17-1.33 causes a decrease of 4.6% on ANN.
Particle diameter from Dp=80nm to 10nm causes an increase of 2.9% on ANN. Using
NiO-Water nanofluid causes an increase of 1% on ANN with respect to CuO and
2.8% with respect to TiO₂-water. Low Re k-ε turbulent model of PHOENICS
CFD code was used for numerical analysis. Numerical results show a good
approximation to experimental results.

Keywords

Heat transfer, Multiple impinging jets, Nanofluids

References

1. Cakır, M.T, Alamüna içeren Nanoakışkan kullanarak ısı borularının performanslarının iyileştirilmesi, Journal of The Faculty of Engineering and Architecture of Gazi University, 2015. 30: p.547-556.
2. Sun, B., Qu, Y., Yang, D., Heat transfer of Single Impinging jet with Cu nonofluids, Applied Thermal Engineering, 2016.102: p.701-707. 3. Teamah, M.A., Dawood M.M., Shehata A., Numerical and experimental investigation of flow structure and behavior of nanofluids flow impingement on horizontal flat plate, Experimental Thermal and Fluid Science, 2016. 74: p.235-246.
4. Qu j., Wu H.Y., Cheng P.,Thermal performance of an oscillating heat pipe with Al2O3-water nanofluids, International Communication Heat and Mass Transfer, , 2010. 37:p.111-115.
5. Chien, H.T., Tsia C.Y., Chen P.H., Chen P.Y., Improvement on thermal performance of a disck-shape miniature heat pipe with nanofluid, Proceedings of the fifth International Conference on Electric Packaging Technology, 2003,17:p.389-391.
6. Kang S.W.,Wei,W.C., Tsia S.H., Yang S.H., Experimental Investigation of silver nano-Fluid on heat pipe thermal performance, Applied Thermal Engineering, 2006. 26: p.2377-2382.
7. Xuan Y., Li Q., Heat transfer enhancement of nanofluids, Int.Journal of Heat and Flouid Flow, 2000. 21:pp.58-64.
8. Shang F.M., Liu D.Y., Xian H.Z., Yang Y.P., Du X.Z., Flow and heat transfer characteristics of different forms of nanaometer particles in oscillating heat pipe, Journal of Chemical Industry, 2007. 58: p.2200-2204.
9. Manay E., Sahin B., Akyurek E.F., Comakli O. Mikro kanallarda nanaoakışkanalrın kullanımı, TMMOB MMO Mühendis ve Makina Dergisi, 2012. 53: p.38-42.
10. Naphon P., Asssdamongkol P., Borirak T., Experimental investigation of titanium nanofluids on the heat pipe thermal efficiency, International Communication Heat and Mass Transfer, 2008. 35: p.1316-1319.
11. Kilic, M., Çalışır, T., Başkaya, Ş, Experimental and numerical study of heat transfer from a heated flat plate in a rectangular channel with an impinging Jet, Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2016. 48, p.1-16.
12. Kilic M., Experimental and numerical study of heat transfer fro a heated flat plate in a rectangular channel with an impinging Jet, PhD Thesis, Graduate School of Natural and Applied Science, Gazi Unıversity, Turkiye, Oct. 2013.
13. Corcione M., Empirical correlating equations for predicting te effective thermal conductivity and dynamic viscosity of nanofluids.Energy Convers. Manag, 2011. 52(1), p.789-793.
14. Abdulvahitoğlu A, Evaluation of the fuel quality values of bay laurel ol as a biodiesel feedstock/title, Biofuels, 2018, 9: p.95-100.
15. Abdulvahitoğlu A,Tüccar G., 2017, Dizel Motorlarda Alternatif Yakıt Olarak Karpuz Çekirdeği Biyodizelinin Değerlendirilmesi, Gazi Üniversitesi Mühendislik-Mimarlık Fakültesi Dergisi, 2017. 32:p.211-216, 10.17341/gazimmfd.300610.
16. Abdulvahitoğlu A., Aydın K., Performance and exhaust emission characteristics of a CI engine fueled with synthesized fuel blends, Energy Education Science and Technology Part A: Energy Science and Research, 2012.2:p. 699-710.

There are 15 citations in total.

Details

Primary Language	English
Journal Section	Research Articles
Authors	Mustafa Kılıç 0000-0002-8006-149X Mahmut Yavuz This is me İbrahim Halil Yılmaz
Publication Date	April 15, 2018
Submission Date	March 2, 2018
Acceptance Date	March 12, 2018
Published in Issue	Year 2018 Volume: 2 Issue: 1

Cite

APA	Kılıç, M., Yavuz, M., & Yılmaz, İ. H. (2018). Numerical investigation of combined effect of nanofluids and impinging jets on heated surface. International Advanced Researches and Engineering Journal, 2(1), 14-19.
AMA	Kılıç M, Yavuz M, Yılmaz İH. Numerical investigation of combined effect of nanofluids and impinging jets on heated surface. Int. Adv. Res. Eng. J. April 2018;2(1):14-19.
Chicago	Kılıç, Mustafa, Mahmut Yavuz, and İbrahim Halil Yılmaz. “Numerical Investigation of Combined Effect of Nanofluids and Impinging Jets on Heated Surface”. International Advanced Researches and Engineering Journal 2, no. 1 (April 2018): 14-19.
EndNote	Kılıç M, Yavuz M, Yılmaz İH (April 1, 2018) Numerical investigation of combined effect of nanofluids and impinging jets on heated surface. International Advanced Researches and Engineering Journal 2 1 14–19.
IEEE	M. Kılıç, M. Yavuz, and İ. H. Yılmaz, “Numerical investigation of combined effect of nanofluids and impinging jets on heated surface”, Int. Adv. Res. Eng. J., vol. 2, no. 1, pp. 14–19, 2018.
ISNAD	Kılıç, Mustafa et al. “Numerical Investigation of Combined Effect of Nanofluids and Impinging Jets on Heated Surface”. International Advanced Researches and Engineering Journal 2/1 (April 2018), 14-19.
JAMA	Kılıç M, Yavuz M, Yılmaz İH. Numerical investigation of combined effect of nanofluids and impinging jets on heated surface. Int. Adv. Res. Eng. J. 2018;2:14–19.
MLA	Kılıç, Mustafa et al. “Numerical Investigation of Combined Effect of Nanofluids and Impinging Jets on Heated Surface”. International Advanced Researches and Engineering Journal, vol. 2, no. 1, 2018, pp. 14-19.
Vancouver	Kılıç M, Yavuz M, Yılmaz İH. Numerical investigation of combined effect of nanofluids and impinging jets on heated surface. Int. Adv. Res. Eng. J. 2018;2(1):14-9.

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