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DÜZ BİR LEVHA ÜZERİNDE ENİNE PULSATİF BİR JET İLE ISI TRANSFERİNİN DENEYSEL İNCELENMESİ

Year 2018, Volume: 38 Issue: 2, 63 - 74, 31.10.2018

Abstract

Bu çalışmada, düz bir levha üzerinde ısı transferine enine pulsatif bir jetin etkisi deneysel olarak incelenmiştir.
Deneysel çalışma bir ısıtıcı ve pulsatif bir jetten oluşmaktadır. Isıtıcı, sabit ısı akısına sahip bakır bir levhadan
yapılmış ve rüzgar tünelinin içine yerleştirilmiştir. Pulsatif jet, levha girişinde akış içerisine enjekte edilmektedir.
Pulsatif jet, piston-silindir mekanizmasının salınım hareketi ile oluşturulmakta ve ikincil kütle akısı yüksek basınçlı bir
fan kullanılarak sağlanmaktadır. Çalışmada, ana akış Reynolds sayısı, pulsatif jet frekansı ve genliği değiştirilirken
geometri ve diğer parametreler tüm durumlar için sabit kalmaktadır. Ayrıca, ısı transferi üzerinde bu parametrelerin
etkisi analiz edilmektedir. Deneyler, dört farklı genlik, altı farklı frekans ve dört farklı üfleme oranı için
gerçekleştirilmiştir. Isı transferi mekanizmasını açıklamak için duman-tel metodu ile akış görüntüleme yapılmış ve
anlık akış görüntüleri elde edilmiştir. Yüksek üfleme oranlarında, pulsatif frekans ve genliğin her ikisinin de artması
ile yüzey soğutma performansının arttığı gözlemlenmiştir. Elde edilen deneysel sonuçlar boyutsuz parametrelerin bir
fonksiyonu olarak verilmiştir.

References

  • Akcay, S., 2015, Heat transfer enhancement on the flat plate by using pulsating jet, Master's Thesis, Aksaray University, (in Turkish) Aksaray, Turkey.
  • Akdag, U., Cetin, O., Demiral, D., and Ozkul, I., 2013, Experimental investigation of convective heat transfer on a flat plate subjected to a transversely synthetic jet. International Communications in Heat and Mass Transfer, 49, 96-103.
  • Akdag, U., Komur, M. A., and Akcay, S., 2016,. Prediction of heat transfer on a flat plate subjected to a 73 transversely pulsating jet using artificial neural networks. Applied Thermal Engineering, 100, 412-420.
  • Akdag, U., Akcay, S., and Demiral, D., 2017, The investigation of the heat transfer characteristics of a cross-flow pulsating jet in a forced flow. Computational Thermal Sciences, 9(6), 567-582.
  • Audier, P., Fénot, M., Bénard, N., and Moreau, E., 2016, Film cooling effectiveness enhancement using surface dielectric barrier discharge plasma actuator, International Journal of Heat and Fluid Flow, Part B, 62, 247–257.
  • Coulthard, S. M., Volino, R. J., and Flack, K. A., 2007, Effect of jet pulsing on film cooling—Part I: Effectiveness and flow-field temperature results. Journal of Turbomachinery, 129 (2), 232-246.
  • Dai, S., Xiao, Y., He, L., Jin, T., and Zhao, Z., 2016, Film cooling from a hole with parallel auxiliary holes influences, Numerical Heat Transfer, Part A: Applications, 69 (5), 497-511.
  • Elnady, T., Hassan, I., Kadem, L., and Lucas, T., 2013, Cooling effectiveness of shaped film holes for leading edge. Experimental Thermal and Fluid Science, 44, 649-661.
  • Engels, G., Peck, R. E., and Kim, Y., 2001, Investigation of a quasi-steady liquid crystal technique for film cooling heat transfer measurements. Experimental Heat Transfer, 14 (3), 181-198.
  • Erkoc, E., Fonte, C. P., Dias, M. M., Lopes, J. C. B., and Santos, R. J., 2016, Numerical study of active mixing over a dynamic flow field in a T-jets mixer—Induction of resonance. Chemical Engineering Research and Design, 106, 74-91.
  • Heneka, C., Schulz, A., Bauer, H. J., Heselhaus, A., and Crawford, M. E., 2012, Film cooling performance of sharp edged diffuser holes with lateral inclination. Journal of Turbomachinery, 134 (4), 041015.
  • Incropera, F.P., and DeWitt, D.P., 2002, Fundamentals of Heat and Mass Transfer, 5th ed., Wiley, New York.
  • Kanani, H., Shams, M., Ebrahimi, R., and Ahmadian, T., 2008, Numerical simulation of film cooling effectiveness on a flat plate. International Journal for Numerical Methods in Fluids, 56 (8), 1329-1336.
  • Kline, S.J. and McClintock, F.A., 1953, Describing uncertainties in single-sample experiments, Mech. Eng., 75 (1),3–8.
  • Koc, I., Islamoglu, Y. and Akdag, U., 2009, Investigation of film cooling effectiveness and heat transfer coefficient and heat transfer coefficient for rectangular holes with two rows for rectangular holes, Aircraft Engineering and Aerospace Technology: An International Journal, 81 (2),106–117.
  • Lee, J. S., and Jung, I. S., 2002, Effect of bulk flow pulsations on film cooling with compound angle holes. International Journal of Heat and Mass Transfer, 45 (1), 113-123.
  • Lee, K. D., and Kim, K. Y., 2014, Film cooling performance of cylindrical holes embedded in a transverse trench. Numerical Heat Transfer, Part A: Applications, 65 (2), 127-143.
  • Li, G., Zheng, Y., Hu, G., and Zhang, Z., 2013, Experimental investigation on heat transfer enhancement from an inclined heated cylinder with constant heat input power in infrasonic pulsating flows. Experimental Thermal and Fluid Science, 49, 75-85.
  • Liu, X., Tao, Z., Ding, S., and Xu, G., 2013, Experimental investigation of heat transfer characteristics in a variable cross-sectioned two-pass channel with combined film cooling holes and inclined ribs. Applied Thermal Engineering, 50 (1), 1186-1193.
  • Loudon, C., and Tordesillas, A., 1998, The use of the dimensionless Womersley number to characterize the unsteady nature of internal flow. Journal of Theoretical Biology, 191 (1), 63-78.
  • Marzouk, S., Aissia, H. B., and Le Palec, G., 2015, Numerical study of amplitude and frequency effects upon a pulsating jet. Computers & Fluids, 123, 99-111.
  • Ramesh, S., Ramirez, D.G., Ekkad, S.V., and Alvin, M.A., 2016, Analysis of film cooling performance of advanced tripod hole geometries with and without manufacturing features, International Journal of Heat and Mass Transfer, 94, 9–19.
  • Rohlf, K., and Tenti, G., 2001, The role of the Womersley number in pulsatile blood flow: a theoretical study of the Casson model. Journal of Biomechanics,34 (1), 141-148.
  • Schreivogel, P., Abram, C., Fond, B., Straußwald, M., Beyrau, F., and Pfitzner, M., 2016, Simultaneous kHz-rate temperature and velocity field measurements in the flow emanating from angled and trenched film cooling holes, International Journal of Heat and Mass Transfer, 103, 390–400.
  • Sidik, N. A. C., Kianpour, E., and Golshokouh, I., 2013, Dynamic and Thermodynamic Analysis of Film-Cooling. International Review of Mechanical Engineering (IREME), 7 (3), 570-577.
  • Singh, K., Premachandran, B. and Ravi, M.R. 2016, Experimental assessment of film cooling performance of short cylindrical holes on a flat surface, International Journal of Heat and Mass Transfer, 52 (12), 2849–2862. 74
  • Sultan, Q., Lalizel, G., Fénot, M., and Dorignac, E., 2016, Influence of coolant jet pulsation on the convective film cooling of an adiabatic wall, Journal of Heat Transfer,139 (2), 022201.
  • Tu, Z., Mao, J., and Han, X., 2017, Numerical study of film cooling over a flat plate with anisotropic thermal conductivity, Applied Thermal Engineering, 111, 968–980.
  • Wu, H., Cheng, H., Li, Y., Rong, C., and Ding, S., 2016, Effects of side hole position and blowing ratio on sister hole film cooling performance in a flat plate, Applied Thermal Engineering, 93, 718–730.
  • Xie, G., Zheng , S., and Sundén, B., 2015, Heat transfer and flow characteristics in rib-/deflector-roughened cooling channels with various configuration parameters, Numerical Heat Transfer, Part A: Applications , 67 (2), 140-169.

EXPERIMENTAL INVESTIGATION OF HEAT TRANSFER WITH A TRANSVERSELY PULSATING JET ON A FLAT PLATE

Year 2018, Volume: 38 Issue: 2, 63 - 74, 31.10.2018

Abstract

In this study, the effect of a transversely pulsating jet on heat transfer over a flat plate is investigated
experimentally. The experimental study consists of a heater and a pulsating jet. The heater is made of a copper plate,
has a constant heat flux, and is located in a wind tunnel. The pulsating jet is injected into the stream at the plate
entrance. The pulsating jet is created using an oscillating movement of a piston-cylinder mechanism, and the
secondary mass flux is supplied using a high-pressure blower. In the study, the Reynolds number in the main stream,
the pulsating jet frequency and amplitude are changed, while the geometry and the other parameters remain constant
for all cases. Furthermore, the effect of these parameters on heat transfer is analyzed. The experiments are performed
for four different amplitudes and six different frequencies at four different blowing ratios. To explain the heat transfer
mechanism, flow visualization is performed using the smoke–wire method, and instantaneous flow images are
obtained. It is observed that, the surface cooling performance increases with the increase of both the pulsating
frequency and amplitude at high blowing ratios. The calculated experimental results are given as a function of
dimensionless parameters.

References

  • Akcay, S., 2015, Heat transfer enhancement on the flat plate by using pulsating jet, Master's Thesis, Aksaray University, (in Turkish) Aksaray, Turkey.
  • Akdag, U., Cetin, O., Demiral, D., and Ozkul, I., 2013, Experimental investigation of convective heat transfer on a flat plate subjected to a transversely synthetic jet. International Communications in Heat and Mass Transfer, 49, 96-103.
  • Akdag, U., Komur, M. A., and Akcay, S., 2016,. Prediction of heat transfer on a flat plate subjected to a 73 transversely pulsating jet using artificial neural networks. Applied Thermal Engineering, 100, 412-420.
  • Akdag, U., Akcay, S., and Demiral, D., 2017, The investigation of the heat transfer characteristics of a cross-flow pulsating jet in a forced flow. Computational Thermal Sciences, 9(6), 567-582.
  • Audier, P., Fénot, M., Bénard, N., and Moreau, E., 2016, Film cooling effectiveness enhancement using surface dielectric barrier discharge plasma actuator, International Journal of Heat and Fluid Flow, Part B, 62, 247–257.
  • Coulthard, S. M., Volino, R. J., and Flack, K. A., 2007, Effect of jet pulsing on film cooling—Part I: Effectiveness and flow-field temperature results. Journal of Turbomachinery, 129 (2), 232-246.
  • Dai, S., Xiao, Y., He, L., Jin, T., and Zhao, Z., 2016, Film cooling from a hole with parallel auxiliary holes influences, Numerical Heat Transfer, Part A: Applications, 69 (5), 497-511.
  • Elnady, T., Hassan, I., Kadem, L., and Lucas, T., 2013, Cooling effectiveness of shaped film holes for leading edge. Experimental Thermal and Fluid Science, 44, 649-661.
  • Engels, G., Peck, R. E., and Kim, Y., 2001, Investigation of a quasi-steady liquid crystal technique for film cooling heat transfer measurements. Experimental Heat Transfer, 14 (3), 181-198.
  • Erkoc, E., Fonte, C. P., Dias, M. M., Lopes, J. C. B., and Santos, R. J., 2016, Numerical study of active mixing over a dynamic flow field in a T-jets mixer—Induction of resonance. Chemical Engineering Research and Design, 106, 74-91.
  • Heneka, C., Schulz, A., Bauer, H. J., Heselhaus, A., and Crawford, M. E., 2012, Film cooling performance of sharp edged diffuser holes with lateral inclination. Journal of Turbomachinery, 134 (4), 041015.
  • Incropera, F.P., and DeWitt, D.P., 2002, Fundamentals of Heat and Mass Transfer, 5th ed., Wiley, New York.
  • Kanani, H., Shams, M., Ebrahimi, R., and Ahmadian, T., 2008, Numerical simulation of film cooling effectiveness on a flat plate. International Journal for Numerical Methods in Fluids, 56 (8), 1329-1336.
  • Kline, S.J. and McClintock, F.A., 1953, Describing uncertainties in single-sample experiments, Mech. Eng., 75 (1),3–8.
  • Koc, I., Islamoglu, Y. and Akdag, U., 2009, Investigation of film cooling effectiveness and heat transfer coefficient and heat transfer coefficient for rectangular holes with two rows for rectangular holes, Aircraft Engineering and Aerospace Technology: An International Journal, 81 (2),106–117.
  • Lee, J. S., and Jung, I. S., 2002, Effect of bulk flow pulsations on film cooling with compound angle holes. International Journal of Heat and Mass Transfer, 45 (1), 113-123.
  • Lee, K. D., and Kim, K. Y., 2014, Film cooling performance of cylindrical holes embedded in a transverse trench. Numerical Heat Transfer, Part A: Applications, 65 (2), 127-143.
  • Li, G., Zheng, Y., Hu, G., and Zhang, Z., 2013, Experimental investigation on heat transfer enhancement from an inclined heated cylinder with constant heat input power in infrasonic pulsating flows. Experimental Thermal and Fluid Science, 49, 75-85.
  • Liu, X., Tao, Z., Ding, S., and Xu, G., 2013, Experimental investigation of heat transfer characteristics in a variable cross-sectioned two-pass channel with combined film cooling holes and inclined ribs. Applied Thermal Engineering, 50 (1), 1186-1193.
  • Loudon, C., and Tordesillas, A., 1998, The use of the dimensionless Womersley number to characterize the unsteady nature of internal flow. Journal of Theoretical Biology, 191 (1), 63-78.
  • Marzouk, S., Aissia, H. B., and Le Palec, G., 2015, Numerical study of amplitude and frequency effects upon a pulsating jet. Computers & Fluids, 123, 99-111.
  • Ramesh, S., Ramirez, D.G., Ekkad, S.V., and Alvin, M.A., 2016, Analysis of film cooling performance of advanced tripod hole geometries with and without manufacturing features, International Journal of Heat and Mass Transfer, 94, 9–19.
  • Rohlf, K., and Tenti, G., 2001, The role of the Womersley number in pulsatile blood flow: a theoretical study of the Casson model. Journal of Biomechanics,34 (1), 141-148.
  • Schreivogel, P., Abram, C., Fond, B., Straußwald, M., Beyrau, F., and Pfitzner, M., 2016, Simultaneous kHz-rate temperature and velocity field measurements in the flow emanating from angled and trenched film cooling holes, International Journal of Heat and Mass Transfer, 103, 390–400.
  • Sidik, N. A. C., Kianpour, E., and Golshokouh, I., 2013, Dynamic and Thermodynamic Analysis of Film-Cooling. International Review of Mechanical Engineering (IREME), 7 (3), 570-577.
  • Singh, K., Premachandran, B. and Ravi, M.R. 2016, Experimental assessment of film cooling performance of short cylindrical holes on a flat surface, International Journal of Heat and Mass Transfer, 52 (12), 2849–2862. 74
  • Sultan, Q., Lalizel, G., Fénot, M., and Dorignac, E., 2016, Influence of coolant jet pulsation on the convective film cooling of an adiabatic wall, Journal of Heat Transfer,139 (2), 022201.
  • Tu, Z., Mao, J., and Han, X., 2017, Numerical study of film cooling over a flat plate with anisotropic thermal conductivity, Applied Thermal Engineering, 111, 968–980.
  • Wu, H., Cheng, H., Li, Y., Rong, C., and Ding, S., 2016, Effects of side hole position and blowing ratio on sister hole film cooling performance in a flat plate, Applied Thermal Engineering, 93, 718–730.
  • Xie, G., Zheng , S., and Sundén, B., 2015, Heat transfer and flow characteristics in rib-/deflector-roughened cooling channels with various configuration parameters, Numerical Heat Transfer, Part A: Applications , 67 (2), 140-169.
There are 30 citations in total.

Details

Primary Language English
Subjects Mechanical Engineering
Journal Section Research Article
Authors

Ünal Akdağ This is me

Selma Akçay This is me

Doğan Demirel This is me

Hakan Palancıoğlu This is me

Publication Date October 31, 2018
Published in Issue Year 2018 Volume: 38 Issue: 2

Cite

APA Akdağ, Ü., Akçay, S., Demirel, D., Palancıoğlu, H. (2018). EXPERIMENTAL INVESTIGATION OF HEAT TRANSFER WITH A TRANSVERSELY PULSATING JET ON A FLAT PLATE. Isı Bilimi Ve Tekniği Dergisi, 38(2), 63-74.