Effect of Particle Size in Aviation Turbine Fuel-Al2O3 Nanofluids for Heat Transfer Applications
The effect of Alumina nanoparticle size on thermophysical
properties, heat transfer performance and pressure loss characteristics of
Aviation Turbine Fuel (ATF)-Al2O3 nanofluids is studied experimentally for
the proposed application of regenerative cooling of semi-cryogenic rocket
engine thrust chambers. Al2O3 particles with mean diameters of 50 nm or 150
nm are dispersed in ATF. At 500C and 0.3% particle volume concentration,
the bigger particles show increases of 17% in thermal conductivity and 55% in
viscosity, whereas the smaller particles show corresponding increases of 21%
and 22% for thermal conductivity and viscosity respectively. Contrary to these
results, experiments to study the heat transfer performance and pressure loss
characteristics show that at the same pumping power, the maximum
enhancement in heat transfer coefficient at 500C and 0.3% concentration is
approximately 47% using bigger particles, whereas it is only 36% using
smaller particles.
[1] S.U.S. Choi, J.A.Eastman, "Enhancing thermal conductivity of fluids
with nanoparticles", ASME Int. Mech. Engg. Congress and Exh., Nov.
12-17, 1995, San Francisco, CA (US).
[2] M.Chandrasekar, S.Suresh, A.Chandra Bose, "Experimental
investigations and theoretical determination of thermal conductivity and
viscosity of Al2O3/water nanofluid", Exp. Therm. Fluid Sci., vol. 34, pp.
210-216, Feb. 2010.
[3] D.Yoo, K.S.Hong, H.Yang, "Study of thermal conductivity of
nanofluids for the applications of heat transfer fluids", Thermochim.
Acta, vol. 455, pp. 66-69, Apr. 2007.
[4] X. Wang, X. Xu, S.U.S. Choi, "Thermal conductivity of nanoparticlesfluid
mixture", J. Thermophys. Heat Transfer, vol. 13(4), pp. 474-480,
Oct.-Dec. 1999.
[5] S.K.Das, N.Putra, P.Theisen, W.Roetzel, "Temperature dependence of
thermal conductivity enhancement of nanofluids", J. Heat Transfer, vol.
125, pp. 567-574, Aug. 2003.
[6] B.C.Pak, Y.I.Cho, "Hydrodynamic and heat transfer study of dispersed
fluids with submicron metallic oxide particles", Exp. Heat Transfer, vol.
11, pp.151-170, 1998.
[7] Y.Xuan, Q.Li, "Investigation on convective heat transfer and flow
features of nanofluids", ASME. J. Heat Transfer, vol. 125, pp. 151-155,
Feb. 2003.
[8] W. Duangthongsuk, S.Wongwises, "An experimental study on the heat
transfer performance and pressure drop of TiO2-water nanofluids
flowing under a turbulent flow regime", Int. J. Heat Mass Transfer, vol.
53, pp. 334-344, Jan. 2010.
[9] B. Farajollahi, S.Gh.Etemad, M.Hojjat, "Heat transfer of nanofluids in a
shell and tube heat exchanger", Int. J. Heat Mass Transfer, vol. 53, pp.
12-17, Jan. 2010.
[10] W.Yu, D.M.France, J.L.Routbort, S.U.S.Choi, "Review and comparison
of nanofluid thermal conductivity and heat transfer enhancements", Heat
Transfer Engg., vol. 29(5), pp. 432-460, 2008.
[11] S.M.S. Murshed, K.C.Leong, C.Yang, "Enhanced thermal conductivity
of TiO2-water based nanofluids", Int. J. Therm. Sci., vol. 44, pp. 367-
373, Apr. 2005.
[12] C. Codreanu, N. Codreanu, V. Obreja, "An experimental approach of the
hot wire method for measurement of the thermal conductivity", pp. 359-
362, IEEE, 2006.
[13] J.J.De Groot, J.Kestin, H.Sookiazian, "Instrument to measure thermal
conductivity of gases", Physica, vol. 75, pp., 454-482, 1974.
[14] F.P.Incropera, D.P.DeWitt, Fundamentals of Heat and Mass Transfer,
5th Edi. Wiley, Singapore, 2002.
[15] M.L.V.Ramires, M.N.A.Fareleria, C.A.Nieto de Castro, M.Dix,
W.A.Wakeham, "The thermal conductivity of toluene and water", Int. J.
Thermophysics., vol. 14(6), pp. 1119-1130, 1993.
[16] D.H.Kumar, H. Patel, V.R.Rajeev Kumar, T.Sundarrajan, T.Pradip,
S.K.Das, "Model of heat conduction in nanofluids", Physical Rev. Lett.,
vol. 93 no. 14, 144301(1- 4), Oct. 2004.
[17] R.Prasher, P.Bhattacharya, P.Phelan, "Brownian-motion-based
convective-conductive model for the effective thermal conductivity of
nanofluids, Trans. ASME, vol. 128, pp. 588-595, June 2006.
[18] S.Kim, S.Choi, D.Kim, "Thermal conductivity of metal-oxide
nanofluids: particle size dependence and effect of laser irradiation",
Trans. ASME, vol. 129, pp. 298-307, Mar. 2007.
[19] C.Li,G.Peterson, "The effect of particle size on the effective thermal
conductivity of Al2O3-water nanofluids", J. Appl. Phy., 101, 044312(1-
5), 2007.
[20] S.P. Jang, S.U.S. Choi, "Role of Brownian motion in the enhanced
thermal conductivity of nanofluids", Appl. Phys. Lett., vol. 84, pp. 4316-
4318, May 2004.
[21] C.T.Nguyen,F.Desgranges,G.Roy,N.Galanis,T.Mare,S.Broucher,
H. Angue Minsta, "Temperature and particle-size dependent viscosity
data for water-based nanofluids-Hysteresis phenomenon", Int. J. Heat
Fluid Flow, vol. 28, pp. 1492-1506, Dec. 2007.
[22] C.T.Nguyen,F.Desgranges,N.Galanis,G.Roy,T.Mare,S.Broucher,
H. Angue Minsta, "Viscosity data for Al2O3-water nanofluid-hysteresis:
is heat transfer enhancement using nanofluids reliable?", Int. J. Ther.
Sci., vol. 47, pp. 103-111, Feb. 2008.
[23] P. Atkins and J. de Paula, Physical chemistry, 8th int. Edi. , New Delhi:
Oxford University Press, 2006.
[1] S.U.S. Choi, J.A.Eastman, "Enhancing thermal conductivity of fluids
with nanoparticles", ASME Int. Mech. Engg. Congress and Exh., Nov.
12-17, 1995, San Francisco, CA (US).
[2] M.Chandrasekar, S.Suresh, A.Chandra Bose, "Experimental
investigations and theoretical determination of thermal conductivity and
viscosity of Al2O3/water nanofluid", Exp. Therm. Fluid Sci., vol. 34, pp.
210-216, Feb. 2010.
[3] D.Yoo, K.S.Hong, H.Yang, "Study of thermal conductivity of
nanofluids for the applications of heat transfer fluids", Thermochim.
Acta, vol. 455, pp. 66-69, Apr. 2007.
[4] X. Wang, X. Xu, S.U.S. Choi, "Thermal conductivity of nanoparticlesfluid
mixture", J. Thermophys. Heat Transfer, vol. 13(4), pp. 474-480,
Oct.-Dec. 1999.
[5] S.K.Das, N.Putra, P.Theisen, W.Roetzel, "Temperature dependence of
thermal conductivity enhancement of nanofluids", J. Heat Transfer, vol.
125, pp. 567-574, Aug. 2003.
[6] B.C.Pak, Y.I.Cho, "Hydrodynamic and heat transfer study of dispersed
fluids with submicron metallic oxide particles", Exp. Heat Transfer, vol.
11, pp.151-170, 1998.
[7] Y.Xuan, Q.Li, "Investigation on convective heat transfer and flow
features of nanofluids", ASME. J. Heat Transfer, vol. 125, pp. 151-155,
Feb. 2003.
[8] W. Duangthongsuk, S.Wongwises, "An experimental study on the heat
transfer performance and pressure drop of TiO2-water nanofluids
flowing under a turbulent flow regime", Int. J. Heat Mass Transfer, vol.
53, pp. 334-344, Jan. 2010.
[9] B. Farajollahi, S.Gh.Etemad, M.Hojjat, "Heat transfer of nanofluids in a
shell and tube heat exchanger", Int. J. Heat Mass Transfer, vol. 53, pp.
12-17, Jan. 2010.
[10] W.Yu, D.M.France, J.L.Routbort, S.U.S.Choi, "Review and comparison
of nanofluid thermal conductivity and heat transfer enhancements", Heat
Transfer Engg., vol. 29(5), pp. 432-460, 2008.
[11] S.M.S. Murshed, K.C.Leong, C.Yang, "Enhanced thermal conductivity
of TiO2-water based nanofluids", Int. J. Therm. Sci., vol. 44, pp. 367-
373, Apr. 2005.
[12] C. Codreanu, N. Codreanu, V. Obreja, "An experimental approach of the
hot wire method for measurement of the thermal conductivity", pp. 359-
362, IEEE, 2006.
[13] J.J.De Groot, J.Kestin, H.Sookiazian, "Instrument to measure thermal
conductivity of gases", Physica, vol. 75, pp., 454-482, 1974.
[14] F.P.Incropera, D.P.DeWitt, Fundamentals of Heat and Mass Transfer,
5th Edi. Wiley, Singapore, 2002.
[15] M.L.V.Ramires, M.N.A.Fareleria, C.A.Nieto de Castro, M.Dix,
W.A.Wakeham, "The thermal conductivity of toluene and water", Int. J.
Thermophysics., vol. 14(6), pp. 1119-1130, 1993.
[16] D.H.Kumar, H. Patel, V.R.Rajeev Kumar, T.Sundarrajan, T.Pradip,
S.K.Das, "Model of heat conduction in nanofluids", Physical Rev. Lett.,
vol. 93 no. 14, 144301(1- 4), Oct. 2004.
[17] R.Prasher, P.Bhattacharya, P.Phelan, "Brownian-motion-based
convective-conductive model for the effective thermal conductivity of
nanofluids, Trans. ASME, vol. 128, pp. 588-595, June 2006.
[18] S.Kim, S.Choi, D.Kim, "Thermal conductivity of metal-oxide
nanofluids: particle size dependence and effect of laser irradiation",
Trans. ASME, vol. 129, pp. 298-307, Mar. 2007.
[19] C.Li,G.Peterson, "The effect of particle size on the effective thermal
conductivity of Al2O3-water nanofluids", J. Appl. Phy., 101, 044312(1-
5), 2007.
[20] S.P. Jang, S.U.S. Choi, "Role of Brownian motion in the enhanced
thermal conductivity of nanofluids", Appl. Phys. Lett., vol. 84, pp. 4316-
4318, May 2004.
[21] C.T.Nguyen,F.Desgranges,G.Roy,N.Galanis,T.Mare,S.Broucher,
H. Angue Minsta, "Temperature and particle-size dependent viscosity
data for water-based nanofluids-Hysteresis phenomenon", Int. J. Heat
Fluid Flow, vol. 28, pp. 1492-1506, Dec. 2007.
[22] C.T.Nguyen,F.Desgranges,N.Galanis,G.Roy,T.Mare,S.Broucher,
H. Angue Minsta, "Viscosity data for Al2O3-water nanofluid-hysteresis:
is heat transfer enhancement using nanofluids reliable?", Int. J. Ther.
Sci., vol. 47, pp. 103-111, Feb. 2008.
[23] P. Atkins and J. de Paula, Physical chemistry, 8th int. Edi. , New Delhi:
Oxford University Press, 2006.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:50514", author = "Sandipkumar Sonawane and Upendra Bhandarkar and Bhalchandra Puranik and S. Sunil Kumar", title = "Effect of Particle Size in Aviation Turbine Fuel-Al2O3 Nanofluids for Heat Transfer Applications", abstract = "The effect of Alumina nanoparticle size on thermophysical
properties, heat transfer performance and pressure loss characteristics of
Aviation Turbine Fuel (ATF)-Al2O3 nanofluids is studied experimentally for
the proposed application of regenerative cooling of semi-cryogenic rocket
engine thrust chambers. Al2O3 particles with mean diameters of 50 nm or 150
nm are dispersed in ATF. At 500C and 0.3% particle volume concentration,
the bigger particles show increases of 17% in thermal conductivity and 55% in
viscosity, whereas the smaller particles show corresponding increases of 21%
and 22% for thermal conductivity and viscosity respectively. Contrary to these
results, experiments to study the heat transfer performance and pressure loss
characteristics show that at the same pumping power, the maximum
enhancement in heat transfer coefficient at 500C and 0.3% concentration is
approximately 47% using bigger particles, whereas it is only 36% using
smaller particles.", keywords = "Heat transfer performance, Nanofluids, Thermalconductivity, Viscosity", volume = "5", number = "9", pages = "1715-7", }
