Effect of Jet Diameter on Surface Quenching at Different Spatial Locations
An experimental investigation has been carried out to study the cooling of a hot horizontal Stainless Steel surface of 3 mm thickness, which has 800±10 C initial temperature. A round water jet of 22 ± 1 oC temperature was injected over the hot surface through straight tube type nozzles of 2.5- 4.8 mm diameter and 250 mm length. The experiments were performed for the jet exit to target surface spacing of 4 times of jet diameter and jet Reynolds number of 5000 -24000. The effect of change in jet Reynolds number on the surface quenching has been investigated form the stagnation point to 16 mm spatial location.
[1] Hatta N., Kokado, J., and Hanasaki, K., Numerical analysis of cooling
characteristics for water bar, Transaction of ISIJ, Vol. 23, pp. 555-564,
1983.
[2] Robidou, H., Auracher, H., Gardin, P., and Lebouche, M., Controlled
cooling of a hot plate with a water jet, Experimental Thermal and Fluid
Science, Vol. 26, pp. 123–129, 2002.
[3] Chen, S.J., Kothari, J., and Tseng, A.A., Cooling of a moving plate with
an impinging circular water jet, Experimental Thermal and Fluid
Science, Vol. 4, pp. 343-353, 1991.
[4] Garimella, S.V., and Nenaydykh, B., Nozzle geometry effect in liquid jet
impingement heat transfer, International Journal of Heat Mass Transfer,
Vol. 39, pp. 2915- 2923, 1996.
[5] Sun, H., Ma, C. F., and Nakayama, W., Local characteristics of
convective heat transfer from simulated microelectronic chips to
impinging submerged round water jets, ASME Journal of Electron
Packaging, Vol. 115, pp. 71-77, 1993.
[6] Raj, V.V., experimental investigation on the rewetting of hot horizontal
annular channels, International Communication in Heat and Mass
Transfer, Vol. 10, pp. 299- 311, 1983.
[7] Mozumder A.K., Monde, M., Woodfield, P.L. and Islam, M.A.,
Maximum heat flux in relation to quenching of a high temperature
surface with liquid jet impingement, International Journal of Heat and
Mass Transfer, Vol. 49, pp. 2877–2888, 2006.
[8] Baughn, J. W., Hechanova, A. E., and Yan, X., An experimental study
of entrainment effects on the heat transfer from a flat surface to a heated
circular impinging jet, ASME Journal of Heat Transfer, Vol. 113, pp
1023-1025, 1991.
[9] Lee J., and Lee S. J., The effect of nozzle configuration on stagnation
region heat transfer enhancement of axisymmetric jet impingement,
International Journal of Heat and Mass Transfer, Vol. 43, pp. 3497-
3509, 2000.
[10] Chitranjan Agrawal, R. Kumar, A. Gupta, B. Chatterjee, Rewetting and
Maximum Surface Heat Flux During Quenching of Hot Surface by
Round Water Jet Impingement, International Journal of Heat and Mass
Transfer, Vol. 55, pp. 4772-4782, 2012.
[11] Chitranjan Agrawal, R. Kumar, A. Gupta, B. Chatterjee, Determination
of Rewetting Velocity during Jet Impingement Cooling of a Hot Surface,
Transaction of ASME Thermal Science and Engineering Application,
Vol. 5, pp 011007-1-9, 2013.
[12] Chitranjan Agrawal, Ravi Kumar, Akhilesh Gupta, Barun Chatterjee,
Determination of Rewetting on Hot Horizontal Surface with Water Jet
Impingement through a Sharp Edge Nozzle, International Journal of
Thermal Science, Vol. 71, pp 310-323, 2013.
[13] Monde M., Critical heat flux in saturated forced convective boiling on a
heated disk with an impinging jet, A new generalized correlation,
Wärme- and Stoffübertragung, Vol. 19, pp. 205-209, 1985.
[14] Chitranjan Agrawal, Oisín F. Lyon, Ravi Kumar, Akhilesh Gupta,
Darina B. Murray, Rewetting of a hot horizontal surface through mist jet
impingement cooling, International journal of Heat and Mass Transfer,
vol. 58, pp. 188-196, 2013.
[15] Hall, D. E., Incropera, F.P., and Viskanta, R., Jet impingement boiling
from a circular free-surface jet during quenching: part 2—two-phase jet,
ASME Journal of Heat Transfer, Vol. 123, pp. 911-917, 2001.
[16] Garimella, S.V., and Rice, R.A., Confined and submerged liquid jet
impingement heat transfer, ASME Journal of Heat Transfer, Vol. 117,
pp. 871-877, 1995.
[17] Womac, J., Ramadhyani, S., and Incropera, F.P., Correlating equations
for impingement cooling of small heat sources with single circular liquid
jets, ASME Journal of Heat Transfer, Vol. 115, pp. 106-115, 1993.
[18] Ruch, M.A., and Holman, J.P., Boiling heat transfer to a Freon-113 jet
impinging upward onto a flat heated surface, International Journal of
Heat and Mass Transfer, Vol. 18, pp. 51-60, 1975.
[19] Monde M., and Katto, Y., Burnout in high heat-flux boiling system with
an impinging jet, International Journal of Heat and Mass transfer, Vol.
21, pp. 295-305, 1978.
[1] Hatta N., Kokado, J., and Hanasaki, K., Numerical analysis of cooling
characteristics for water bar, Transaction of ISIJ, Vol. 23, pp. 555-564,
1983.
[2] Robidou, H., Auracher, H., Gardin, P., and Lebouche, M., Controlled
cooling of a hot plate with a water jet, Experimental Thermal and Fluid
Science, Vol. 26, pp. 123–129, 2002.
[3] Chen, S.J., Kothari, J., and Tseng, A.A., Cooling of a moving plate with
an impinging circular water jet, Experimental Thermal and Fluid
Science, Vol. 4, pp. 343-353, 1991.
[4] Garimella, S.V., and Nenaydykh, B., Nozzle geometry effect in liquid jet
impingement heat transfer, International Journal of Heat Mass Transfer,
Vol. 39, pp. 2915- 2923, 1996.
[5] Sun, H., Ma, C. F., and Nakayama, W., Local characteristics of
convective heat transfer from simulated microelectronic chips to
impinging submerged round water jets, ASME Journal of Electron
Packaging, Vol. 115, pp. 71-77, 1993.
[6] Raj, V.V., experimental investigation on the rewetting of hot horizontal
annular channels, International Communication in Heat and Mass
Transfer, Vol. 10, pp. 299- 311, 1983.
[7] Mozumder A.K., Monde, M., Woodfield, P.L. and Islam, M.A.,
Maximum heat flux in relation to quenching of a high temperature
surface with liquid jet impingement, International Journal of Heat and
Mass Transfer, Vol. 49, pp. 2877–2888, 2006.
[8] Baughn, J. W., Hechanova, A. E., and Yan, X., An experimental study
of entrainment effects on the heat transfer from a flat surface to a heated
circular impinging jet, ASME Journal of Heat Transfer, Vol. 113, pp
1023-1025, 1991.
[9] Lee J., and Lee S. J., The effect of nozzle configuration on stagnation
region heat transfer enhancement of axisymmetric jet impingement,
International Journal of Heat and Mass Transfer, Vol. 43, pp. 3497-
3509, 2000.
[10] Chitranjan Agrawal, R. Kumar, A. Gupta, B. Chatterjee, Rewetting and
Maximum Surface Heat Flux During Quenching of Hot Surface by
Round Water Jet Impingement, International Journal of Heat and Mass
Transfer, Vol. 55, pp. 4772-4782, 2012.
[11] Chitranjan Agrawal, R. Kumar, A. Gupta, B. Chatterjee, Determination
of Rewetting Velocity during Jet Impingement Cooling of a Hot Surface,
Transaction of ASME Thermal Science and Engineering Application,
Vol. 5, pp 011007-1-9, 2013.
[12] Chitranjan Agrawal, Ravi Kumar, Akhilesh Gupta, Barun Chatterjee,
Determination of Rewetting on Hot Horizontal Surface with Water Jet
Impingement through a Sharp Edge Nozzle, International Journal of
Thermal Science, Vol. 71, pp 310-323, 2013.
[13] Monde M., Critical heat flux in saturated forced convective boiling on a
heated disk with an impinging jet, A new generalized correlation,
Wärme- and Stoffübertragung, Vol. 19, pp. 205-209, 1985.
[14] Chitranjan Agrawal, Oisín F. Lyon, Ravi Kumar, Akhilesh Gupta,
Darina B. Murray, Rewetting of a hot horizontal surface through mist jet
impingement cooling, International journal of Heat and Mass Transfer,
vol. 58, pp. 188-196, 2013.
[15] Hall, D. E., Incropera, F.P., and Viskanta, R., Jet impingement boiling
from a circular free-surface jet during quenching: part 2—two-phase jet,
ASME Journal of Heat Transfer, Vol. 123, pp. 911-917, 2001.
[16] Garimella, S.V., and Rice, R.A., Confined and submerged liquid jet
impingement heat transfer, ASME Journal of Heat Transfer, Vol. 117,
pp. 871-877, 1995.
[17] Womac, J., Ramadhyani, S., and Incropera, F.P., Correlating equations
for impingement cooling of small heat sources with single circular liquid
jets, ASME Journal of Heat Transfer, Vol. 115, pp. 106-115, 1993.
[18] Ruch, M.A., and Holman, J.P., Boiling heat transfer to a Freon-113 jet
impinging upward onto a flat heated surface, International Journal of
Heat and Mass Transfer, Vol. 18, pp. 51-60, 1975.
[19] Monde M., and Katto, Y., Burnout in high heat-flux boiling system with
an impinging jet, International Journal of Heat and Mass transfer, Vol.
21, pp. 295-305, 1978.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:66050", author = "C. Agrawal and R. Kumar and A. Gupta and B. Chatterjee", title = "Effect of Jet Diameter on Surface Quenching at Different Spatial Locations", abstract = "An experimental investigation has been carried out to study the cooling of a hot horizontal Stainless Steel surface of 3 mm thickness, which has 800±10 C initial temperature. A round water jet of 22 ± 1 oC temperature was injected over the hot surface through straight tube type nozzles of 2.5- 4.8 mm diameter and 250 mm length. The experiments were performed for the jet exit to target surface spacing of 4 times of jet diameter and jet Reynolds number of 5000 -24000. The effect of change in jet Reynolds number on the surface quenching has been investigated form the stagnation point to 16 mm spatial location.
", keywords = "Hot-Surface, Jet Impingement, Quenching, Stagnation Point.", volume = "8", number = "1", pages = "46-4", }
