The objective of the present experimental
work is to investigate the performance of a wrapped screen heat pipe for atmospheric
air heating to compare with the limits of this pipe. The experiment was
conducted using copper pipe material and acetone as working fluid at different
vapor temperatures. The testing also consists of a heater, a blower for heat
removal (condenser), temperature measuring device, a vapor temperature probe,
acetone charging system, and a vacuum pump. The copper outside diameterof the
pipe is 0.022 m, with a total length of 0.6 m. The results showed that the pipe
wall temperature (Tw) for a wrapped screen heat pipe has a rapid increase and
takes 50 min to reach steady state at (Q = 63 W). The vapour temperature of
working fluid increases as the heat load increases at constant air velocity. It
was also been found that the range of vapour temperature deceases as the
filling ratio increases that means the increasing of the filling ratio results
the decrease of the maximum vapour temperature and the variation in the vapour
temperature. The best recorded filling ratio is 0.6 which has the lowest vapour
temperature at highest heat load. The maximum heat transport limit for this
pipe is 80 W and the maximum temperature difference for air is 5。C.
?
References
[1]
Dinh, K. (2000) Dehumidifier Heat Pipes for Rice Drying and Storage. 6th International Heat Pipe Symposium, Chiang Mai, 5-9 November 2000.
[2]
Shafahi, M., Bianco, V., Vafai, K. and Manca, O. (2010) Thermal Performance of Flat-Shaped Heat Pipes Using Nanofluids. International Journal of Heat and Mass Transfer, 53, 1438-1445.
http://dx.doi.org/10.1016/j.ijheatmasstransfer.2009.12.007
[3]
Meyer, A. and Dobson, R.T. (2006) A Heat Pipe Heat Recovery Heat Exchanger for a Mini-Drier. Journal of Energy in Southern Africa, 17.
[4]
Mousa, M.G. (2011) Effect of Nanofluid Concentration on the Performance of Circular Heat Pipe. Ain Shams Engineering Journal, 2, 63-69. http://dx.doi.org/10.1016/j.asej.2011.03.003
[5]
Sarmasti Emami, M.R., Noie, S.H. and Khoshnoodh, M. (2008) Effect of Aspect Ratio and Filling Ratio on Thermal Performance of an Inclined Two-Phase Closed. Iranian Journal of Science & Technology, Transaction B, Engineering, 32, 39-51.
[6]
Ong, K.S. and Tong, W.L. (2011) Inclination and Fill Ratio Effects on Water Filled Two-Phase Closed Thermosyphon. 10th IHPS, Taipei, 6-9 November 2011.
[7]
Raja Balayanan, S.R., Velmurugan, V., Sudhakaran, R. and Shenbaga Vinayaga Moorthi, N. (2011) Optimization of Thermal Performance of Water to Air Thermosyphon Solar Heat Pipe Heat Exchanger Using Response Surface Methodology. European Journal of Scientific Research, 59, 451-459.
[8]
Mirshahi, H. and Rahimi, M. (2009) Experimental Study on the Effect of Heat Loads, Fill Ratio and Extra Volume on Performance of a Partial-Vacuumed Thermosyphon. Iranian Journal of Chemical Engineering, 6.
[9]
Firouzfar, E., Soltanieh, M., Noie, S.H. and Saidi, M.H. (2011) Application of Heat Pipe Heat Exchangers in Heating, Ventilation and Air Conditioning (HVAC) Systems. Scientific Research and Essays, 6, 1900-1908.
[10]
Lv, F., Yu, G., Zhao, M., Zhang, J.M. and Yang, H.X. (2012) Investigation on Heat Pipe Application in Central Air-Conditioning Systems. Applied Mechanics and Materials, 170-173, 2546-2549.
http://dx.doi.org/10.4028/www.scientific.net/AMM.170-173.2546
[11]
Lei, S. (2014) Study of Influence Effect on Heat Transfer Performance of Single-Loop Oscillating Heat Pipe. Applied Mechanics and Materials, 535, 114-118. http://dx.doi.org/10.4028/www.scientific.net/AMM.535.114
[12]
Chi, W. (1976) Heat Pipe Theory and Practice. Hemisphere Publishing Corporation, New York.
