International Journal of Materials Chemistry and Physics
Articles Information
International Journal of Materials Chemistry and Physics, Vol.1, No.3, Dec. 2015, Pub. Date: Nov. 12, 2015
Experimental Investigation of Performance of Heat Pipe for Drilling Purposes
Pages: 343-346 Views: 2319 Downloads: 1309
[01] Mohammad Gholamhossein Pour, Department of Petroleum Engineering, Marvdasht Branch, Islamic Azad University, Marvdasht, Iran.
[02] Ehsan Ghaedi, Department of Petroleum Engineering, Marvdasht Branch, Islamic Azad University, Marvdasht, Iran.
Nano science development introduces nano materials which are used into the heat transfer subfields as nano fluids which are produced by dispersing nano particles of metals in the working fluids. Effects of different important parameters in heat pipe drill configuration, such as heat pipe diameter, heat flux input magnitude, length of the heat input zone and depth of the heat pipe within the drill are investigated. A solid cylinder model with conduction mechanism for heat transfer is proposed to simulate the performance of drill approximately. Numerical results from the proposed model are verified by the experimental data. Results indicate the significant effect of using a nano fluid in heat pipe drilling in temperature field reduction. Also, results propose applicable criteria in manufacturing nano fluid heat pipe in drilling.
Heat Pipe, Drilling, Modeling, Mechanism, Nano Fluid
[01] F. Moreira Bordin, R. Panosso Zeilmann (2014), Effect of the Cutting Edge Preparation on the Surface Integrity after Dry Drilling, Procedia CIRP, 13, pp. 103-107.
[02] M. Boopathi, S. Shankar, S. Manikandakumar, R. Ramesh (2013), Experimental Investigation of Friction Drilling on Brass, Aluminium and Stainless Steel, Procedia Engineerin, 64, pp. 1219-1226.
[03] D. Biermann, H. Hartmann (2012), Reduction of Burr Formation in Drilling Using Cryogenic Process Cooling, 3, pp. 85-90.
[04] S. P. Jang, S. U. S. Choi (2004), Role of Brownian motion in the enhanced thermal conductivity of nanofluids, Appl. Phys. Letter. 84, pp. 4316–4318.
[05] N. Bhuwakietkumjohn, S. Rittidech (2010), Internal flow patterns on heat transfer characteristics of a closed-loop oscillating heat-pipe with check valves using ethanol and a silver nano-ethanol mixture, Exp. Therm. Fluid Sci. 34, pp. 1000-1007.
[06] C. C. Tang, S. Tiwari, M. W. Cox (2013), Experimental Charactrization of Viscosity and Thermal Conductivity of Aluminum Oxide Nanofluid, Proceedings of the ASME 2013 Heat Transfer Summer Conference, HT 2013, July 14-19, 2013, Minneapolis, MN, USA.
[07] L. Zhu, T. Ch. Jen, Y. H. Yen, X. L. Kong (2011), Feasibility and Effectiveness of Heat Pipe Cooling in End Milling Operations: Thermal, Structural Static, and Dynamic Analyses: A New Approach. International Journal of Advanced Manufacturing Technology, 64, pp. 5-8.
[08] W.C., Wei, S. H., Tsai, S. Y., Yang, S. W., Kang, (2005a). Effect of nano-fluid onheat pipe thermal performance, in: Proceedings of the 3rd IASME/WSEAS. International Conference on Heat Transfer. Therm. Eng. Environ. 2, pp. 115–117.
[09] W. C., Wei, S. H., Tsai, S. Y., Yang, S.W., Kang, (2005b). Effect of nano-fluid concentration on heat pipe thermal performance. IASME Trans. 2, pp. 1432–1439.
[10] R. Sureshkumar, S. Tharves Mohideen, N. Nethaji (2013), Heat transfer characteristics of nanofluids in heat pipes: A review. Renewable and Sustainable Energy Reviews, 20, pp. 397-410.
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