Heat transfer in a smooth-walled reciprocating anti-gravity open thermosyphon

• Published in: International journal of thermal sciences Vol. 42; no. 12; pp. 1089 - 1103
• Main Authors: Chang, S.W., Su, L.M., Morris, W.D., Liou, T.M.
• Format: Journal Article
• Language: English
• Published: Paris Elsevier Masson SAS 01.12.2003; Elsevier
• Subjects: Anti-gravity; Applied sciences; Energy; Energy. Thermal use of fuels; Exact sciences and technology; Heat transfer; Piston cooling; Reciprocating; Theoretical studies. Data and constants. Metering; Thermosyphon; Piston cooling; Thermosyphon; Anti-gravity; Reciprocating; Diesel engine; Cooling; Marine propulsion; Engine piston; Heat transfer
• ISSN: 1290-0729; 1778-4166
• DOI: 10.1016/S1290-0729(03)00090-5

This paper describes an experimental investigation of heat transfer in a smooth-walled reciprocating anti-gravity open thermosyphon with relevance to the ‘shaker’ cooling system for the pistons of marine propulsive diesel engines. A selection of experimental results illustrates the interactive effects of inertial, reciprocating and buoyancy forces on heat transfer. It is demonstrated that the gravitational and reciprocating buoyancy effects, respectively, improve heat transfer in the static and reciprocating anti-gravity open thermosyphon. The individual pulsating force effect impairs heat transfer in the axial region with 5 hydraulic diameter length measured from the entrance of thermosyphon (region I). In the vicinity of sealed end of reciprocating thermosyphon with one hydraulic diameter from the sealed surface (region II), the individual pulsating force effect improves heat transfer at low pulsating number range, over which range a subsequent heat transfer reduction in this axial region is followed. The synergistic effects of inertial force, reciprocating force and buoyancy interaction in the reciprocating anti-gravity open thermosyphon could, respectively, impede or improve the regional heat transfers in the axial regions I and II from the static references of zero-buoyancy. A set of empirical correlations, which is physically consistent, was developed that permits the individual and interactive effects of inertial, reciprocating and buoyancy forces on heat transfer to be evaluated.