A CFD parametric study on the performance of a low-temperature-differential γ-type Stirling engine

Abstract An in-house CFD code has been applied to a low-temperature-differential (LTD) γ-type Stirling engine to understand the effects posed by several geometrical and operational parameters on engine performance. The results include variations of pressure, temperature, and heat transfer rates within an engine cycle as well as variations of engine’s power and efficiency versus these parameters. It is found that power piston stroke and radius influence engine performance very similarly, and power and efficiency both increase as these two parameters increase. In fact, the effects of the two parameters can be assimilated into those by the parameter of compression ratio. The stroke of displacer is observed to affect strongly on heat input but weakly on power, thus causing the efficiency to decrease as it increases. As expected, both power and efficiency increase as temperature difference between the hot and cold ends increases. Lastly, engine speed is observed to pose strong positive effects on power but exert weak effects on efficiency. This study reveals the effects produced by several important parameters on engine performance, and such information is very useful for the design of new LTD Stirling engines.

[1]  Wen Lih Chen,et al.  A numerical analysis on the performance of a pressurized twin power piston gamma-type Stirling engine , 2012 .

[2]  Iskander Tlili,et al.  Design and performance optimization of GPU-3 Stirling engines , 2008 .

[3]  Tie Li,et al.  Development and test of a Stirling engine driven by waste gases for the micro-CHP system , 2012 .

[4]  Wen Lih Chen,et al.  A computational fluid dynamics study on the heat transfer characteristics of the working cycle of a β-type Stirling engine , 2014 .

[5]  Andreas Wagner,et al.  Thermodynamic analysis of a gamma type Stirling engine in non-ideal adiabatic conditions , 2009 .

[6]  James R. Senft Mechanical efficiency of heat engines , 2007 .

[7]  K. Pericleous,et al.  Mathematical modelling of a compressible oxygen jet entering a hot environment using a pressure-based finite volume code , 2012 .

[8]  Alibakhsh Kasaeian,et al.  Multi-objective optimization of GPU3 Stirling engine using third order analysis , 2014 .

[9]  W. Chen,et al.  A computational fluid dynamics study on the heat transfer characteristics of the working cycle of a low-temperature-differential γ-type Stirling engine , 2014 .

[10]  Fatih Aksoy,et al.  Thermodynamic analysis of a β type Stirling engine with a displacer driving mechanism by means of a lever , 2009 .

[11]  Khamid Mahkamov,et al.  Closure to “Discussion: ‘Design Improvements to a Biomass Stirling Engine Using Mathematical Analysis and 3D CFD Modeling’ ” (2007, ASME J. Energy Resour. Technol., 129, pp. 278, 279, 280) , 2007 .

[12]  Wen Lih Chen,et al.  An experimental study on the performance of the moving regenerator for a γ-type twin power piston Stirling engine , 2014 .

[13]  Somchai Wongwises,et al.  A review of solar-powered Stirling engines and low temperature differential Stirling engines , 2003 .

[14]  K. Mahkamov An axisymmetric computational fluid dynamics approach to the analysis of the working process of a solar stirling engine. , 2006 .