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Stirling Cycle a n d Engines. Bryan Tibbetts California State University, Sacramento Fall 2012. Studied divinity at the University of Glasgow and the University of Edinburgh. Became a minister of the Church of Scotland. Obtained a patent for his “Heat Economiser ” in 1816.
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Stirling Cycle and Engines Bryan Tibbetts California State University, Sacramento Fall 2012
Studied divinity at the University of Glasgow and the University of Edinburgh. • Became a minister of the Church of Scotland. • Obtained a patent for his “Heat Economiser” in 1816. • “Heat Economiser” now called the regenerator. • Built first practical engine in 1818 used to pump water out of a quarry. Reverend Dr. Robert Stirling Born: October 25, 1790 Died: June 6, 1878 • The thermodynamic cycle driving Stirling’s engine was not completely understood until the work of Sadi Carnot (1796 - 1832) and was named the Stirling Cycle.
Ideal Stirling Cycle • Stirling Cycle P-V Diagram • 1 2: Isometric heat addition P 2 • 2 3: Isothermal expansion T = const QR Qin • 3 4: Isometric heat rejection 3 • 4 1: Isothermal compression 1 QR Qout T = const 4 • Cycle is reversible, and so can be mechanically powered to operate as a heat pump for cooling. V
Ideal Stirling Cycle • Stirling Cycle P-V Diagram P 2 T = const QR Qin 3 1 QR Qout T = const 4 V
Ideal Stirling Cycle • Stirling Cycle P-V Diagram P 2 T = const QR Qin 3 1 QR Qout T = const 4 V
Ideal Stirling Cycle • Stirling Cycle P-V Diagram P 2 T = const QR Qin 3 1 QR Qout T = const 4 V
Regenerator • Stirling Cycle P-V Diagram P 2 T = const QR Qin 3 1 QR Qout T = const 4 V
Authors: M.C. Campos, J.V.C. Vargas, J.C. Ordonez Thermodynamic Optimization of a Stirling Engine • Model based on Ford-Philips 4-215 engine
Authors: M.C. Campos, J.V.C. Vargas, J.C. Ordonez Thermodynamic Optimization of a Stirling Engine • Dimensionless Equations Describing System • Solved numerically using an adaptive time step fourth-fifth order Runge-Kutta method
Authors: M.C. Campos, J.V.C. Vargas, J.C. Ordonez Thermodynamic Optimization of a Stirling Engine • Optimized Efficiency and Work Plot • Two-way maximized system efficiency (ηmax,max) based on optimization of two system characteristic parameters, φ and y. • φis the ratio of the swept expansion volume over the total swept volume. • y is the ratio of the hot side heat transfer area over the total heat transfer area.
Finite Time Thermodynamic Evaluation of Endoreversible Stirling Heat Engine at Maximum Power Conditions • Author: IskanderTlili • Finite Time Thermodynamic analysis accounts for a finite temperature difference between the hot and cold sources and the working fluid of the engine (required for heat transfer to occur) and the finite amount of heat transferred in a finite time period per process.
Finite Time Thermodynamic Evaluation of Endoreversible Stirling Heat Engine at Maximum Power Conditions • Author: IskanderTlili • Regenerator effectiveness only effects Thermal Efficiency • Hot and cold side heat exchanger effectiveness only effects maximum power output
Finite Time Thermodynamic Evaluation of Endoreversible Stirling Heat Engine at Maximum Power Conditions • Author: IskanderTlili • Temperatures of the external hot and cold source fluids effect both the thermal efficiency and maximum power output
Thermodynamic Study on Optimal Solar Stirling Engine Cycle Taking Into Account the Irreversibilities Effects • Author: IskanderTlili • Model based on General Motors GPU-3 engine
Thermodynamic Study on Optimal Solar Stirling Engine Cycle Taking Into Account the Irreversibilities Effects • Author: IskanderTlili • Equations Describing System
Thermodynamic Study on Optimal Solar Stirling Engine Cycle Taking Into Account the Irreversibilities Effects • Author: IskanderTlili • Results
Oscillating Flow in a Stirling Engine Heat Exchanger • Authors: M. Kuosa, K. Saari, A. Kankkunen, T.-M. Tveit • Problem Approached • No correlations existed for calculating heat transfer coefficient and friction factor in oscillating flow • Annular Effect occurs in oscillating flow in a pipe, which is the maximum flow velocity occurs near the wall instead of the center of the pipe • Fluid flow in a Stirling engine is comprised of laminar, transitional, and turbulent flows during every cycle • Pressure losses for various geometries were also analyzed:
Oscillating Flow in a Stirling Engine Heat Exchanger • Authors: M. Kuosa, K. Saari, A. Kankkunen, T.-M. Tveit • Equations
Oscillating Flow in a Stirling Engine Heat Exchanger • Authors: M. Kuosa, K. Saari, A. Kankkunen, T.-M. Tveit • Nu vs. Re plot
Oscillating Flow in a Stirling Engine Heat Exchanger • Authors: M. Kuosa, K. Saari, A. Kankkunen, T.-M. Tveit • Results • The pressure losses and Nusselt numbers were examined to determine that designs which form thinner boundary layers along the length of heat exchanger tubes but do not significantly increase the dead volume space or pressure losses are recommended
Analytical Model for Predicting the Effect of Operating Speed on Shaft Power Output of Stirling Engines • Authors: Chin-Hsiang Cheng, Hang-Suin Yang
Analytical Model for Predicting the Effect of Operating Speed on Shaft Power Output of Stirling Engines • Authors: Chin-Hsiang Cheng, Hang-Suin Yang
Analytical Model for Predicting the Effect of Operating Speed on Shaft Power Output of Stirling Engines • Authors: Chin-Hsiang Cheng, Hang-Suin Yang
Analytical Model for Predicting the Effect of Operating Speed on Shaft Power Output of Stirling Engines • Authors: Chin-Hsiang Cheng, Hang-Suin Yang
Questions? References: M.C. Campos, J.V.C. Vargas, J.C. Ordonez, Thermodynamic optimization of a Stirling engine, Energy, Volume 44, Issue 1, August 2012, Pages 902-910, ISSN 0360-5442, 10.1016/j.energy.2012.04.060. IskanderTlili, Finite time thermodynamic evaluation of endoreversible Stirling heat engine at maximum power conditions, Renewable and Sustainable Energy Reviews, Volume 16, Issue 4, May 2012, Pages 2234-2241, ISSN 1364-0321, 10.1016/j.rser.2012.01.022. IskanderTlili, Thermodynamic Study on Optimal Solar Stirling Engine Cycle Taking Into Account the Irreversibilities Effects, Energy Procedia, Volume 14, 2012, Pages 584-591, ISSN 1876-6102, 10.1016/j.egypro.2011.12.979. M. Kuosa, K. Saari, A. Kankkunen, T.-M. Tveit, Oscillating flow in a stirling engine heat exchanger, Applied Thermal Engineering, Volumes 45–46, December 2012, Pages 15-23, ISSN 1359-4311, 10.1016/j.applthermaleng.2012.03.023. Chin-Hsiang Cheng, Hang-Suin Yang, Analytical model for predicting the effect of operating speed on shaft power output of Stirling engines, Energy, Volume 36, Issue 10, October 2011, Pages 5899-5908, ISSN 0360-5442, 10.1016/j.energy.2011.08.033.