Thermodynamic Calculation of a Rotary Engine with External Heat Supply Based on the Ideal Rallis Cycle

1. Walker G. Stirling cycle machines. Moscow: Energy; 1978. (In Russ.). Search in Google Scholar

2. Kruglov MG. Stirling Engines. Moscow: Machinery engineering; 1977. 150. (In Russ.). Search in Google Scholar

3. Myshinsky EL., Ryzhkov-Dudonov M.A. Marine piston external combustion engines (Stirling engines). Leningrad: Shipbuilding; 1976. 76. (In Russ.). Search in Google Scholar

4. Brodyansky VM. Stirling Engines: Collection of articles. Moscow: World; 1975. 446. (In Russ.). Search in Google Scholar

5. Campos MC., Vargas JVC., Ordonez JC. Thermodynamic optimization of a Stirling engine. Energy. 2012;44(1):902–910.10.1016/j.energy.2012.04.060 Search in Google Scholar

6. Chen D, Xinggang W, Shuiming S, Changwei J, Huawei C. Thermodynamic design of Stirling engine using multi-objective particle swarm optimization algorithm. Energy Conversion and Management. 2014;84:88–96.10.1016/j.enconman.2014.04.003 Search in Google Scholar

7. Somayeh T, Alibakhsh K, Mohammad HA. Multi-objective optimization of Stirling engine using non-ideal adiabatic method. Energy Conversion and Management. 2014;80:54–62.10.1016/j.enconman.2014.01.022 Search in Google Scholar

8. Khafizov CA., Usenkov RA., Khalyullin FK., Latypov RA. The thermodynamic calculation of offset shafts rotary engine ideal cycle with external heat supply. International Journal of Mechanical and Production Engineering Research and Development. 2019;9(4):1109–1116.10.24247/ijmperdaug2019114 Search in Google Scholar

9. Salem AAS, Erol K, Khaled MEH, Aybaba H. A numerical model for a Stirling engine. Journal of Energy Systems. 2018;2(1):1–12. DOI: 10.30521/jes.379164.10.30521/jes.379164 Search in Google Scholar

10. Paul R, Hoffmann KH. Cyclic Control Optimization Algorithm for Stirling Engines. Symmetry. 2021;13(873). DOI: 10.3390/sym13050873.10.3390/sym13050873 Search in Google Scholar

11. Uswatun H. Rahmatsyah. Eva M. Development of Stirling Engine Based Thermodynamics Tools. IOP Conf. Series: Journal of Physics: Conf. Series. 2020;1485. DOI: 10.1088/1742-6596/1485/1/012015.10.1088/1742-6596/1485/1/012015 Search in Google Scholar

12. Pratik S, Sumit R, Swapnil P, Nikhil P, Rajan P A Review on Stirling. Engine Performance. 2019;6(4):648–650. Search in Google Scholar

13. Ladas HG., Ibrahim OM. Finite-time view of Stirling engine. Energy. 1994;19(8):837–843.10.1016/0360-5442(94)90036-1 Search in Google Scholar

14. Wrona J, Prymon M. Mathematical Modelling of the Stirling engine. Procedia Engineering. 2016;157:349–356.10.1016/j.proeng.2016.08.376 Search in Google Scholar

15. Wandong Z,, Ruijie L, Hailing L, Ying Z, Songgang Q. Numerical analysis of fluid dynamics and thermodynamics in a Stirling engine. Applied Thermal Engineering. 2021;189;116727. DOI: 10.1016/j.applthermaleng.2021.116727.10.1016/j.applthermaleng.2021.116727 Search in Google Scholar

16. Podešva J, Poruba Z. The Stirling engine mechanism optimization. Perspectives in Science. 2015. DOI: 10.1016/j.pisc.2015.11.052.10.1016/j.pisc.2015.11.052 Search in Google Scholar

17. García MT, Trujillo EC, Godiño JAV, Martínez DS. Thermodynamic Model for Performance Analysis of a Stirling Engine Prototype Energies. 2018;11;2655. DOI: 10.3390/en11102655.10.3390/en11102655 Search in Google Scholar

18. Somayeh T, Alibakhsh K, Mohammad HA. Multi-objective optimization of Stirling engine using non-ideal adiabatic method. Energy Conversion and Management. 2014;80:54–62. DOI: 10.1016/j.enconman.2014.01.022.10.1016/j.enconman.2014.01.022 Search in Google Scholar

19. Engine with external heat supply. Patent 2319848 Rus. Federation. No. 2006118599/06. 2008;8. 8 p. (In Russ.). Search in Google Scholar

20. Rotary piston machine. Patent 2637301 Rus. Federation. No. 2016146956. 2017;34. 8 p. (In Russ.). Search in Google Scholar

21. Heat engine implementing the Rallis cycle. Patent 2637301 Rus. Federation. No. 2016146956. 2015;16. 7 p. (In Russ.). Search in Google Scholar