| 1 |
Analysis of a displacer-coupled multi-stage thermoacoustic-Stirling engine
Hu JY, Luo EC, Zhang LM, Chen YY, Wu ZH, Gao B
Energy, 145, 507, 2018 |
| 2 |
New polytropic model to predict the performance of beta and gamma type Stirling engine
Li RJ, Grosu L, Li W
Energy, 128, 62, 2017 |
| 3 |
Modelling of pulse tube refrigerators with inertance tube and mass-spring feedback mechanism
Wang K, Dubey S, Choo FH, Duan F
Applied Energy, 171, 172, 2016 |
| 4 |
Displacer gap losses in beta and gamma Stirling engines
Mabrouk MT, Kheiri A, Feidt M
Energy, 72, 135, 2014 |
| 5 |
Numerical investigation on a thermoacoustic heat engine unit with a displacer
Zhang S, Wu ZH, Zhao RD, Dai W, Luo EC
Energy Conversion and Management, 85, 793, 2014 |
| 6 |
Nanoparticle surface modification by amphiphilic polymers in aqueous media: Role of polar organic solvents
Sarkar B, Venugopal V, Bodratti AM, Tsianou M, Alexandridis P
Journal of Colloid and Interface Science, 397, 1, 2013 |
| 7 |
The effect of displacer material on the performance of a low temperature differential Stirling engine
Cinar C, Aksoy F, Erol D
International Journal of Energy Research, 36(8), 911, 2012 |
| 8 |
Improved Stirling engine performance through displacer surface treatment
Karabulut H, Cinar C, Aksoy F, Yucesu HS
International Journal of Energy Research, 34(3), 275, 2010 |
| 9 |
Thermodynamic analysis of a beta type Stirling engine with a displacer driving mechanism by means of a lever
Karabulut H, Aksoy F, Ozturk E
Renewable Energy, 34(1), 202, 2009 |
| 10 |
Performance of a beta-configuration heat engine having a regenerative displacer
Eid E
Renewable Energy, 34(11), 2404, 2009 |
