An experimental study on the development of a β-type Stirling engine for low and moderate temperature heat sources H Karabulut, HS Yücesu, C Çınar, F Aksoy Applied Energy 86 (1), 68-73, 2009 | 144 | 2009 |
Torque and power characteristics of a helium charged Stirling engine with a lever controlled displacer driving mechanism H Karabulut, C Çınar, E Oztürk, HS Yücesu Renewable Energy 35 (1), 138-143, 2010 | 126 | 2010 |
Manufacturing and testing of a gamma type Stirling engine C Cinar, H Karabulut Renewable energy 30 (1), 57-66, 2005 | 120 | 2005 |
Dynamic analysis of a free piston Stirling engine working with closed and open thermodynamic cycles H Karabulut Renewable Energy 36 (6), 1704-1709, 2011 | 109 | 2011 |
Thermodynamic analysis of a β type Stirling engine with a displacer driving mechanism by means of a lever H Karabulut, F Aksoy, E Öztürk Renewable Energy 34 (1), 202-208, 2009 | 91 | 2009 |
Thermodynamic analysis of the V-type Stirling-cycle refrigerator ÖE Ataer, H Karabulut International Journal of Refrigeration 28 (2), 183-189, 2005 | 72 | 2005 |
Performance comparison of a novel configuration of beta-type Stirling engines with rhombic drive engine H Solmaz, H Karabulut Energy conversion and management 78, 627-633, 2014 | 63 | 2014 |
A thermodynamic approach to compare the performance of rhombic-drive and crank-drive mechanisms for a beta-type Stirling engine F Aksoy, H Solmaz, H Karabulut, C Cinar, YO Ozgoren, S Polat Applied Thermal Engineering 93, 359-367, 2016 | 59 | 2016 |
Manufacturing and testing of a V-type Stirling engine H Karabulut, HS Yucesu, A Koca Turkish Journal of Engineering and Environmental Sciences 24 (2), 71-80, 2000 | 59 | 2000 |
Thermal performance of a Stirling engine powered by a solar simulator F Aksoy, H Karabulut, C Çınar, H Solmaz, YÖ Özgören, A Uyumaz Applied Thermal Engineering 86, 161-167, 2015 | 52 | 2015 |
Nodal analysis of a Stirling engine with concentric piston and displacer H Karabulut, HS Yücesu, C Çinar Renewable Energy 31 (13), 2188-2197, 2006 | 48 | 2006 |
Thermodynamic and dynamic analysis of an alpha type Stirling engine and numerical treatment D Ipci, H Karabulut Energy Conversion and Management 169, 34-44, 2018 | 47 | 2018 |
Thermodynamic and dynamic analysis of an alpha type Stirling engine with Scotch Yoke mechanism M Altin, M Okur, D Ipci, S Halis, H Karabulut Energy 148, 855-865, 2018 | 44 | 2018 |
Performance testing of a Fresnel/Stirling micro solar energy conversion system F Aksoy, H Karabulut Energy Conversion and Management 75, 629-634, 2013 | 39 | 2013 |
Dynamic model of a two-cylinder four-stroke internal combustion engine and vibration treatment H Karabulut International Journal of Engine Research 13 (6), 616-627, 2012 | 37 | 2012 |
Thermodynamic and dynamic modeling of a single cylinder four stroke diesel engine D Ipci, H Karabulut Applied Mathematical Modelling 40 (5-6), 3925-3937, 2016 | 34 | 2016 |
Performance prediction of a Martini type of Stirling engine H Karabulut, M Okur, AO Ozdemir Energy Conversion and Management 179, 1-12, 2019 | 29 | 2019 |
Construction and testing of a dish/Stirling solar energy unit H Karabulut, HS Yucesu, C Cinar, F Aksoy Journal of the Energy Institute 82 (4), 228-232, 2009 | 28 | 2009 |
1.2 kW beta type Stirling engine with rhombic drive mechanism F Aksoy, H Solmaz, C Çinar, H Karabulut International Journal of Energy Research 41 (9), 1310-1321, 2017 | 27 | 2017 |
Thermodynamic, dynamic and flow friction analysis of a Stirling engine with Scotch yoke piston driving mechanism H Karabulut, M Okur, S Halis, M Altin Energy 168, 169-181, 2019 | 26 | 2019 |