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Appl. Sci. 2020, 10, 6824 13 of 13 3. Kimball, K.J.; Clementoni, E.M. Supercritical carbon dioxide brayton power cycle development overview. In Proceedings of the Turbo Expo 2012, Copenhagen, Denmark, 11–15 June 2012. 4. Clementoni, E.M.; Cox, T.L.; King, M.A. Steady-State power operation of a supercritical carbon dioxide brayton cycle with thermal-hydraulic control. In Proceedings of the Turbo Expo 2016, Seoul, Korea, 13–17 June 2016. 5. Avadhanula, V.K.; Held, T.J. Transient Modeling of a Supercritical CO2 power Cycle and Comparison with Test Data. In Proceedings of the Turbo Expo 2017, Charlotte, NC, USA, 26–30 June 2017. 6. Seo, J.; Choi, W.; Lim, H.; Park, M.; Kim, D.; Lee, K.; Yoon, E. Development of a 250-kWe class supercritical carbon dioxide rankine cycle power generation system and its core components. In Proceedings of the Turbo Expo 2019, Phoenix, AZ, USA, 17–21 June 2019. 7. Sienicki, J.J.; Moisseytsev, A.; Fuller, R.L.; Wright, S.A.; Pickard, P.S. Scale dependencies of supercritical carbon dioxide Brayton cycle technologies and the optimal size for a next-step supercritical CO2 cycle demonstration. In Proceedings of the SCO2 Power Cycle Symposium, Boulder, CO, USA, 24–25 May 2011. 8. Kim, D.; Baik, S.; Lee, J. Investigation of magnetic journal bearing instability issues in supercritical CO2 turbomachinery. In Proceedings of the ASME-JSME-KSME 2019 Joint Fluids Engineering Conference 2019, San Francisco, CA, USA, 28 July 2019. 9. Rowe, W.B.; O’Donoghue, J.P.; Cameron, A. Optimisation of externally pressurized bearings for minimum power and low temperature. Tribol. Int. 1970, 3, 153–157. [CrossRef] 10. Singh, D.V.; Sinhasan, R.; Ghai, R.C. Static and dynamic analysis of capillary compensated hydrostatic journal bearings by finite element method. J. Lubr. Tech. 1977, 99, 478–484. [CrossRef] 11. Ghosh, M.K. Dynamic characteristic of multirecess externally pressurized oil journal bearing. J. Lub. Tech. 1978, 100, 467–471. [CrossRef] 12. Rowe, W.B. Dynamic and static properties of recessed hydrostatic journal bearings by small displacement analysis. J. Lub. Tech. 1980, 102, 71–79. [CrossRef] 13. Chen, Y.S.; Wu, H.Y.; Xie, P.L. Stability of multirecess hybrid-operating oil journal bearings. J. Lub. Tech. 1985, 107, 116–121. [CrossRef] 14. Rhode, S.M.; Ezzat, H.A. On the dynamic behavior of hybrid journal bearings. J. Lub. Tech. 1976, 98, 90–94. [CrossRef] 15. Ghosh, M.K.; Viswanath, N.S. Recess fluid compressibility effect on the dynamic characteristics of multirecess hydrostatic journal bearings with journal rotation. J. Tribol. 1987, 109, 417–426. [CrossRef] 16. Heller, S. Static and dynamic performance of externally pressurized fluid film journal bearings in the turbulent regime. J. Lub. Tech. 1974, 95, 381–399. [CrossRef] 17. Kim, S.; Kang, J.; Kim, K. A study on performance analysis of cryogenic hydrostatic journal bearings: The effects of turbulent flow, pressure drop and variable liquid properties. J. Korean Soc. Tribol. Lubr. Eng. 2003, 19, 139–145. 18. San, L. Andres approximate analysis of turbulent hybrid bearings. Static and dynamic performance for centered operation. J. Tribol. 1990, 112, 692–698. 19. Ghosh, M.K.; Satish, M.R. Rotordynamic characteristics of multilobe hybrid bearings with short sills-part I. Tribol. Int. 2003, 36, 625–632. [CrossRef] 20. Ghosh, M.K.; Satish, M.R. Stability of multilobe hybrid bearing with short sills-part II. Tribol. Int. 2003, 36, 633–636. [CrossRef] 21. Ren, T.; Feng, M. Stability analysis of water-lubricated journal bearings for fuel cell vehicle air compressor. Tribol. Int. 2016, 95, 342–348. [CrossRef] 22. Du, J.; Liang, G. Dynamic coefficients and stability analysis of a water-lubricated hydrostatic bearing by solving the uncoupled Reynolds equation. Chin. J. Aeronaut. 2019. [CrossRef] © 2020 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).PDF Image | Development of Pump-Drive Turbine Module Super CO2 Application
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