참고문헌 (27)

1. 10.1007/978-3-642-24653-1_11 

   

2. 10.1017/9781108241625 

   

3. Kost, C., Shammugam, S., Julch, V., Nguyen, H., and Schlegl, T., “Levelized Cost of Electricity Renewable Energy Technologies,” Fraunhofer Institute for Solar Energy Systems ISE, Vol. 144, 2013. 

4. U.S. Energy Information Administration, “Annual Energy Outlook 2019 with Projections to 2050,” https://www.eia.gov/outlooks/aeo/pdf/aeo2019.pdf (Accessed 13 APR 2020) 

5. Gonzalez-Salazar, Miguel Angel, Kirsten, Trevor, Prchlik, Lubos. Review of the operational flexibility and emissions of gas- and coal-fired power plants in a future with growing renewables. Renewable & sustainable energy reviews, vol.82, no.1, 1497-1513.

   상세보기

6. 10.2172/1060601 

   

7. Byfield, S. and Vetter, D., “Flexibility Concepts for the German Power Supply in 2050: Ensuring Stability in the Age of Renewable Energies,” Munchen: Acatech-Deutsche Akademie Der Technikwissenschaften, 2016. 

8. Fabiani, A., Adam, B., Barbel, E., Duncan, G., Bozhil, Ko., Angus, M., et al., “Renewables in Cities 2019 Global Status Report,” https://www.ren21.net/wp-content/uploads/2019/05/REC-2019-GSR_Full_Report_web.pdf (Accessed 12 MAR 2020) 

9. American Physical Society, “Integrating Renewable Electricity on the Grid: A Report by the APS Panel on Public Affairs,” https://www.aps.org/policy/reports/popa-reports/upload/integratingelec.pdf (Accessed 13 APR 2020) 

10. Bloch H. P., “Improving Machinery Reliability,” Material, 3rd Ed., 1998. 

11. Lee, A. S., “Rotor Dynamic Design Supervision for the Reliability of the Rotating Machinery,” Transactions of the Korean Society for Noise and Vibration Engineering, Vol. 8, No. 5, pp. 775-783, 1998. 

12. Kim, S. Y., Oh, G., Oh, G., Ahn, K., Cho, S., et al., “Conceptual Design of a Heavy Duty Gas Turbine Engine for Power Generation,” Korea Institute of Machinery and Materials, 1998. 

13. 10.1115/92-GT-273 

    

14. Bunker, R. S., “Cooling Design Analysis,” The Gas Turbine Handbook, pp. 296-308, 2006. 

15. 10.2514/6.2002-3790 

    

16. Peng, Kai, Fan, Ding, Yang, Fan, Fu, Qiang, Li, Yong. Active generalized predictive control of turbine tip clearance for aero-engines. Chinese journal of aeronautics, vol.26, no.5, 1147-1155.

    상세보기

17. Hershey, J. E., Osborn, B. E., Gardner, D. L., Ruiz, R. J., and Herron, W. L., “Aircraft Gas Turbine Engine Blade Tip Clearance Control,” US Patent, 8126628B2, 2012. 

18. Hagi, N., “Seal Active Clearance Control System for Gas Turbine Stationary Blade,” US Patent, 6152685A, 2000. 

19. Leach, D., Kellock, I. R., Plemmons, L. W., Chow, C., Sexton, B. F., et al., “Turbine Inner Shell Heating and Cooling Flow Circuit,” US Patent, 6422807B1, 2002. 

20. Ciokajlo, J. J. and Hauser, A. A., “Mechanical Blade Tip Clearance Control Apparatus for a Gas Turbine Engine,” US Patent, 5018942A, 1991. 

21. Reichert, A. and Becker, B., “Shaft Bearing for a Turbomachine, Turbomachine, and Method of Operating a Turbomachine,” US Patent, 20020009361A1, 2002. 

22. Stefan J. and Michael K, “Method for Operating a Rotary Machine.” US Patent, 9494046B2, 2016. 

23. Ceric, H., Duzic, A., and Pasqualino, S., “Lager Fur Die Axiale Lagerung Eines Laufers Einer Gas turbine,” EP Patent, 1627132B1, 2004. 

24. Ceric, H., Duzic, A., and Pasqualino, S., “Bearing for Axially Mounting a Rotor of a Gas Turbine, and Gas Turbine,” US Patent, 20070025839A1, 2007. 

25. Kim, Y. C., “Blade Tip Clearance Control Apparatus for Gas Turbine,” US Patent, 20190195081A1, 2019. 

26. Kim, Y. and Park, H., “Design of Gas Turbine Blade Tip Clearance Control Device Using Hydraulic Actuator,” Proc. of the Spring Conference of Korean Society of Propulsion Engineers, pp. 207-208, 2017. 

27. Kim. Y., “Design of the Control Device for Gas Turbine Blade Clearance with Multi-Step Axial Movement System of Robor,” Proc. of the Fall Conference of Korean Society for Precision Engineering, pp. 75-77, 2019.