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Part III - Extras

Published online by Cambridge University Press:  15 February 2019

S. Can Gülen
Affiliation:
Bechtel Infrastructure and Power, Inc.
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Print publication year: 2019

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References

References

Fitzgerald, A.E., Kingsley, Jr., Kusko, C., A., Electric Machinery, 3rd edition (New York: McGraw Hill Book Co., 1971).Google Scholar
Stevenson, W.D. Jr., Elements of Power System Analysis, 3rd edition (New York: McGraw Hill Book Co., 1975).Google Scholar
Kundur, P., Power System Stability and Control. The EPRI Power System Engineering Series (New York: McGraw Hill Book Co., 1994).Google Scholar
Grigsby, L.L., The Electric Power Engineering Handbook (Boca Raton, FL: CRC Press, 2001).Google Scholar
General Electric Company, “LS2100 Static Starter Product Description,” GE Industrial Systems Document GEI-100539, 2002.Google Scholar
Baker, T.E., Electrical Calculations and Guidelines for Generating Stations and Industrial Plants (Boca Raton, FL: CRC Press, 2012).Google Scholar

References

Forty, G., German Tanks of World War Two in Action (London, UK: Blanford Press, 1988).Google Scholar
Chivers, C. J., The Gun (New York: Simon & Schuster, 2011).Google Scholar
Della Villa, S. A. Jr., Koeneke, C., “A Historical and Current Perspective of the Availability and Reliability Performance of Heavy-Duty Gas Turbines: Benchmarks and Expectations,” GT2010-23182, ASME Turbo Expo 2010, June 14–18, 2010, Glasgow, UK.CrossRefGoogle Scholar
Steele, R. F. Jr., Paul, D. C., Rui, T., “Expectations and Recent Experience for Gas Turbine Reliability, Availability, and Maintainability (RAM),” GT2007–27655, ASME Turbo Expo 2007, May 14–17, 2007, Montreal, QC, Canada.Google Scholar
Grace, D., Christiansen, T., “Risk Based Assessment of Unplanned Outage Events and Costs for Combined Cycle Plants,” GT2012-68435, ASME Turbo Expo 2012, June 11–15, 2012, Copenhagen, Denmark.Google Scholar
“Common Causes of Large Losses in Global Power Industry,” A Report by Marsh Risk Management Research, Marsh & McLennan Companies, New York, 2013.Google Scholar
Orme, G. J., Venturi, M., “Property Risk Assessment for Combined Cycle Power Plants,” ASME Turbo Expo 2008, June 9–13, 2008, Berlin, Germany.Google Scholar
Orme, G. J., Venturi, M., “Prediction of Power Plant Exposure to Economic Losses through A Property Risk Assessment Methodology,” GT2009-59018, ASME Turbo Expo 2009, June 8–12, 2009, Orlando, FL.Google Scholar
Nagy, D., Savic, S., “Alternative Gas Turbine Maintenance Concepts by Independent Service Providers,” Powergen International 2015, December 8–10, 2015, Las Vegas, NV.Google Scholar
Meher-Homji, C. B., Chaker, M., Bromley, A. W., “The Fouling of Axial Compressors – Causes, Effects, Susceptibility and Sensitivity,” GT2009-59239, ASME Turbo Expo 2009, June 8–12, 2009, Orlando, FL.CrossRefGoogle Scholar
Grace, D., Perullo, C., Lieuwen, T., How to Select the Optimal Inlet Air Filters for Your Engine, Combined Cycle Journal, 53 (2017).Google Scholar
Gülen, S. C., Smith, R. W., A Simple Mathematical Approach to Data Reconciliation in a Single-Shaft Combined Cycle System, Journal of Engineering for Gas Turbines and Power, 131 (2009), 021601.CrossRefGoogle Scholar
Gülen, S. C., Griffin, P. R., Paolucci, S., Real-Time On-Line Performance Diagnostics of Heavy Duty Industrial Gas Turbines, Journal of Engineering for Gas Turbines and Power, 124 (2002), 910921.Google Scholar
Lifson, A., Quentin, G. H., Smalley, A. J., Knauf, C. L., Assessment of Gas Turbine Vibration Monitoring, Journal of Engineering for Gas Turbines and Power, 111 (1989), 257263.Google Scholar
Fletcher, D., Willey, D., Hayton, M., Tiger Tank – Owner’s Workshop Manual (Minneapolis, MN: Zenith Press, 2011).Google Scholar

References

Gülen, S. C., Étude on Gas Turbine Combined Cycle Power Plant – Next 20 Years, Journal of Engineering for Gas Turbines and Power, 138 (2016), 051701.Google Scholar
Kehlhofer, R., Rukes, B., Hannemann, F., Stirnimann, F., Combined-Cycle Gas and Steam Turbine Power Plants, 3rd edition (Tulsa, OK: PennWell Corp., 2009).Google Scholar
Horlock, J. H., Combined Power Plants: Including Combined Cycle Gas Turbine (CCGT) Plants (Oxford, UK: Pergamon Press Ltd., 1992).Google Scholar
HRSG Users Handbook: Design, Operation, Maintenance (Bozeman, MT: HRSG User’s Group, 2006).Google Scholar
Sanders, W. P., Turbine Steam Path Maintenance and Repair, Volumes 1–3 (Tulsa, OK: PennWell Corp., 2001).Google Scholar
Leyzerovich, A., Large Power Steam Turbines: Design and Operation, Volumes 1–2 (Tulsa, OK: PennWell Corp., 1997).Google Scholar
Smith, R. W., “Steam Turbine Cycles and Cycle Design Optimization: Combined Cycle Power Plants,” in Advances in Turbines for Modern Power Plants, Ed. Tanuma, T. (Duxford, UK: Woodhead Publishing, 2017).Google Scholar
Gülen, S. C., Smith, R. W., Second Law Efficiency of the Rankine Bottoming Cycle of a Combined Cycle Power Plant, Journal of Engineering for Gas Turbines and Power, 132 (2010), 011801.CrossRefGoogle Scholar
Chin, W. W., El-Masri, M. A., Exergy Analysis of Combined Cycles: Part 2 – Analysis and Optimization of Two-Pressure Steam Bottoming Cycles, Journal of Engineering for Gas Turbines and Power, 109 (1987), 237243.Google Scholar
Horlock, J. H. et al., Exergy Analysis of Modern Fossil-Fuel Power Plants, Journal of Engineering for Gas Turbines and Power, 122 (2000), 17.Google Scholar
Patterson, J. R., Walsh, E. J., “A Manufacturer’s Role in Heavy-Duty Gas Turbine Future Technology,” ASME Paper 83-TOKYO-IGTC-118, 1983 Tokyo International Gas Turbine Congress, October 23–29, 1983, Tokyo, Japan.Google Scholar
Rice, I., The Reheat Gas Turbine with Steam-Blade Cooling – A Means of Increasing Reheat Pressure, Output, and Combined Cycle Efficiency, Journal of Engineering for Gas Turbines and Power, 104: 1 (1982), 922.Google Scholar

References

Jansen, M., Schulenberg, T., Waldinger, D., Shop Test Result of the V64.3 Gas Turbine, ASME Journal of Engineering for Power, 114 (1992), 676681.Google Scholar
Gülen, S. C., Joseph, J., Combined Cycle Off-Design Performance Estimation: A Second-Law Perspective, ASME Journal of Engineering for Gas Turbines and Power, 134 (2011), 011801.Google Scholar
Chaker, M., Meher-Homji, C. M., Evaporative Cooling of Gas Turbine Engines, ASME Journal of Engineering for Gas Turbines and Power, 135: 8 (2013), 081901.Google Scholar
Chaker, M., Meher-Homji, C. M., Selection of Climatic Design Points for Gas Turbine Power Augmentation, ASME Journal of Engineering for Gas Turbines and Power, 134: 4 (2012), 042001.CrossRefGoogle Scholar
Bhargava, R. K., Meher-Homji, C. B., Chaker, M. A., Bianchi, M., Melino, F., Peretto, A., Ingistov, S., Gas Turbine Fogging Technology: A State-of-the-Art Review – Part I: Inlet Evaporative Fogging – Analytical and Experimental Aspects, ASME Journal of Engineering for Gas Turbines and Power, 129 (2006), 443453.Google Scholar
Bhargava, R. K., Meher-Homji, C. B., Chaker, M. A., Bianchi, M., Melino, F., Peretto, A., Ingistov, S., Gas Turbine Fogging Technology: A State-of-the-Art Review – Part II: Overspray Fogging – Analytical and Experimental Aspects, ASME Journal of Engineering for Gas Turbines and Power, 129 (2006), 454460.Google Scholar
Bhargava, R. K., Meher-Homji, C. B., Chaker, M. A., Bianchi, M., Melino, F., Peretto, A., Ingistov, S., Gas Turbine Fogging Technology: A State-of-the-Art Review – Part III: Practical Considerations and Operational Experience, ASME Journal of Engineering for Gas Turbines and Power, 129 (2006), 461472.Google Scholar
Ondryas, I. S., Wilson, D. A., Kawamoto, M., Haub, G. L., Options in Gas Turbine Power Augmentation Using Inlet Air Chilling, ASME Journal of Engineering for Gas Turbines and Power, 113: 2 (1991), 203211.Google Scholar
Cortes, C., Willems, D., “Gas Turbine Inlet Air Cooling Techniques: An Overview of Current Technologies,” POWERGEN 2003, December 9–11, 2003, Las Vegas, NV.Google Scholar
McGuigan, P., Why Keeping Cool Keeps Output High, Power Engineering, 122: 2 (2018), 3844.Google Scholar
Nuding, J.-R., Johnke, T., “Increasing GT Power and Efficiency through Wet Compression,” POWERGEN 2002, 11–13 June, 2002, Milan, Italy.Google Scholar
Hoffmann, J., Agostinelli, G.-L., “High Fogging Commissioning Test in the Alstom Test Center Birr (Switzerland),” POWERGEN 2002, 11–13 June, 2002, Milan, Italy.Google Scholar
Lecheler, S., Hoffmann, J., “The Power of Water in Gas Turbines: Alstom’s Experience with Air Inlet Cooling,” POWERGEN Latin America 2003, November 11–13, 2003, Sao Paolo, Brazil.Google Scholar
Jolly, S., Cloyd, S., “Performance Enhancement of GT24 with Wet Compression,” POWERGEN International 2003, December 9–11, 2003, Las Vegas, NV.Google Scholar
Johnson, D., Miller, R. W., Ashley, T., “Speedtronic™ Mark V Gas Turbine Control System,” GER-3658E, 39th GE Turbine State-of-the-Art Technology Seminar, 1994.Google Scholar
Rowen, W. I., “Operating Characteristics of Heavy-Duty Gas Turbines in Utility Service,” ASME Paper No. 88-GT-150, ASME Gas Turbine and Aeroengine Congress, June 6–9, 1988, Amsterdam, The Netherlands.Google Scholar
Mendoza, E., Lin, T., Jiang, X., “Reduction of Gas Turbine Exhaust Temperature Limit Due to HRSG Limitations by Change on Control Curve to Optimize Plant Operation and Performance,” ASME Paper GT2015-43784, ASME Turbo Expo 2015, June 15–19, 2015, Montreal, QC, Canada.CrossRefGoogle Scholar

References

Gülen, S. C., Kim, K., Gas Turbine Combined Cycle Dynamic Simulation: A Physics Based Simple Approach, Journal of Engineering for Gas Turbines and Power, 136 (2014), 011601.Google Scholar
Rowen, W. I., Simplified Mathematical Representations of Heavy-Duty Gas Turbines, ASME Journal of Engineering for Power, 105 (1983), 865869.Google Scholar
Rowen, W. I., “Simplified Mathematical Representations of Single-Shaft Gas Turbines in Mechanical Drive Service,” ASME Paper 92-GT-22, ASME International Gas Turbine and Aeroengine Congress and Exposition, June 1–4, 1992, Köln, Germany.CrossRefGoogle Scholar
Yee, S. K., Milanovic, J. V., Hughes, F. M., Overview and Comparative Analysis of Gas Turbine Models for System Stability Studies, IEEE Transactions on Power Systems, 23: 1 (2008), 108118.Google Scholar
De Mello, F. P., Ahner, D. J., Dynamic Models for Combined Cycle Plants in Power System Studies, IEEE Transactions on Power Systems, 9: 3 (1994), 16981708.Google Scholar
Hannett, L. N., Khan, A., Combustion Turbine Dynamic Model Validation from Tests, IEEE Transactions on Power Systems, 98: 1 (1993), 152158.CrossRefGoogle Scholar
Hannett, L. N., Feltes, J. W., “Testing and Model Validation for Combined Cycle Power Plants,” IEEE Power Engineering Society Winter Meeting, January 28–February 1, 2001, Columbus, OH.Google Scholar
Kundur, P., Power System Stability and Control (New York: McGraw-Hill, Inc., 1994).Google Scholar
Incropera, F. P., Dewitt, D. P., Introduction to Heat Transfer, 4th edition (New York: John Wiley & Sons, Inc., 2002).Google Scholar
Özışık, N., Conduction Heat Transfer (New York: John Wiley & Sons, Inc., 1988).Google Scholar
Gülen, S. C., Jones, C. M., “GE’s Next Generation CCGT Plants: Operational Flexibility Is the Key,” Modern Power Systems, June 2011, pp. 16–18.Google Scholar
Diegel, D. et al., “Fullfillment of Grid Code Requirements in the Area Served by UCTE by Combined Cycle Power Plants,” POWER-GEN Europe 2004, May 25–27, 2004, Barcelona, Spain.Google Scholar

References

“Cost Estimation Methodology for NETL Assessments of Power Plant Performance,” US DOE Report DOE/NETL-2011/1455, April 2011.Google Scholar
Bejan, A., Tsatsaronis, M. M., Thermal Design & Optimization (New York: John Wiley & Sons, 1996).Google Scholar
Peters, M. S., Timmerhaus, K. D., West, R. E., Plant Design and Economics for Chemical Engineers, 5th edition (New York: McGraw Hill, Inc., 2004).Google Scholar
“Updated Capital Cost Estimates for Utility Scale Electricity Generating Plants,” US Energy Information Administration, April 2013, Washington, DC.Google Scholar
Gülen, S. C., Mazumder, I., An Expanded Cost of Electricity Model for Highly Flexible Power Plants, Journal of Engineering for Gas Turbines and Power, 135 (2013), 011801.Google Scholar
Balevic, D., Burger, R., Forry, D., “Heavy-Duty Gas Turbine Operating and Maintenance Considerations,” GER-3620K, GE Energy, 2004.Google Scholar
Nagy, D., Savic, S., “Alternative Gas Turbine Maintenance Concepts by Independent Service Providers,” Powergen International 2015, December 8–10, 2015, Las Vegas, NV.Google Scholar
US Energy Information Administration, “Annual Energy Outlook 2010,” December 2009, DOE/EIA-0383, 2009.Google Scholar
Maize, K., Peltier, R., “The U.S. Gas Rebound,” POWER, January 2010, pp. 20–31.Google Scholar
Carrino, A. J., Jones, R. B., “Coal Plants Challenged as Gas Plants Surge,” POWER, January 2011, pp. 47–49.Google Scholar
Cox, J., “Implications of Intermittency,” Modern Power Systems, January 2010, pp. 22–23.Google Scholar
Peltier, R., “Flexible Turbine Operation Is Vital for a Robust Grid,” POWER, September 2010, pp. 50–54.Google Scholar
Husak, M., Jones, C., Tegel, D., “Combined Cycle Plant Operational Flexibility,” POWER-GEN International 2006, November 28–30, 2006, Orlando, FL.Google Scholar
DellaVilla, S., Koeneke, C., “A Historical and Current Perspective of the Availability and Reliability Performance of Heavy Duty Gas Turbines: Benchmarks and Expectations,” GT2010-23182, ASME Turbo Expo 2010, June 14–18, 2010, Glasgow, UK.Google Scholar
Diakunchak, I. S., Performance Deterioration in Industrial Gas Turbines, Journal of Engineering for Gas Turbines and Power, 114 (1992), 161168.Google Scholar
Marsh, W. D., Economics of Electric Power Utility Power Generation (New York: Oxford University Press, 1980).Google Scholar
Gülen, S. C., “A More Accurate Way to Calculate the Cost of Electricity,” POWER, June 2011, pp. 62–65.Google Scholar
Gülen, S. C., “What Is the Worth of 1 Btu/kWh of Heat Rate?” POWER, June 2013, pp. 60–63.Google Scholar
Mun, J., Real Options Analysis: Tools and Techniques for Valuing Strategic Investment and Decisions, 2nd edition (Hoboken, NJ: John Wiley & Sons, Inc., 2005).Google Scholar

References

Matta, R. K. et al., “Power Systems for the 21st Century – ‘H’ Gas Turbine Combined-Cycles,” GER-3935B, 2000.Google Scholar
Pritchard, J. E., “H-System™ Technology Update,” ASME Paper GT2003-38711, ASME Turbo Expo 2003, June 16–19, 2003, Atlanta, GA.Google Scholar
Schilke, P. W., “Advanced Gas Turbine Materials and Coatings,” GER-3569G, 2004.Google Scholar
Probert, T., “Exelon Will Be First to Debut GE’s New 7HA.02 Gas Turbine,” Gas Turbine World, September–October 2014, pp. 14–19.Google Scholar
Tsutsumi, A. et al., Description of the Latest Combined Cycle Power Plant with G type Gas Turbine Technology in the Philippines, Mitsubishi Heavy Industries Technical Review, 40: 4 (2003), 15.Google Scholar
Koeneke, C., Steam Cooling of Large Frame Gas Turbines One Decade in Operation, VDI-Berichte, 1965 (2006), 3342.Google Scholar
Yuri, M. et al., Operating Results of J-series Gas Turbine and Development of JAC, Mitsubishi Heavy Industries Technical Review 54: 3 (2017), 1622.Google Scholar
Ruedel, U. et al., “Development of the New Ansaldo Energia Gas Turbine Technology Generation,” ASME Paper GT2017-64893, ASME Turbo Expo 2017, June 26–30, 2017, Charlotte, NC.Google Scholar
Meier, P., “Validierung einer neuartigen, sauberen, und hocheffizienten Verbrennungstechnologie,” Final Report, BFE-Vertragsnummer SI/501154-01, Ansaldo Energia, 2017.Google Scholar
Brown-Boveri Company, BBC Publication No. D GK 1274 86 E, “Operating Experience with the Huntorf Air Storage Gas Turbine Power Station,” 1979.Google Scholar
Brown-Boveri Company, BBC Publication No. D GK 90202 E, “Huntorf Air Storage Gas Turbine Power Plant,” 1979.Google Scholar
Nakhamkin, M. et al., “Compressed Air Energy Storage: Plant Integration, Turbomachinery Development,” ASME Paper 85-IGT-4, 1985.Google Scholar
Gülen, S. C., “General Electric – Alstom merger brings visions of the Überturbine,” Gas Turbine World, July/August 2014, pp. 28–35.Google Scholar
Rice, I. G., The Reheat Gas Turbine with Steam-Blade Cooling – A Means of Increasing Reheat Pressure, Output, and Combined Cycle Efficiency, Journal of Engineering for Gas Turbines and Power, 104: 1 (1982), 922.Google Scholar

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  • Extras
  • S. Can Gülen
  • Book: Gas Turbines for Electric Power Generation
  • Online publication: 15 February 2019
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  • Extras
  • S. Can Gülen
  • Book: Gas Turbines for Electric Power Generation
  • Online publication: 15 February 2019
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  • Extras
  • S. Can Gülen
  • Book: Gas Turbines for Electric Power Generation
  • Online publication: 15 February 2019
Available formats
×