BWK 51 (1999), Nr. 11/12 Gasturbinenmarkt 1. M.Perkavec, R.
Transcription
BWK 51 (1999), Nr. 11/12 Gasturbinenmarkt 1. M.Perkavec, R.
BWK 51 (1999), Nr. 11/12 Gasturbinenmarkt 1. 2. M.Perkavec, R.-G.Schmidt: Gasturbinen, Jahresübersicht 1996, BWK, 4 / 1997. Turbomachinery International Handbook 1998 Projekte und Anlagen 3. 4. 5. 6. 7. 8. 9. Chellini, R.: Successful IPPs in Malaysia; Diesel & Gas Turbine Worldwide 1-2 1998, S. 60-61. Mullins, P.: Gas Turbine Power for Banff FPSO; Diesel & Gas Turbine Worldwide 4 1998, S. 8. Mullins, P.: Compressor Package for U.K. Gas Terminal; Diesel & Gas Turbine Worldwide 6 1998, S. 1819. Chellini, R.: Malpensa 2000 Cogeneration Plant; Diesel & Gas Turbine Worldwide 6 1998, S. 30-31. Chellini, R.: Paguthan Plant on Schedule; Diesel & Gas Turbine Worldwide 10 1998, S. 12-13. Hönings, N.: Das Gasturbinenprojekt Obernburg - Konzept, Contracting-Modell, Realisierung und Betriebserfahrungen. VGB Kraftwerkstechnik 78 (1998) 7, S. 37-43. Llagostera, J.: Power Generation Possibilities in the State of Sao Paulo, Brazil. ASME 98-GT-447. Uprates und Updates 10. Chellini, R.: Staying Competitive with Gas Turbine Uprates; Diesel & Gas Turbine Worldwide 1-2 1998, S. 48-50. 11. Chambers, H. A.: Rolls-Royce Allison 501K Industrial Engine Product Improvement, Power-Gen International 1998, 2.B.4. 12. Boley, W. M.: The Pratt & Whitney Gas Turbine Product Line, Power-Gen International 1998, 2.B.2. 13. Wikner, J.: ABB Gas Turbine Technology Update, 5-50 MW GT Size, Power-Gen International 1998, 2.B.5. 14. Chellini, R.: Modernizing the MS5002D Gas Turbine; Diesel & Gas Turbine Worldwide 4 1998, S. 12-14. 15. Chellini, R.: ABB’s GT8C2 Gas Turbine; Diesel & Gas Turbine Worldwide 4 1998, S. 40-43. 16. Chellini, R.: ABB Uprates GT10 Gas Turbine; Diesel & Gas Turbine Worldwide 7-8 1998, S. 54-55. 17. Schneider, Ch.: Gas Turbine Uprating Programme Development and Testing of the GT11NM. ASME 98GT-219. 18. Fischer, W.: GUD 1S.64.3A - die optimierte Einwellenanlage in der 100 MW Klasse; VDI Berichte Nr. 1438 (1998), S. 63-77. Neue Modelle 19. Chellini, R.: Solar Introduces Mercury 50 Advance Turbine System; Diesel & Gas Turbine Worldwide 1-2 1998, S. 34-37. 20. Rocha, G.: Evolution of the Solar Turbines Titan 130 Industrial Gas Turbine. ASME 98-GT-590. 21. Wadman, B.: First Two-Shaft Titan 130 Shipped; Diesel & Gas Worldwide 7-8 1998, S. 62-63. 22. -: Sales Agreement, Engine Test Results Mark Developments at AlliedSignal; Diesel & Gas Turbine Worldwide 7-8 1998, S. 65-67. 23. Chellini, R.: New Gas Turbine from Nuovo Pignone; Diesel & Gas Turbine Worldwide 1-2 1998, S. 1214. 24. Johnson, P.: First Cooper Rolls Allison Package Unveiled; Diesel & Gas Turbine Worldwide 4 1998, S. 58-61. 25. Mullins, P.: Coberra 6761 Gas Turbine Introduced; Diesel & Gas Turbine Worldwide 6 1998, S. 35-37. 26. Wilson, J. M.: A New High Efficiency Gas Turbine for Mechanical Drives. ASME 98-GT-535. Analysen 27. Negri di Montenegro, G.: Comparative Thermoeconomic Analysis between Combined Cycle Units Derived from Existing Steam Power Plants and a New Combined Cycle Plant. ASME 98-GT-197. 28. Anthony, R.: GEs LM6000: The Answer for Deregulated Power Markets, Power-Gen International 1998, 2.B.3. 29. Mader, O.: Heavy-duty- oder aeroderivative Gasturbinen? Eine Gegenüberstellung.VGB Kraftwerkstechnik 78 (1998) 6, S. 42-48. Gasturbinentechnik Technik für das 21.Jahrhundert 30. Mukherjee, D.-K.: Stand der Gasturbinentechnik. Gas, Wasser, Abwasser, 78/1998, 2, S. 84-91. 31. van der Linden, S.: Combustion Turbines and Cycles for the New Millennium, Power-Gen International 1998, 2.A.2. 32. Layne, A. W.: Advanced Turbine Systems for the 21st Century, Power-Gen International 1998, 2.A.5. 33. Lowe, E.: Powering the Next Century, Power-Gen International 1998, 2.A.1. 34. Perkavec, M.: Entwicklungstendenzen im Gasturbinenbau; BWK 50 (1998) 4, S. 114-119. 35. Wolf, J., Perkavec, M.: Neueste Entwicklungen im Gasturbinenbau; VDI Berichte Nr. 1438 (1998), S. 1124. Entwicklungsprogramme 36. Layne, A. W.: The U.S. Department of Energy’s Advanced Turbine Systems Program. ASME 98-GT141. 37. Geipel, H.: Verbundforschung zur Hochtemperatur-Gasturbine. VGB Kraftwerkstechnik 78 (1998) 11, S. 33-44. 38. Gabrielsson, R.: Status of the European Gas Turbine Program - AGATA. ASME 98-GT-392. 39. Diakunchak, I. S.: Status of Westinghouse’s Advanced Turbine Systems Program. ASME 98-GT-077. 40. McQuiggan, G.: An Evolutionary Approach to the Development of New Advanced Technology Gas Turbines. ASME 98-GT-223. 41. -:Turbine Tech 98 - Reports from Gas Turbine Manufacturers on the Latest Advancements in the Design and Application of Gas Turbine Engine Systems; Diesel & Gas Turbine Worldwide 6 1998, S. 46-74. 42. Susta, M. R.: Compatibility of Advanced Power Generation Technologies with the Independent Power Production. ASME 98-GT-222. 43. Ali, Sy A.: Renewable Fuels Turbine Project. ASME 98-GT-295. 44. Rooth, R. A.: Does User-Oriented Gas Turbine Research Pay Off? ASME 98-GT-429. Kleine Gasturbinen 45. Jones, M.: Small Gas Turbines Outlook, Power-Gen International 1998, 2.B.1. 46. Haller, B. R.: Advances in Gas Turbines of Lower Power; VDI Berichte Nr. 1438 (1998), S. 25-48. 47. Carnö, J.: Micro Gas Turbine for Combined Heat and Power in Distributed Generation. ASME 98-GT309. Testen und Betriebserfahrungen 48. Radeklint, U. R.: A New Test Facility for Testing of Cooled Gasturbine Components. ASME 98-GT-557. 49. Chellini, R.: V64.3A Finishes Gas Test Program; Diesel & Gas Turbine Worldwide 1-2 1998, S. 24-25. 50. Becker, B.: Betriebserfahrungen mit der V94.3A-Gasturbine. VGB Kraftwerkstechnik 78 (1998) 9, S. 6062. 51. Parece, N.: Construction, Startup, Commissioning and Testing of a 240 MW Gas Turbine Spinning Reserve Power Plant, Cambalache, Puerto Rico. ASME 98-GT-307 52. Kiesow, H.-J.: The ABB GT26 family-field experience; VDI Berichte Nr. 1438 (1998), S.1-10 53. Termuehlen, H.: Advanced Gas Turbine Operating Experience With Dry Low Nox Combustion, PowerGen International 1998, 2.A.3. 54. Homley, B.: Development and Early Field Experience of the Tempest Gas Turbine. Power-Gen Europe 98. 55. Nilsson, J. C.: The GT140P-Machine is Extensively Tested for Commercial Application. ASME 98-GT121. 56. Masanori Yuri: Technical Features and Operating Experience of Mitsubishi Advanced 501G Gas Turbine, Power-Gen International 1998, 2.A.4. 57. Kim, S. Y.: Performance Analysis of a 50KW Turbogenerator Gas Turbine Engine. ASME 98-GT-209. Studien und Parametrische Studien 58. Bernstein, W.: Einfluß der Gastemperaturen vor der Turbine auf Lebensdauer und Schadstoffemission Untersuchungen an Originalmaschinen zur Bauteillebensdauer und zur Emissionsminderung durch Vormischbetrieb und Wassereinspritzung. VGB Kraftwerkstechnik 78 (1998) 10, S. 104-110. 59. Reichert, A. W.: Steigerungen der Leistungsdaten von Großgasturbinen durch Optimierung des Sekundärluftsystems; VDI Berichte Nr. 1438 (1998), S. 221-228. 60. Owen, A. K.: A Parametric Starting Study of an Axial-Centrifugal Gas Turbine Engine Using a OneDimensional Dynamic Engine Model and Comparisons to Experimental Results Part 1: Model Development and Facility Description. ASME 98-GT-470. 61. Owen, A. K.: A Parametric Starting Study of an Axial-Centrifugal Gas Turbine Engine Using a OneDimensional Dynamic Engine Model and Comparisons to Experimental Results Part 2: Simulation Calibration and Trade-Off Study. ASME 98-GT-471. 62. Tarabrin, A. P.: Influence of Axial Compressor Fouling on Gas Turbine Unit Performance Based on Different Schemes and With Different Initial Parameters. ASME 98-GT-416. 63. Corti, A.: Exergy Analysis of Two Second-Generation SCGT Plant Proposals. ASME 98-GT-144. 64. Korakianitis, T.: Off-Design Performance of Various Gas-Turbine Cycle and Shaft Configurations. ASME 98-GT-386. 65. Neto, A. C.: An Exergy Analysis of Novel Power Generation Systems. ASME 98-GT-290. 66. Miller, H.: Engineering Gas Turbines for Best Value over Time. Power-Gen Europe 98. 67. Volponi, A. J.: Gas Turbine Parameter Corrections. ASME 98-GT-347. 68. Egorov, I. N.: The Technology of Multipurpose Optimization of Gas-Turbine Engines and Their Components. ASME 98-GT-512. 69. Luby, P.: Power Generation Technological Determinants for Fuel Scenario Outlook. ASME 98-GT-221. 70. Barbeau, D. E.: "Fast CE" A Radical Approach to Concurrent Engineering. ASME 98-GT-354. 71. Demouzon, F.: Cost Reduction through Digital Mock-up. ASME 98-GT-262. 72. Manfrida, G.: A Thermo-Economic Evaluation of the SCGT Cycle. Power-Gen Europe 98. Diverses 73. Moritz, R. R.: Near Term Gas Turbine Program to Enable the Use of "Renewable" Fuels. ASME 98-GT271. 74. Bannister, R. L.: Preliminary Assessment of Advanced Gas Turbines for CVX. ASME 98-GT-278. 75. Giovondo, C.-A.: Capacity quest leads KCP&L to advanced gas turbine. Kapazitätserhöhung durch eine hocheffektive Gasturbine im Hawthorn-Kraftwerk der KCP&L. Power, 142/1998, 1, S. 34-36. 76. Rakhit, A. K.: Characteristics of Low Frequency Non-Synchronous Vibrations Induced by an Epicyclic Gearbox in Gas Turbogenerator Applications. ASME 98-GT-333. 77. Russom, D. M.: Investigating and Resolving Accessory Gearbox Failures on Allison 501-K Series Engines. ASME 98-GT-281. Verdichter 78. Servaty, S.: Turboverdichter-Forschung in der AG Turbo; VDI Berichte Nr. 1425 (1998), S. 7-30. 79. Kmecl, T.: Turboverdichter: Mögliche Potentiale zur Energieeinsparung; BWK 50 (1998) 9, S. 44-46. 80. Stringham, G. D.: Design and Development of a Nine Stage Axial Flow Compressor for Industrial Gas Turbines. ASME 98-GT-140. 81. Kerrebrock, J. L.: A Family of Designs for Aspirated Compressors. ASME 98-GT-196. 82. Hah, C.: Control of Shock Structure and Secondary Flow Field inside Transonic Compressor Rotors through Aerodynamic Sweep. ASME 98-GT-561. CFD Anwendungen 83. Casey, M.: CFD Applications in Turbocompressors; VDI Berichte Nr. 1425 (1998), S. 31-42. 84. Dunham, J.: An AGARD Working Group Study of 3D Navier-Stokes Codes Applied to Single Turbomachinery Blade Rows. ASME 98-GT-050. 85. Elmendorf, W.: Three-Dimensional Analysis of a Multistage Compressor Flow Field. ASME 98-GT-249. 86. Gannon, A. J.: A Comparison of the Streamline Throughflow and Streamline Curvature Methods for Axial Turbomachinery. ASME 98-GT-048. 87. Baralon, St.: Validation of a Throughflow Time-Marching Finite-Volume Solver for Transonic Compressors. ASME 98-GT-047. 88. Buchanan, C. R.: Analysis of Aspect Ratio Effects on Transonic Rotor Performance Using a 3D Viscous Solver. ASME 98-GT-250. 89. Ozturk, H. K.: A Three Dimensional Computational Study of Windage Heating within an Axial Compressor Stator Well. ASME 98-GT-119. 90. Arima, T.: Computation of Subsonic and Transonic Compressor Rotor Flow Taking Account of Reynolds Stress Anisotropy. ASME 98-GT-423. 91. Issa, R. I.: Numerical Modeling of Unsteady Flow through a Turbomachine Stage. ASME 98-GT-253. Beschaufelung 92. Bogers, P. F.: Design and Experimental Verification of an Optimised Compressor Blade. ASME 98-GT193. 93. Hobson, G. V.: Effect of Reynolds Number on Separation Bubbles on Controlled-Diffusion Compressor Blades in Cascade. ASME 98-GT-422. 94. Currie, T. C.: Comparison of w-Based Turbulence Models for Sumulating Separated Flows in Transonic Compressor Cascades. ASME 98-GT-421. 95. Biesinger, Th. E.: Refined k-e Turbulence Model Q3D-Predictions in Compressor Cascades at Design and Off-Design. ASME 98-GT-322. Stufenbelastung 96. Willinger, R.: Vergleich verschiedener aerodynamischer Lastverteilungskonzepte in vielstufigen Axialverdichtern; VDI Berichte Nr. 1425 (1998), S. 121-131. 97. Müller, R.: Belastungsänderungen bei Verdichtern und deren Beurteilung anhand von Meßergebnissen am Niedergeschwindigkeitsverdichter Dresden; VDI Berichte Nr.1425 (1998), S. 157-166. 98. Probasco, D. P.: Variations in Upstream Vane Loading with Changes in Back Pressure in a Transonic Compressor. ASME 98-GT-344. Verstellbare Leitschaufeln 99. Gerodez, P.: Verstellbare Verdichter-Vorleitreihe und EV-Brennkammer - Erfahrungen, Durchführung und Ergebnisse eines Gasturbinen-Retrofit-Projektes. VGB Kraftwerkstechnik 78 (1998) 11, S. 53-59. 100. Puetz, O.: IGV-Rotor Interactions in a 4-Stage Axial Compressor. ASME 98-GT-093. 101. Minne, M.: Fast Acting Inlet Guide Vanes. Power-Gen Europe 98. 102. Cyrus, V.: Aerodynamic Performance of an Axial Compressor Stage with Variable Rotor Blades and Variable Inlet Guide Vanes. ASME 98-GT-151. 103. Walbaum, M.: Einfluß der Leitschaufelverstellung auf die Entwicklungsformen des Rotating Stall in mehrstufigen Verdichtern; VDI Berichte Nr. 1425 (1998), S. 177-188. Diffusoren und Spiralen 104. Casartelli, E.: Performance Analysis in a Subsonic Radial Diffuser. ASME 98-GT-153. 105. Hillewaert, K.: Numerical Simulation of Impeller-Volute Interaction in Centrifugal Compressors. ASME 98-GT-244. 106. Braembussche, R. A.: Improved Model for the Design and Analysis of Centrifugal Compressor Volutes. ASME 98-GT-187. 107. Bennett, I.: Detailed Measurements within a Selection of Pipe Diffusers for Centrifugal Compressors. ASME 98-GT-092. 108. Engeda, A.: Design and Investigation of Four Low Solidity Vaned Diffusers to Assess the Effect of Solidity and Vane Number. ASME 98-GT-252. Verluste 109. Fuchs, R.: Ein verlustminimiertes Verdichtergitter für einen transsonischen Rotor - Entwurf und Analyse; VDI Berichte Nr. 1425 (1998), S. 259-270. Spaltweiten und -verluste 110. Inoue, M.: Physical Explanations of Tip Leakage Flow Field in an Axial Compressor Rotor. ASME 98-GT091. 111. Thompson, D. W.: Experimental and Computational Investigation of Stepped Tip Gap Effects on the Flowfield of a Transonic Axial-Flow Compressor Rotor. ASME 98-GT-090. 112. Doukelis, A.: Investigation of the 3-D Flow Structure in a High-Speed Annular Compressor Cascade for Tip Clearance Effects. ASME 98-GT-039. 113. Hoeger, M.: Numerical Simulation of the Shock-Tip Leakage Vortex Interaction in a HPC Front Stage. ASME 98-GT-261. 114. Furukawa, M.: The Role of Tip Leakage Vortex Breakdown in Compressor Rotor Aerodynamics. ASME 98-GT-239. 115. Politis, E. S.: High-Speed Flow in an Annular Cascade with Tip Clearance: Numerical Investigation. ASME 98-GT-247. 116. Ivey, P. C.: Leakage Effects in the Rotor Tip-Clearance Region of a Multistage Axial Compressor, Part 1: Innovative Experiments. ASME 98-GT-591. 117. Politis, E. S.: Leakage Effects in the Rotor Tip-Clearance Region of a Multistage Axial Compressor, Part 2: Numerical Modelling. ASME 98-GT-592. 118. Gerolymos, G. A.: Tip-Clearance and Secondary Flows in a Transonic Compressor Rotor. ASME 98-GT366. 119. Doukelis, A.: The Effect of Tip Clearance Gap Size and Wall Rotation on the Performance of a HighSpeed Annular Compressor Cascade. ASME 98-GT-038. 120. Bonhommet-Chabanel, C.: Analysis of Tip Leakage Effects in a High Subsonic Annular Compressor Cascade. ASME 98-GT-195. Strömungsinteraktion 121. Puetz, O.: Strömungs-Wechselwirkung zwischen Vorleitreihe und Rotor 1 eines 4-stufigen Axialverdichters; VDI Berichte Nr. 1425 (1998), S. 91-104. 122. Wadia, A. R.: Design and Testing of Swept and Leaned Outlet Guide Vanes to Reduce Stator-StrutSplitter Aerodynamic Flow Interactions. ASME 98-GT-070. 123. Wu, X. H.: Vortex Simulation of Rotor/Stator Interaction in Turbomachinery. ASME 98-GT-015. Wirbelstörungen 124. Valkov, T. V.: Effect of Upstream Rotor Vortical Disturbances on the Time-Average Performance of Axial Compressor Stators: Part 1 Framework of Technical Approach and Wake-Stator Blade Interactions. ASME 98-GT-312. 125. Valkov, T. V.: Effect of Upstream Rotor Vortical Disturbances on Time-Average Performance of Axial Compressor Stators: Part 2 - Rotor Tip Vortex/Streamwise Vortex-Stator Blade Interactions. ASME 98GT-313. 126. Boos; P.: Flow Measurement in a Multistage Large Scale Low Speed Axial Flow Research Compressor. ASME 98-GT-432. Inverse Auslegung 127. Mertens, B.: Mischungsvorgänge in einem invers ausgelegten Axialverdichter. Bericht aus der Tätigkeit der Forschungsvereinigung Verbrennungskraftmaschinen e.V. (FVV). Motortechnische Zeitschrift, 59/1998, 2, S. 136-144. 128. Damle, S.: Practical Use of 3D Inverse Method For Compressor Blade Design. ASME 98-GT-115. 129. Wang, Z.: A Fully Three-Dimensional Inverse Method for Turbomachinery Blading with Navier-Stokes Equations. ASME 98-GT-126. 130. Tiow, W. T.: A Viscous Transonic Inverse Design Method for Turbomachinery Blades Part I: 2D Cascades. ASME 98-GT-125. Instabilitäten 131. März, J.: Circumferential Structure of Rotating Instability under Variation of Flow Rate and Solidity; VDI Berichte Nr. 1425 (1998), S. 189-198. 132. Regnery, D.: Entwicklung eines Systems zur Stabilitätsüberwachung in vielstufigen Axialverdichtern; VDI Berichte Nr. 1425 (1998), S. 199-210. 133. Hofmann, W.: Analyse transienter Meßdaten eines zehnstufigen Hochdruckverdichters an der Stabilitätsgrenze; VDI Berichte Nr. 1425 (1998), S. 211-223. 134. Gnesin, V. I.: Numerical Analysis of Unsteady Transonic 3D Flow in Oscillating Turbomachinery Blading; VDI Berichte Nr. 1425 (1998), S. 359-369. 135. Walker, G. J.: Periodic Transition on an Axial Compressor Stator - Incidence and Clocking Effects Part I Experimental Data. ASME 98-GT-363. 136. Solomon, W. J.: Periodic Transition on an Axial Compressor Stator - Incidence and Clocking Effects Part II - Transition Onset Predictions. ASME 98-GT-364. 137. Prato, J.: Steady and Unsteady Three-Dimensional Flow Field Downstream of an Embedded Stator in a Multistage Axial Flow Compressor - Part 1: Unsteady Velocity Field. ASME 98-GT-521. 138. Suryavamshi, N.: Steady and Unsteady Three Dimensional Flow Field Downstream of an Embedded Stator in a Multistage Axial Flow Compressor - Part 2: Composite Flow Field. ASME 98-GT-522. 139. Suryavamshi, N.: Steady and Unsteady Three Dimensional Flow Field Downstream of an Embedded Stator in a Multistage Axial Flow Compressor - Part 3: Deterministic Stress and Heat-Flux Distribution and Average-Passage Equation System. ASME 98-GT-523. 140. Singh, U. K.: A Comparison of Measured and Predicted Unsteadiness in a Transonic Fan. ASME 98-GT274. 141. Wallscheid, L.: Investigation of Unsteady Flow Phenomena in a Counterrotating Ducted Propfan. ASME 98-GT-251. Pumpen und Rotating stall 142. Peitsch, D.: A New Method for Surge Margin Improvement of Booster Compressors in Modern Aeroengines. ASME 98-GT-234. 143. Höss, B.: Stall Inception in the Compressor System of a Turbofan Engine. ASME 98-GT-475. 144. Hoying, D. A.: Role of Blade Passage Flow Structures in Axial Compressor Rotating Stall Inception. ASME 98-GT-588. 145. Grauer, F.: Detection of Precursor Waves Announcing Stall in Two 3-Stage Axial Compressors. ASME 98-GT-520. 146. Gong, Y.: A Computational Model for Short Wavelength Stall Inception and Development in Multi-Stage Compressors. ASME 98-GT-476. 147. Vo, H. D.: Experimental Development of a Jet Injection Model for Rotating Stall Control. ASME 98-GT308. 148. Spakovszky, Z. S.: Rotating Stall Control in a High-Speed Stage with Inlet Distortion, Part I - Radial Distortion. ASME 98-GT-265. 149. Spakovszky, Z. S.: Rotating Stall Control in a High-Speed Stage with Inlet Distortion, Part II Circumferential Distortion. ASME 98-GT-264. 150. Saxer-Felici, H. M.: Prediction and Measurement of Rotating Stall Cells in an Axial Compressor. ASME 98-GT-067. 151. Palomba, C.: 3D Flow Field Measurement around a Rotating Stall Cell. ASME 98-GT-594. 152. Bright, M. M.: Investigation of Pre-Stall Mode and Pip Inception in High Speed Compressors Through the Use of Correlation Integral. ASME 98-GT-365. Schwingungen 153. Witte, H.: Beurteilung von strömungserregten Schaufelschwingungen eines FlugtriebwerkAxialverdichters mittels statistischer Analysenmethode; VDI Berichte Nr. 1425 (1998), S. 321-336. 154. Enghardt, L.: Akustische Radialmodenanalyse an einem dreistufigen Niederdruckaxialverdichter; VDI Berichte Nr. 1425 (1998), S. 337-346. 155. Lu, P.-J.: Evaluation of Acoustic Flutter Suppression for Cascade in Transonic Flow. ASME 98-GT-065. Experimente 156. Mailach, R.: Experimentelle Untersuchung von Verdichterinstabilitäten am Niedergeschwindigkeitsverdichter Dresden; VDI Berichte Nr. 1425 (1998), S. 167-176. 157. Lyes, P. A.: Experimental Evaluation of the High-to-Low Speed Transformation Process for a Highly Loaded Core Compressor Stage. ASME 98-GT-334. 158. Swoboda, M.: An Experimental Examination of Cantilevered and Shrouded Stators in a Multistage Axial Compressor. ASME 98-GT-282. 159. Silkowski, P. D.: An Experimental Investigation of System Effects in Axial Flow Compressors. ASME 98GT-593. Vergleich Messung - Rechnung 160. Dohring, C. M.: Experimental and Numerical Investigation of Flapping Wing Propulsion and its Application for Boundary Layer Control. ASME 98-GT-046. Diverses 161. Funazaki, K.: Effects of Periodic Wake Passing upon Flat-Plate Boundary Layers Experiencing Favorable and Adverse Pressure Gradient. ASME 98-GT-114. 162. Dorney, D. J.: Physics of Airfoil Clocking in a High-Speed Axial Compressor. ASME 98-GT-082. 163. Tuncer, I. H.: Investigation of Periodic Boundary Conditions in Multi-Passage Cascade Flows Using Overset Grids. ASME 98-GT-011. 164. Singh, U. K.: The Effect of Hub Leakage Flow in a Transonic Compressor Stator. ASME 98-GT-424. 165. Tuccillo, R.: Genetic Algorithm Based Strategies for Radial Flow Impeller Design. ASME 98-GT-427. 166. Hatman, A.: A Prediction Model for Separated-Flow Transition. ASME 98-GT-237. 167. Hu, J.: On the Application of Transition Correlations in Turbomachinery Flow Calculation. ASME 98-GT460. 168. Rao, J. S.: A Mixed Shell Element for Cambered Helicoidal Blades and Dynamic Stresses Due to Aerodynamic Excitation. ASME 98-GT-356. 169. Khalid, S. A.: Endwall Blockage in Axial Compressors. ASME 98-GT-188. 170. Barankiewicz, W. S.: Impact of Variable-Geometry Stator Hub Leakage in a Low Speed Axial Compressor. ASME 98-GT-194. 171. Wellborn, St. R.: The Influence of Shrouded Stator Cavity Flows on Multistage Compressor Performance. ASME 98-GT-012. Radialverdichter 172. Yiu, K. F. C.: A 3D Automatic Optimization Strategy for Design of Centrifugal Compressor Impeller Blades. ASME 98-GT-128. 173. Demeulenaere, A.: Application of a Three-Dimensional Inverse Method to the Design of a Centrifugal Compressor Impeller. ASME 98-GT-127. 174. Zangeneh, M.: On 3D Inverse Design of Centrifugal Compressor Impellers with Splitter Blades. ASME 98-GT-507. 175. Clayton, R. P.: A Numerical Study of the Three-Dimensional Turbulent Flow in the Impeller of a HighSpeed Centrifugal Compressor. ASME 98-GT-049. 176. Eisenlohr, G.: Analysis of the Transonic Flow at the Inlet of a High Pressure Ratio Centrifugal Impeller. ASME 98-GT-024. 177. Filipenco, V. G.: Effects of Inlet Flow Field Conditions on the Performance of Centrifugal Compressor Diffuser Part 1: Discrete-Passage Diffusers. ASME 98-GT-473. 178. Deniz, S.: Effects of Inlet Flow Field Conditions on the Performance of Centrifugal Compressor Diffuser Part 2: Straight-Channel Diffusers. ASME 98-GT-474. 179. Rodgers, C.: The Centrifugal Compressor Inducer. ASME 98-GT-032. 180. Meuleman, C.: Surge in a Low-Speed Radial Compressor. ASME 98-GT-426. 181. Salvage, J. W.: Development of a Centrifugal Compressor With a Variable Geometry Split-Ring Pipe Duffuser. ASME 98-GT-007. 182. Stahlecker, D.: Investigations of Turbulent Flow in a Centrifugal Compressor Vaned Diffuser by 3Component Laser Velocimetry. ASME 98-GT-300. 183. Roduner, C.: Comparison of Measurement Data at the Impeller Exit of a Centrifugal Compressor Measured with both Pneumatic and Fast-Response Probes. ASME 98-GT-241. 184. Chen, Y. N.: Excitation Mechanism for Standing Stall of Centrifugal Compressors. ASME 98-GT-245. 185. Paroubek, J.: The Influence of Impeller Flow Channel Modification on Aerodynamic Performance of a Centrifugal Compressor Stage. ASME 98-GT-040. 186. Mutou, A.: Behavior of Attractors During Surge in Centrifugal Compression Systems. ASME 98-GT-301. 187. Justen, F.: Experimental Investigation of Unsteady Flow Phenomena in a Centrifugal Compressor Vaned Diffuser of Variable Geometry. ASME 98-GT-368. 188. Kassens, I.: Flow Measurements behind the Inlet Guide Vane of a Centrifugal Compressor. ASME 98GT-086. 189. Oh, J.S.: Numerical Investigation of Internal Flow Field for Modified Design of Eckardt Backswept Impeller. ASME 98-GT-296. 190. Lenke, L. J.: Numerical Simulation of the Flow through the Return Channel of Multi-Stage Centrifugal Compressors. ASME 98-GT-255. 191. Sorokes, J. M.: Investigation of the Circumferential Static Pressure Non-Uniformity Caused by a Centrifugal Compressor Discharge Volute. ASME 98-GT-326. 192. Arnulfi, G. L.: Multistage Centrifugal Compressor Surge Analysis Part I: Experimental Investigation. ASME 98-GT-068. 193. Arnulfi, G. L.: Multistage Centrifugal Compressor Surge Analysis: Part II: Numerical Simulation and Dynamic Control Parameters Evaluation. ASME 98-GT-069. Turbine 194. Woinowsky-Krieger, M.: Off-Design Performance of a Single Stage Transonic Turbine. ASME 98-GT002. 195. Arcoumanis, D.: Inlet and Exit Flow Characteristics of Mixed Flow Turbines. ASME 98-GT-495. 196. Jennions, I. K.: The GT24/26 Low Pressure Turbine. ASME 98-GT-029. CFD Anwendungen 197. Liamis, N.: CFD Analysis of High Pressure Turbines. ASME 98-GT-453. 198. Niestroj, O.: Three Dimensional Flow Predictions in Axial Flow Turbine Cascades. ASME 98-GT-325. 199. Noera, F.: Through Flow Calculation in Axial Flow Turbines Using a Quasi-Orthogonal Solver. ASME 98GT-503. 200. Fransson, T. H.: Viscous and Inviscid Linear/Nonlinear Calculations Versus Quasi 3D Experimental Cascade Data for a New Aeroelastic Turbine Standard Configuration. ASME 98-GT-490. 201. Hasan, R. G. M.: 3D RANS Calculations of Flow Through Turbine Volutes. ASME 98-GT-496. 202. Passrucker, H.: Numerical Calculation of Three-Dimensional Euler Flow Through a Transonic Test Turbine Stage. ASME 98-GT-428. 203. Pierret, St.: Turbomachinery Blade Design Using a Navier-Stokes Solver and Artificial Neural Network. ASME 98-GT-004. 204. Bassi, F.: Quasi-3D Numerical Computations on a Film-Cooled Gas Turbine Nozzle. ASME 98-GT-536. 205. Bell, D. L.: Three Dimensional Unsteady Flow for an Oscillating Turbine Blade and the Influence of Tip Leakage. ASME 98-GT-571. 206. Eulitz, F.: Numerical Investigation of Wake Interaction in a Low Pressure Turbine. ASME 98-GT-563. 207. Vogel, D. T.: Numerical Investigation of the Influence of Specific Vortex Generation on the Mixing Process of Film Cooling Jets. ASME 98-GT-210. 208. Krogh Nielsen, K.: Optimization of Swirl Brakes by Means of a 3D Navier-Stokes Solver. ASME 98-GT328. Beschaufelung 209. Hartland, J. C.: Non-Axisymmetric Endwall Profiling in a Turbine Rotor Blade. ASME 98-GT-525. 210. Venable, B. L.: Influence of Vane-Blade Spacing on Transonic Turbine Stage Aerodynamics, Part I: Time-Averaged Data and Analysis. ASME 98-GT-481. 211. Busby, J. A.: Influence of Vane-Blade Spacing on Transonic Turbine Stage Aerodynamics, Part II: TimeResolved Data and Analysis. ASME 98-GT-482. 212. Amano, R. S.: Predictions of Turbulent Flow in a Turbine Stator/Rotor Passage. ASME 98-GT-524. 213. Matsunuma, T.: Characteristics of an Annular Turbine Cascade at Low Reynolds Numbers. ASME 98GT-518. 214. Gudmundsson, B.: Experiences from the Joint Development of the GTX100 Turbine Blading. ASME 98GT-201. 215. Boyle, R. J.: Aerodynamics of a Transitioning Turbine Stator over a Range of Reynolds Numbers. ASME 98-GT-285. Verluste 216. Hatman, A.: Separated-Flow Transition Part 1 - Experimental Methodology and Mode Classification. ASME 98-GT-461. 217. Hatman, A.: Separated-Flow Transition Part 2 - Experimental Results. ASME 98-GT-462. 218. Hatman, A.: Separated-Flow Transition Part 3 - Primary Modes and Vortex Dynamics. ASME 98-GT463. 219. Sondak, D. L.: Simulation of Vortex Shedding in a Turbine Stage. ASME 98-GT-242. 220. Duden, A.: Controlling the Secondary Flow in a Turbine Cascade by 3D Airfoil Design and Endwall Contouring. ASME 98-GT-072. 221. Kubo, R.: Aerodynamic Loss Increase Due to Individual Film Cooling Injections from Gas Turbine Nozzle Surface. ASME 98-GT-497. 222. Boyle, R. J.: Mach Number Effects on Turbine Blade Transition Length Prediction. ASME 98-GT-367. Spaltweiten und -verluste 223. Stastny, M.: Effects of the Rotor Tip Leakage in a Transonic Turbine with Long Blades. ASME 98-GT096. 224. Willinger, R.: The Role of Rotor Tip Clearance on the Aerodynamic Interaction of a Last Gas Turbine Stage and an Exhaust Diffuser. ASME 98-GT-094. 225. Ameri, A. A.: Effects of Tip Clearance and Casing Recess on Heat Transfer and Stage Efficiency in Axial Turbines. ASME 98-GT-369. Instabilitäten 226. Hilditch, M. A.: Unsteady Flow in a Single Stage Turbine. ASME 98-GT-531. 227. Walraevens, R.E.: Experimental and Computational Study of the Unsteady Flow in a 1.5 Stage Axial Turbine with Emphasis on the Secondary Flow in the Second Stator. ASME 98-GT-254. Schaufelschwingungen 228. Nowinski, M.: Flutter Mechanisms in Low Pressure Turbine Blades. ASME 98-GT-573. 229. Panovsky, J.: A Design Method to Prevent Low Pressure Turbine Blade Flutter. ASME 98-GT-575. . Wärmefluß und -übergang 230. Bohn, D.: The Effect of Turbulence on the Heat Transfer in Closed Gas-Filled Rotating Annuli for Different Rayleigh Numbers. ASME 98-GT-542. 231. Hall, U.: Simulations and Measurements on Impulse Blades for Heat Transfer Prediction in Supersonic Turbine Applications. ASME 98-GT-154. 232. Holmberg, D. G.: A Frequency Domain Analysis: Turbine Pressure Side Heat Transfer. ASME 98-GT152. 233. Radomsky, R. W.: Effects of High Freestream Turbulence Levels and Length Scales on Stator Vane Heat Transfer. ASME 98-GT-236. 234. Iyer, G. R.: A New Low-Reynolds Number k-e Model for Simulation of Momentum and Heat Transport Under High Free Stream Turbulence. ASME 98-GT-081. 235. Yuki, U. M.: Effect of Coolant Injection on Heat Transfer For a Simulated Turbine Airfoil Leading Edge. ASME 98-GT-431. 236. Wang, H. P.: Effect of High Freestream Turbulence with Large Length Scale on Blade Heat/Mass Transfer. ASME 98-GT-107. 237. Glezer, B.: Heat Transfer in a Rotating Radial Channel with Swirling Internal Flow. ASME 98-GT-214. 238. Joe, Ch. R.: High Pressure Turbine Vane Annular Cascade Heat Flux and Aerodynamic Measurements with Comparisons to Predictions. ASME 98-GT-430. 239. Jakoby, R.: Correlations of the Convective Heat Transfer in Annular Channels with Rotating Inner Cylinder. ASME 98-GT-097. 240. Saidi, A.: Calculation of Convective Heat Transfer in Square-Sectioned Gas Turbine Blade Cooling Channels. ASME 98-GT-204. 241. Mirzaee, I.: Heat Transfer in a Rotating Cavity With a Stationary Stepped Casing. ASME 98-GT-112. 242. Kang, M. B.: Heat Transfer and Flowfield Measurements in the Leading Edge Region of a Stator Vane Endwall. ASME 98-GT-173. 243. Chyu, M. K.: Measurements of Heat Transfer Characteristics of Gap Leakage Around a Misaligned Component Interface. ASME 98-GT-132. 244. Schobeiri, M. T.: Unsteady Wake effects on Boundary Layer Transition and Heat Transfer Characteristics of a Turbine Blade. ASME 98-GT-291.Rigby, D. L.: Prediction of Heat and Mass Transfer in a Rotating Ribbed Coolant Passage with a 180 Degree Turn. ASME 98-GT-329. 245. Pilbrow, R.: Heat Transfer in a "Cover-Plate" Pre-Swirl Rotating-Disc System. ASME 98-GT-113. 246. Shih, T. I-P.: Flow and Heat Transfer in a Ribbed U-Duct under Typical Engine Conditions. ASME 98GT-213. 247. Khalatov, A.: Improved Approach to an Endwall Heat Transfer Analysis: A Linear Guide Vane and a Curved Duct. ASME 98-GT-293. 248. Bohn, D. E.: A Conjugate 3-D Flow and Heat Transfer Analysis of a Thermal Barrier Cooled Turbine Guide Vane. ASME 98-GT-089. 249. Michelassi, V.: Unsteady Heat Transfer in Stator-Rotor Interaction by Two Equation Turbulence Model. ASME 98-GT-243. 250. Hedhund, C. R.: Heat Transfer and Flow Phenomena in a Swirl Chamber Simulating Turbine Blade Internal Cooling. ASME 98-GT-466. 251. Taslim, M. E.: Measurements of Heat Transfer Coefficients in Rib-Roughened Trailing-Edge Cavities with Crossover Jets. ASME 98-GT-435. 252. Cho, H. H.: Characteristics of Heat Transfer in Impinging Jets by Control of Vortex Pairing. ASME 98GT-276. 253. Gritsch, M.: Heat Transfer Coefficient Measurements of Film-Cooling Holes with Expanded Exits. ASME 98-GT-028. 254. Gehrer, A.: External Heat Transfer Predictions in a Highly-Loaded Transonic Linear Turbine Guide Vane Cascade Using an Upwind Biased Navier-Stokes Solver. ASME 98-GT-238. 255. Jung, K.: Highly Resolved Distribution of Heat Transfer for Turbine Leading Edge Film Cooling Including Reynolds Number and Blowing Rate Effects. ASME 98-GT-064. 256. Hwang, J.-J.: Heat Transfer and Pressure Drop in Pin-Fin Trapezoidal Ducts. ASME 98-GT-110. 257. Chyu, M. K.: Heat Transfer Contributions of Pins and Endwall in Pin-Fin Arrays: Effects of Thermal Boundary Condition Modeling. ASME 98-GT-175. 258. Taslim, M. E.: 45° Round-Corner Rib Heat Transfer Coefficient Measurements in a Square Channel. ASME 98-GT-176. 259. Jerhamre, A.: Characteristics of Heat Transfer in Rotating Cavities. ASME 98-GT-137. Kühlung 260. Mirzamoghadam,A.V.: Turbine Disc-Rim Cooling Design Criteria for Modern Two Stage High Pressure Turbine Aero-Engines. ASME 98-GT-205. 261. Carcasci, C.: Modular Simulation of Coolant Internal Network and Rotating Cavity Analysis. ASME 98GT-120. 262. Kerrebrock, J. L.: Vaporization Cooling for Gas Turbines, the Return-Flow Cascade. ASME 98-GT-177. Filmkühlung 263. Seo, H. J.: Effects of Bulk Flow Pulsations on Film Cooling from Different Length Injection Holes at Different Blowing Ratios. ASME 98-GT-192. 264. Jung, I. S.: Effects of Bulk Flow Pulsations on Film Cooling from Spanwise Oriented Holes. ASME 98GT-211. 265. Hui Du: Effect of Unsteady Wake with Trailing Edge Coolant Ejection on Film Cooling Performance for a Gas Turbine Blade. ASME 98-GT-259. 266. Burd, St. W.: Turbulence Spectra and Length Scales Measured in Film Coolant Flows Emerging from Discrete Holes. ASME 98-GT-190. 267. Lin, Y.-L.: Computations of Discrete-Hole Film Cooling over Flat and Convex Surfaces. ASME 98-GT436. 268. Drost, U.: Investigation of Detailed Film Cooling Effectiveness and Heat Transfer Distributions on a Gas Turbine Airfoil. ASME 98-GT-020. 269. Dahlander, P.: Numerical Simulation of a Film Cooled Nozzle Guide Vane Using an Injection Model. ASME 98-GT-439. 270. Ferguson, J. D.: Performance of Turbulence Models and Near-Wall Treatments in Discrete Jet Film Cooling Simulations. ASME 98-GT-438. 271. Garg, V. K.: Heat Transfer on a Film-Cooled Blade - Effect of Hole Physics. ASME 98-GT-404. 272. Kohli, A.: Entrance Effects on diffused Film-Cooling Holes. ASME 98-GT-402. 273. Chernobrovkin, A.: Numerical Simulation and Aerothermal Physics of Leading Edge Film Cooling. ASME 98-GT-504. 274. Moser, S.: The Influence of Pressure Pulses to an Innovative Turbine Blade Film Cooling System. ASME 98-GT-545. 275. Urban, M. F.: Experimental and Numerical Investigations of Film-Cooling Effects on the Aerodynamic Performance of Transonic Turbine Blades. ASME 98-GT-546. 276. Goldstein, R. J.: Film Cooling Effectiveness and Mass/Heat Transfer Coefficient Downstream of One Row of Discrete Holes. ASME 98-GT-174. 277. McGrath, E. L.: Physics of Hot Crossflow Ingestion in Film Cooling. ASME 98-GT-191. 278. Seager, D. J.: Film Cooling Heat Transfer: Shaped and Compound Angle Hole Injection. ASME 98-GT134. 279. Berhe, M. K.: Curvature Effects on Discrete-Hole Film Cooling. ASME 98-GT-373. 280. Berhe, M. K.: Investigation of Discret-Hole Film Cooling Parameters Using Curved-Plate Models. ASME 98-GT-374 Kühlmedium 281. Carnevale, E.: A Rotor Blade Cooling Improvement for Heavy Duty Gas Turbine Using Steam and Mixed Steam/Air Cooling. ASME 98-GT-275. 282. Brillert, D.: Cooling Air Flow in a Multi Disc Industrial Gas Turbine Rotor. ASME 98-GT-136. . Kühlgeometrie 283. Liou, M-S.: Numerical Analysis of Turbine Coolant Passage Flows. ASME 98-GT-320. 284. Lutum, E.: Influence of the Hole Length-to-Diameter Ratio on Film Cooling with Cylindrical Holes. ASME 98-GT-010. 285. Tolpadi, A. K.: Predictions of the Effect of Roughness on Heat Transfer From Turbine Airfoils. ASME 98GT-087. 286. Uzol, O.: Oscillator Fin as a Novel Heat Transfer Augmentation Device for Gas Turbine Cooling Applications. ASME 98-GT-150. 287. Dutta, P.: Internal Heat Transfer Enhancement by Two Perforated Baffles in a Rectangular Channel. ASME 98-GT-055. 288. Donahoo, E. E.: Determination of Optimal Row Spacing for a Staggered Cross-Pin Array in a Turbine Blade Cooling Passage. ASME 98-GT-149. 289. Chen, P.-H.: Effects Of Compound Angle Injection On Flat-Plate Film Cooling Through A Row of Conical Holes. ASME 98-GT-459. 290. Wang, T.: Jet Mixing in a Slot. ASME 98-GT-056. 291. Schabacker, J.: PIV Investigation of the Flow Characteristics in an Internal Coolant Passage with Two Ducts Connected by a Sharp 180° Bend. ASME 98-GT-544. 292. Day, Ch. R. B.: Efficiency Measurements of an Annular Nozzle Guide Vane Cascade with Different Film Cooling Geometries. ASME 98-GT-538. 293. Berger, Ph. A.: A Near-Field Investigation Into the Effects of Geometry and Compound Angle on the Flowfield of a Row of Film Cooling Holes. ASME 98-GT-279. 294. Friedrichs, S.: The Design of an Improved Endwall Film-Cooling Configuration. ASME 98-GT-483. Meßtechnik 295. Servouze, Y.: 3D Laser Anemometry in a Rotating Cooling Channel. ASME 98-GT-123. 296. Taylor, M. D.: Time Resolved HWA Measurements of the OTL Flow Field from a Shrouded Turbine HP Rotor Blade. ASME 98-GT-564. Experimente 297. Denninger, M. J.: An Experimental Study on the Relationship between Velocity Fluctuations and Heat Transfer in a Turbulent Air Flow. ASME 98-GT-108. 298. Burd, St. W.: Measurements of Discharge Coefficients in Film Cooling. ASME 98-GT-009. 299. Dambach, R.: An Experimental Study of Tip Clearance Flow in a Radial Inflow Turbine. ASME 98-GT467. 300. Bons, J. P.: Complementary Velocity and Heat Transfer Measurements in an Rotating Cooling Passage with Smooth Walls. ASME 98-GT-464. 301. Cravero, C.: Experimental Analysis of Fluid Flow and Surface Heat Transfer in a Three-Pass Trapezoidal Serpentine Smooth Passage. ASME 98-GT-543. 302. Funazaki, K.: Surface Heat Transfer Measurements of a Scaled Rib-Roughened Serpentine Cooling Passage by Use of a Transient Liquid Crystal Technique. ASME 98-GT-515. 303. Ardey, S.: A Systematic Experimental Study on the Aerodynamics of Leading Edge Film Cooling on a Large Scale High Pressure Turbine Cascade. ASME 98-GT-434. 304. Haiping, Ch.: Experimental Investigation on Impingement Heat Transfer from Rib Roughened Surface within Arrays of Circular Jet: Effect of Geometric Parameters. ASME 98-GT-208. 305. Kaszeta, R. W.: Flow Measurements in Film Cooling Flows With Lateral Injection. ASME 98-GT-054. 306. Sohn, Ki H.: Experimental Investigation of Boundary Layer Behavior in a Simulated Low Pressure Turbine. ASME 98-GT-034. Vergleich Messung - Rechnung 307. Bohn, D. E.: Experimental and Numerical Conjugate Investigation of the Blowing-Ratio Influence on the Showerhead Cooling Efficiency. ASME 98-GT-085. 308. Fitzgerald, J. E.: Turbine Blade Aerodynamic Wall Shear Stress Measurements and Predictions. ASME 98-GT-562. 309. Carscallen, W. E.: Measurement and Computation of Energy Separation in the Vortical Wake Flow of a Turbine Nozzle Cascade. ASME 98-GT-477. 310. Menter, U. W.: Experimental Analysis and Numerical Simulation of the Flow Field in Turbine Scrolls. ASME 98-GT-597. 311. Harvey, N. W.: Measurement and Calculation of Nozzle Guide Vane End Wall Heat Transfer. ASME 98GT-066. 312. Casciaro, C.: A Comparison of Experimental with Computational Results in an Annular Turbine Cascade with Emphasis on Losses. ASME 98-GT-146. 313. Sanz, W.: Numerical and Experimental Investigation of the Wake Flow Downstream of a Linear Turbine Cascade. ASME 98-GT-246. 314. Rubensdörffer, F.G.: Experimental and Numerical Investigation of Heat Transfer on a Cooled Turbine Vane. ASME 98-GT-212. 315. Wallis, A. M.: Comparison of Design Intent and Experimental Measurements in a Low Aspect Ratio Axial Flow Turbine with Three-Dimensional Blading. ASME 98-GT-516. 316. Rowbury, D. A.: Scaling of Film Cooling Discharge Coefficient Measurements to Engine Conditions. ASME 98-GT-079. 317. Ott, P.: The Influence of Tailboards on Unsteady Measurements in a Linear Cascade. ASME 98-GT-572. Diverses 318. Heselhaus, A.: A Hybrid Coupling Scheme and Stability Analysis for Coupled Solid/Fluid Turbine Blade Temperature Calculations. ASME 98-GT-088. 319. Jennions, I. K.: A Numerical Study of Air Transfer from a Stationary to a Rotating System through an Unsealed Cavity. ASME 98-GT-139. 320. Muldoon, F.: Dynamics of Large-Scale Structures for Jets in a Crossflow. ASME 98-GT-019. 321. Dossena, V.: The Influence of Endwall Contouring on the Performance of a Turbine Nozzle Guide Vane. ASME 98-GT-071. 322. Michelassi, V.: Secondary Flow Decay Downstream of Turbine Inlet Guide Vane with Endwall Contouring. ASME 98-GT-095. 323. Hildebrandt, Th.: A Numerical Study of the Influence of Grid Refinement and Turbulence Modelling on the Flow Field inside a Highly Loaded Turbine Cascade. ASME 98-GT-240. 324. Sekavcnik, M.: Characteristics of One Stage Radial Centrifugal Turbine. ASME 98-GT-494. 325. Liou, T-M.: Fluid Flow in a 180 Deg Sharp Turning Duct with Different Divider Thicknesses. ASME 98GT-189. 326. Norris, G.: Strut Influences Within a Diffusing Annular S-Shaped Duct. ASME 98-GT-425. Verbrennung, Brennkammer, Emissionen CFD Applications 327. Crocker, D. S.: CFD Modeling of a Gas Turbine Combustor from Compressor Exit to Turbine Inlet. ASME 98-GT-184. 328. Tolpadi, A. K.: Advanced Combustion Code: Overall Description, Prediction of a Jet Diffusion Flame and Combustor Flowfields. ASME 98-GT-229. 329. Costura, D. M.: A Computational Model for the Study of Gas Turbine Combustor Dynamics. ASME 98GT-342. 330. Liever, P. A.: CFD Assessment of a Wet, Low-NOx Combustion System for a 3MW-Class Industrial Gas Turbine. ASME 98-GT-292. 331. Bideau, R. J.: The Development of a Computer Code for the Estimation of Combustor Exhaust Temperature Using Simple Gas Analysis Measurements. ASME 98-GT-180. Experimente 332. Ferrante, A.: Main Features and Potential Applications of the New Turbogas Burner Test Facility in Gioia del Colle. Power-Gen Europe 98. 333. Benelli, G.: High Pressure Tests on Gas Turbine Combustors. Power-Gen Europe 98. 334. Hung, W. S. Y.: Uncertainty in Gas Turbine NOx Emission Measurements. ASME 98-GT-075. Modellierungen und Simulationen 335. Xia, J.-L.: Numerical and experimental study of swirling flow in a model combuster. International Journal of Heat and Mass Transfer, 41/1998, 11, S. 1485-1497. 336. Schmid, H.-P.: A model for calculating heat release in premixed turbulent flames. Combustion and Flame, 113/1998, 1/2, S. 79-91. 337. Kim, J.-S.: Effects of non-homogeneities on the eigenmodes of acoustic pressure in combustion chambers. Journal of Sound and Vibration, 209/1998, 5, S. 821-843. 338. Polifke, W.: Optimization of rate coefficients for simplified reaction mechanisms with genetic algorithms. Combustion and Flame, 113/1998, 1/2, S. 119-134. 339. Menon, S.: Subgrid Two-Phase Mixing and Combustion Modeling for Large-Eddy Simulations. ASME 98-GT-227. 340. Ganz, B.: Validation of Numerical Methods at a Confined Turbulent Natural Gas Diffusion Flame Considering Detailed Radiative Transfer. ASME 98-GT- 228. 341. Oost van, M.L.E.: Applying the Relationship between the Amount of CO2 and O2 in Flue Gases to Reduce the NOx Emission Measurement Uncertainty. ASME 98-GT-235. 342. Nicol, D. G.: Development of a Five-Step Global Methane Oxidation-NO Formation Mechanism for LeanPremixed Gas Turbine Combustion. ASME 98-GT-185. 343. Smirnov, A.: Modeling of Turbulent Swirling Flame Stabilization in LPP Combustors. ASME 98-GT-493. 344. Lachner, R.: Simultaneous Single-Shot LIF-Imaging of OH and UHC in a Prevaporized, Partially Premixed, Swirl-Stablized N-Heptane Flame. ASME 98-GT-560. 345. Hicks, R. A.: The Effect of the Fuel Injector Internal Geometry upon the Primary Zone Aerodynamics. ASME 98-GT-232. 346. Honami, S.: Effect of the Flame Dome Depth and Improvement of the Pressure Loss in the Dump Diffuser. ASME 98-GT-225. 347. Ale, B. B.: The Effect of Time of Exposure to Elevated Temperatures on the Flammability Limits of Some Common Gaseous Fuels in Air. ASME 98-GT-179. 348. Bunama, R.: An Investigation of the Formation and Venting of Flammable Mixtures Formed within Liquid Fuel Vessels. ASME 98-GT-178. 349. Parker, T.: Fugitive Methane Emission Reductions Using Gas Turbines. ASME 98-GT-314. Brennkammer 350. Anderson, T. J.: Dynamic Flame Structure in a Low NOx Premixed Combustor. ASME 98-GT-568. 351. Harding, St. C.: Fuel-Air Mixing and Combustion in an Optical, Lean, Premixed, Prevaporised Gas Turbine Combustor. ASME 98-GT-553. 352. Hu, I. Z.: Aerodynamics of a Fuel Spoke in a Gas Turbine Combustor. ASME 98-GT-389. 353. Koopmann, J. W.: Investigation of a Rectangular Rich Quench Lean Combustor Sector. ASME 98-GT230. 354. Peracchio, A. A.: Nonlinear Heat-Release/Acoustic Model for Thermoacoustic Instability in Lean Premixed Combustors. ASME 98-GT-269. 355. Rutar, T.: NOx Dependency on Residence Time and Inlet Temperature for Lean-Premixed Combustion in Jet-Stirred Reactors. ASME 98-GT-433. 356. Held, T. J.: Application of a Partially Premixed Laminar Flamelet Model to a Low Emissions Gas Turbine Combustor. ASME 98-GT-217. 357. Held, T. J.: Application of a Micro-/Macro-Mixing Two Reactor Model to a Single-Cup Low-Emissions Combustor. ASME 98-GT-218. Vormischsysteme 358. Vilayanur, S. R.: Effect of Inlet Conditions on Lean Premixed Gas Turbine Combustor Performance. ASME 98-GT-440. 359. Straub, D. L.: Effect of Fuel Nozzle Configuration on Premix Combustion Dynamics. ASME 98-GT-492. 360. Krüger, U.: Influence of Turbulence on the Dynamic Behaviour of Premixed Flames. ASME 98-GT-323. 361. Kraemer, G.: Flashback Arrestor for Lean Premixed, Prevaporized, Low NOx Combustors. ASME 98GT-596. 362. Hura, H. S.: Dry Low Emissions Premixer CCD Modeling and Validation. ASME 98-GT-444. Druckschwingungen 363. Gysling, D. L.: Combustion System Damping Augmentation with Helmholtz Resonators. ASME 98-GT268. 364. Mongia, R.: Measurement of Air-Fuel Ratio Fluctuations Caused by Combustor Driven Oscillations. ASME 98-GT-304. 365. Kendrick, D. W.: Acoustic Sensitivities of Lean-Premixed Fuel Injectors in a Single Nozzle Rig. ASME 98-GT-382. 366. Paschereit, Ch. O.: Investigation of the Thermoacoustic Characteristics of a Lean Premixed Gas Turbine Burner. ASME 98-GT-582. 367. Cronemyr, P. J. M.: Coupled Acoustic-Structure Analysis of an Annular DLE Combustor. ASME 98-GT502. 368. Ohtsuka, M.: Combustion Oscillation Analysis of Premixed Flames at Elevated Pressures. ASME 98-GT581. 369. Sattinger, St.: Sub-Scale Demonstration of the Active Feedback Control of Gas-Turbine Combustion Instabilities. ASME 98-GT-258. 370. Vermeulen, P. J.: Acoustically Controlled Combustor NOx. ASME 98-GT-303. 371. Verhage, A.: Pressure Pulsations in Combustion Chambers of Large Gas Turbines. Power-Gen Europe 98. Kühlung im Verbrennungssystem 372. Janczewski, J.: Heat Load on the Walls of an Annular DLE Combustor Calculation and Comparison with Experiments. ASME 98-GT-454. 373. Wigren, J.: A Combustor Can with 1.8 mm Thick Plasma Sprayed Thermal Barrier Coating. ASME 98GT-388. 374. Nilsson, U. E.: Experimental Investigation of GTX100 Combustor Liner Cooling System. ASME 98-GT539. 375. Abdon, A.: Investigation of a Turbulence Model for Wall Cooling of Combustion Chambers. ASME 98GT-540. 376. Silverstein, C. C.: Heat Pipe Combustor Cooling. ASME 98-GT-541. Verschiedene Systeme 377. Joshi, N. D.: Dry Low Emissions Combustor Development. ASME 98-GT-310. 378. Hoffmann, St.: Further Development of the Siemens LPP Hybrid Burner. ASME 98-GT-552. 379. Steinbach, Ch.: ABB’s Advanced EV Burner-A Dual Fuel Dry Low NOx Burner for Stationary Gas Turbines. ASME 98-GT-519. 380. Ziemann, J.: Low-NO(x) combustors for hydrogen fueled aero engine. International Journal of Hydrogen Energy, 23/1998, 4, S. 281-288. 381. Okuto, A.: Development of a Low NOx Combustor for 300kw-Class Ceramic Gas Turbine (CGT302). ASME 98-GT-272. 382. Takahashi, S.: Research and Development of Swirling Flow Combustor For Low NOx. ASME 98-GT357. 383. Chellini, R.: First LM1600 with DLE Combustor; Diesel & Gas Turbine Worldwide 7-8 1998, S. 28-31. 384. Vandesteene, J.: A Fleet Leader Experience with Dry Low Emissions Aeroderivative Gas Turbines (LM 6000 PB and PD). Power-Gen Europe 98. 385. Arrighi, L.: Operation and Maintenance Experiences of Dry Low NOx Combustors for Heavy Duty Gas Turbines GE MS 8001E (Type DLN1) and Fiat 70ID (Type K Point). Power-Gen Europe 98. 386. Soudarev, A.: Low-Emission Combustor for Power GTU Application. Power-Gen Europe 98. 387. Eroglu, A.: Vortex Generators in Lean-Premix Combustion. ASME 98-GT-487. 388. Kühnel, J.: Optimierung von Gasturbinenprozessen unter Berücksichtigung der Stickoxidbildung; VDI Berichte Nr. 1438 (1998), S 189-198. 389. Joos, F.: Field Experience of the Sequential Combustion System for the GT24/GT26 Gas Turbine Family. ASME 98-GT-220. 390. Solt, J. Ch.: The Ultimate NOx Solution for Gas Turbines. ASME 98-GT-287. Katalytische Verfahren 391. Ozawa, Y.: High Pressure Test Results of a Catalytically Assisted Ceramic Combustor for a Gas Tubine. ASME 98-GT-381. 392. Le Gal, J-H.: Development of a Dual Fuel Catalytic Combustor for a 2.3 MWe Gas Turbine. ASME 98GT-294. 393. Lipinski, J. J.: Development and Test of a Catalytic Combustor for an Automotive Gas Turbine. ASME 98-GT-390. Emissionen 394. Cannon, S.-M.: Stochastic modeling of CO and NO in premixed methane combustion. Combustion and Flame, 113/1998, 1/2, S. 135-146. 395. Facchini, B.: A Semi-Analytical Approach to Emissions Prediction in Gas Turbine Combustors. ASME 98-GT-216. 396. Botros, K. K.: One-Dimensional Model to Quantify NOx Reduction in Gas Turbines Using EGR. ASME 98-GT-270. 397. -: Studies of NOx Formation in Two-Stage Methane-Air Flames. ASME 98-GT-073. 398. Hasegawa, T.: A Study of Low NOx Combustion in Medium-Btu Fueled 1300° C class Gas Turbine Combustor in IGCC. ASME 98-GT-331. 399. Audus, H.: Technologies for Reducing Greenhouse Gas Emissions from Fossil Fuels. ASME 98-GT-074. 400. Li, S. C.: Experimental and Numerical 401. Poppe, C.: Control of NO(x) emissions in confined flames by oscillations. Combustion and Flame, 113/1998, 1/2, S. 13-26. 402. Osenga, M.: Emissions Reduction To 3.5 ppm Nox. Diesel & Gas Turbine Worldwide 1-2 1998, S. 44-46. 403. Urbach, H. B.: Water Injection into Navy Gas-Turbine Combustors to Reduce NOx Emissions. ASME 98GT-298. 404. Topaloglu, B.: Stickoxide bei der Verbrennung; BWK 50 (1998) 9, S. 47-51. Brennstoffe, Sonderbrennstoffe Zerstäubung von flüssigen Brennstoffen 405. Purcell, J.: Liquid Fuels for Gas Turbines and Their Effects on Fuel System Reliability. Power-Gen Europe 98. 406. Yeoung, M. H.: Effects of Fuel Nozzle Displacement on Pre-Filming Airblast Atomization. ASME 98-GT360. 407. O’Shaughnessy, P.: Injector Geometry Effect on Plain Jet Airblast Atomization. ASME 98-GT-445. 408. Chin, J. S.: Study on High Liquid Pressure Internal Mixing Prefilming Airblast Atomization. ASME 98-GT442. 409. Liao, Y.: A Comprehensive Model to Predict Simplex Atomizer Performance. ASME 98-GT-441. 410. Benjamin, M. A.: Film Thickness, Droplet Size Measurements and Correlations for Large Pressure-Swirl Atomizers. ASME 98-GT-537. 411. Ibrahim, M.: Spray Characteristics of an Airblast-Simplex Nozzle for Liquid-Fueled Gas Turbine Combustors. ASME 98-GT-517. 412. Rosskamp, H.: Effect of the Shear Driven Liquid Wall Film on the Performance of Prefilming Airblast Atomizers. ASME 98-GT-500. 413. Karbasi, M.: The effects of hydrogen addition on the stability limits of methane jet diffusion flames. International Journal of Hydrogen Energy, 23/1998, 2, S. 123-129. 414. Brushwood, J. S.: A Combined Cycle Power Generation / Alfalfa Processing System: Part 1: Development & Testing. ASME 98-GT-335. Sonderbrennstoffe 415. Bannister, R. L.: Final Report on the Development of a Hydrogen-Fueled Combustion Turbine Cycle for Power Generation. ASME 98-GT-021. 416. Aoki, S.: A Study of Hydrogen Combustion Turbines. ASME 98-GT-392. 417. Narula, R. G.: Alternative Fuels for Gas Turbine Plants. An Engineering, Procurement, and Construction Contractor’s Perspective. ASME 98-GT-122. 418. Morris, J. D.: Combustion Aspects of Application of Hydrogen and Natural Gas Fuel Mixtures to MS9001E DLN-1 Gas Turbines at Elsta Plant, Terneuzen, The Netherlands. ASME 98-GT-359. 419. Moliére, M.: Volatile, Low Lubricity Fuels in Gas Turbine Plants: A Review of Main Fuel Options and Their Respective Merits. ASME 98-GT-231. 420. Smith, A. R.: Air Separation Unit Integration for Alternative Fuel Projects. ASME 98-GT-063. 421. Heilos, A.: Combustion of Refinery Residual Gas with a Siemens V94.2 (K) Burner. Power-Gen Europe 98. 422. Sperkac, I.-E.: Möglichkeiten zur Modernisierung des Komplexes von Ausrüstungen für die Aufbereitung und Verwertung des Hochofengases. Stal, 68/1998, 1, S. 7-11. 423. Chellini, R.: Low Btu Gas for Combined-Cycle Plant; Diesel & Gas Turbine Worldwide 6 1998, S. 12-15. 424. Pourchot, T.: Heavy Duty Gas Turbines in LCV Applications: 25 Years of Experience and Development. Power-Gen Europe 98. 425. Benter, M. M.: Low Ash Fuel and Chemicals From the Convertech Process. ASME 98-GT-351. 426. Huth, M.: Verbrennung von Synthesegas in Gasturbinen; BWK 50 (1998) 9, S. 35-39. Biomasse 427. Patnaik, P. C.: Elevated Temperature Exposure of Gas Turbine Materials to a Bio-fuel Combustion Environment. ASME 98-GT-164. 428. Schmidt, E. R.: Large-Scale Handling and Use of Solid Biofuels, ASME 98-GT-327. 429. Craig, J. D.: A Small Scale Biomass Fueled Gas Turbine Engine. ASME 98-GT-315. 430. Arcate, J. R.: Biomass Charcoal Co-Firing with Coal. ASME 98-GT-226. 431. Cavani, A.: Modified Humid Air Turbine Cycle for Biomass Gasification. ASME 98-GT-233. 432. Waldheim, L.: Update on the Progress of the Brazilian Wood BIG-GT Demonstration Project. ASME 98GT-472. 433. Neilson, Ch. E.: LM2500 Gas Turbine Fuel Nozzle Design and Combustion Test Evaluation & Emission Results with Simulated Gasifire Wood Product Fuels. ASME 98-GT-337. 434. Johansson, E. M.: Development of Hexaaluminate Catalysts for Combustion of Gasified Biomass in Gas Turbines. ASME 98-GT-338. 435. Kilpinen, P.: Staged Combustion of Air-Blown Biomass Gasification Gas in Gas Turbines - a Kinetic Modelling Study of Nitrogen Oxide Control; VDI Berichte Nr. 1438 (1998), S. 167-176. 436. Salo, K.: Pressurized Gasification of Biomass. ASME 98-GT-439. 437. Larson, E. D.: Combined Biomass and Black Liquor Gasifier/Gas Turbine Cogeneration at Pulp and Paper Mills. ASME 98-GT-339. 438. Ahlroth, M.: Case Study on Simultaneous Gasification of Black Liquor and Biomass in a Pulp Mill. ASME 98-GT-350. 439. Larson, E. D.: Preliminary Economics of Black Liquor Gasifier/Gas Turbine Cogeneration at Pulp and Paper Mills. ASME 98-GT-346. Kohlenutzung in Gasturbinen 440. Storm, Ch.: Co-Pyrolysis of Coal/Biomass and Coal/Sewage Sludge Mixtures. ASME 98-GT-103. 441. Green, A. E. S.: Feedstock Blending Studies with Laboratory Indirectly Heated Gasifiers. ASME 98-GT574. 442. Peres, S.: Catalytic Indirectly Heated Gasification of Bagasse. ASME 98-GT-161. 443. Newby, R. A.: Status of Westinghouse Hot Gas Filters for Coal and Biomass Power Systems. ASME 98GT-340. 444. Robson, F. L.: Advanced Aeroderivative Gas Turbines in Coal-Based High Performance Power Systems (HIPPS). ASME 98-GT-131. 445. Wang, T.: Effect of Air Extraction for Cooling and/or Gasification on Combustor Flow Uniformity. ASME 98-GT-102. 446. Hoppesteyn, P.D.J.: Biomass/Coal Derived Gas Utilization in a Gas Turbine Combustor. ASME 98-GT160. Kohlevergasung 447. Baumann, II. R.: Development of the Cost-Effective IGCC Power Plant. Power-Gen Europe 98. 448. Farina, G.: Optimisation of the Degree of Integration of IGCC Design.Power-Gen Europe 98. 449. Pinacci, P.: A Commercial Project for Private Investments; Update of the 280 MW API Energia IGCC Plant Construction in Central Italy. Power-Gen Europe 98. 450. Huth, M.: Siemens Gas Turbine Operating Experience with Coal Gas in the IGCC in Buggenum. PowerGen Europe 98. 451. Chiesa, P.: Shift Reactors and Physical Absorption for Low-CO2 Emissions IGCCs. ASME 98-GT-396. 452. Collodi, G.: Progress of the Sarlux IGCC Project. Power-Gen Europe 98. 453. Joos, E.: Puertollano IGCC Power Plant Analysis of Performance Test Data. Power-Gen Europe 98. 454. Newby, R. A.: Fuel Gas Cleanup Parameters in Air-Blown IGCC. ASME 98-GT-341. 455. Minchener, A. J.: An Overview of Recent Clean Coal Gasification Technology R&D Activities Supported by the European Commission. ASME 98-GT-163. 456. Gaio, G.: Energieerzeugung durch Kohle- und Schwerölrückstandsvergasung mit anschließender Verbrennung in Siemens Gasturbinen; VDI Berichte Nr. 1438 (1998), S. 143-149. Druckwirbelschichten 457. Nemet, A.: Die Gasturbine in der Druckwirbelschichtfeuerung; VDI Berichte Nr. 1438 (1998), S. 151-166. 458. Romeo, L.: Operational and Design Strategies to Improve PFBC Power Plant Efficiency. Power-Gen Europe 98. 459. Lundqvist, R.: Repowering and Retrofilting of Old Power Plants with Circulating Fluidised Bed Technology in Central and Eastern Europe. Power-Gen Europe 98. 460. Luby, P.: Contribution of IGCC & PFCB to Global Fuel Consumption Trends. Power-Gen Europe 98. 461. Kaneko, S.: Operating Experience of First Commercial PFBC in Japan and its Future Application. PowerGen Europe 98. 462. Pai, D.: Advanced Pressurised Circulating Fluidised Bed Technology. Power-Gen Europe 98. 463. Testi, A.: Performance of a Pressurised Fluidised Bed Combined Cycle Using High Sulphur Content Coals. Power-Gen Europe 98. 464. Jong de, W.: Coal Biomass Gasification in a Pressurized Fluidized Bed Gasifier. ASME 98-GT-159. 465. Collot, A-G.: Co-Pyrolysis and Co-Gasification of Coal and Biomass in a Pressurized Fixed-Bed Reactor. ASME 98-GT-162. Kombiprozesse 466. Ortmann, P.: Optimisation of Combined Cycle Power Plant Operation with Degraded Compressor and Heat Recovery Boiler Efficiency; VDI Berichte Nr. 1438 (1998), S. 199-220. 467. Franke, U.: Zur thermodynamischen Prozeßoptimierung; BWK 50 (1998) 1/2, S. 54-58. 468. Kurzke, J.: Gas Turbine Cycle Design Methodology: A Comparison of Parameter Variation with Numerical Optimization. ASME 98-GT-343. 469. Longhi, A.: Combined Cycle Power Plants Close to Gas Fields or to Electricity Final Users? Power-Gen Europe 98. 470. Antonini,C.: New Combined Cycle Plants Experience in Commissioning and Operation, Technical and Economical Results. Power-Gen Europe 98. 471. Jeske, H.-O.: Ein modulares, standardisiertes Kraftwerkskonzept auf der Basis von Dampf- und Gasturbinen. VGB Kraftwerkstechnik 78 (1998) 6, S. 49-54. 472. Scherzer, St.: GuD-Anlagen für kommunale und industrielle Energieversorgung Teil 1: Planungsüberlegungen. VGB Kraftwerkstechnik 78 (1998) 8, S. 40-43. 473. Koch, J.: Improved Combined-Cycle Economics Through Marginal Pricing with Variable Gas Turbine Firing Temperature Control, Power-Gen International 1998, 2.D.3. 474. Hanawa, K.: Thermodynamic Performance Analysis of Mixed Gas-Steam Cycle (1): Performance Prediction Method. ASME 98-GT-117 475. Hanawa, K.: Thermodynamic Performance Analysis of Mixed Gas-Steam Cycle (2): A Case Study of Aeroderivative Gas Turbine. ASME 98-GT-118. 476. Sheard, A.: The Combined Cycle Application of Aeroderivative Gas Turbines. Power-Gen Europe 98. 477. Finckh, H.: Perspective of the Next Generation of Combined-Cycle Processes, Power-Gen International 1998, 2.D.1. Anlagen 478. Robinson, B.: The First Mechant Plant in Massachusetts Dighton CC-Single Shaft-GT11N2, Power-Gen International 1998, 2.D.4. 479. Mattes, K.: Sacramento Power Authority Project-Execution and Operation of the Cleanest Power Plant of its Class in the World, Power-Gen International 1998, 2.C.1. 480. Baumgartner, R.-J.: Bridgeport Energy: 520 MW Combined-Cycle Power Plant, Power-Gen International 1998, 2.C.4. 481. Magneschi, P.: La Spezia Power Plant: Transformation of Units 1 & 2 to Combined Cycle with Modification of the Steam Turbines from Cross Compound to Tandem Compound. Power-Gen Europe 98. 482. Dumoulin, J.: The Eems Project (1675MW); From Feasibility to Reality. Power-Gen Europe 98. 483. Kotschenreuther, H.:Combined Cycle Power Plant of Schwarze Pumpe - Operating Experience Gained with Low Calorific Value Fuel Resulting from Gasification Processes. Power-Gen Europe 98. 484. Galaberi, B.: Acceptance Tests of 3 Combined Cycles at the Taranto Steel Factory. Power-Gen Europe 98. 485. d’Izarny-Gargas, L.: The Tarragone Power Plant. Power-Gen Europe 98. 486. Zachary, J.: Sacramento Power Authority Project - Experience of Building and Testing a Combined Cycle Project with Emissions less than 3 PPM NO. Power-Gen Europe 98. 487. Jonas, K.: Der Umbau des Kraftwerkes VEO Eisenhüttenstadt zu einem Kombi-Kraftwerk für die industrielle und öffentliche Energieversorgung. VGB Kraftwerkstechnik 78 (1998) 8, S. 34-39. 488. Gebert, H.: Betriebserfahrungen mit dem Kombi-Kraftwerk HKW Mitte, Berlin. VGB Kraftwerkstechnik 78 (1998) 7, S. 31-36. 489. Kolp, D. A.: LM2500+ Single Shaft Combined Cycle with Frequency Stabilization. ASME 98-GT-418. 490. Pfleger, C.: Operation Record of the Large 9FA Based CCGT Built in Europe. Power-Gen Europe 98. 491. Chellini, R.: 100 MW, Single-Shaft Combined-Cycle Block Available; Diesel & Gas Turbine Worldwide 6 1998, S. 76-77. 492. Murphy, J. C.: Barge Mounted Combined-Cycle Plants, Power-Gen International 1998, 2.C.5. Repowering 493. Barik, M.: Optimization of Turbine Blade Flow Path for Combined-Cycle Repowering, Power-Gen International 1998, 2.D.5. 494. Bauer, G.: Ertüchtigung bestehender Dampfkraftwerke durch Gasturbinen; BWK 50 (1998)1/2, S. 32-36. 495. Clerici, A.: Transformation into Combined Cycle of Old Steam Plants in an Competitive Market. PowerGen Europe 98. 496. Pfost, H.: Gas Turbines Increase Power and Efficiency of Steam Power Plants. Power-Gen Europe 98 Fortschrittliche Kreisprozesse 497. Cavenagh, A.: Helium hope. A helium cooled reactor with gas turbine technology could boost nuclear energy as pressure builds to cut CO2 emissions. The Engineer, 286/1998, 7383/4, S. 26-27. 498. Kizuka, N.: Conceptual Design of the Cooling System for 1700°C-Class Hydrogen-Fueled Combustion Gas Turbines. ASME 98-GT-345. 499. Penninger, A.: Moderne 500 MW Spitzlastkraftwerkanlage mit Pressluft-Energiespeicherung; VDI Berichte Nr. 1438 (1998), S. 255-258. 500. Deckamps, P.: Experience Gained on the Demonstration Unit of a Once-Through Supercritical Heat Recovery Steam Generator. Power-Gen Europe 98. 501. Oggero, L.: A Novel Optimisation Method for Variable Cycle Jet Engines. ASME 98-GT-142. 502. Humphries, J. J.: Multi-Cycle Plus Energy Generation for Large Industrials, Power-Gen International 1998, 2.C.2. 503. Negri di Montenegro, G.: Intercooled and Brayton Cycle Gas Turbines for Steam Power Plant Hot Windbox Repowering. ASME 98-GT-198. 504. McNeely, M.: Intercooling for LM6000 Gas Turbines; Diesel & Gas Turbine Worldwide 7-8 1998, S. 4245. 505. Hisazumi, Y.: Proposal of a Novel Gas Turbine System with High Generation Efficiency by Using Two Stages Combustion and Steam Injection. Power-Gen Europe 98. 506. Hofstädter, A.: Effects of Steam Reheat in Advanced Steam Injected Gas Turbine Cycles. ASME 98-GT584. 507. De Paepe, M.: Economic Analysis of Condensers for water Recovery in Steam Injected Gas Turbines. Power-Gen Europe 98. 508. Paepe de, M.: Industrial Application of Water Recovery in Steam Injected Gas Turbines; VDI Berichte Nr. 1438 (1998), S. 241-250. Rekuperative Zyklen 509. Utriainen, E.: Recuperators in Gas Turbine Systems. ASME 98-GT-165. 510. Horlock, J. H.: The Effect of Heat Exchanger Effectiveness and Exergy Loss in the Estimation of Cycle Efficiency. ASME 98-GT-352. 511. Behrens, D.: Gasturbinenprozesse mit variabler Rekuperation; VDI Berichte Nr. 1438 (1998), S. 229240. 512. Carcasci, C.: Design & Off-Design Analysis of a CRGT Cycle Based on the LM2500-STIG Gas Turbine. ASME 98-GT-036. 513. Lefcort, M. D.: Sawmill, Wood Waste Fuelled, 100 % Recuperated, 5 MW Gas Turbine Co-Generation Plant. ASME 98-GT-062. 514. Abdallah, H.: Part Load Performance of Chemically Recuperated Gas Turbine Cycles Compared to Other Advanced Cycles. ASME 98-GT-037. 515. Arai, N.: Development of Highly Efficient Gas Turbine Systems: the Chemical Gas Turbine System. Power-Gen Europe 98. 516. Carcasci, C.: Design Issues for the Methane-Steam Reformer of a Chemically Recuperated Gas Turbine Cycle. ASME 98-GT-035. Geschlossene und halbgeschlossene Zyklen 517. Corti, A.: Absorption of CO2 with Amines in a Semiclosed GT Cycle: Plant Performance and Operating Costs. ASME 98-GT-395. 518. Chiesa, P.: CO2 Emission Abatement in IGCC Power Plants by Semiclosed Cycles. Part A: With Oxygen-Blown Combustion. ASME 98-GT-384. 519. Chiesa, P.: CO2 Emission Abatement in IGCC Power Plants by Semiclosed Cycles. Part B: With AirBlown Combustion and CO2 Physical Absorption. ASME 98-GT-385. 520. Veld op het, R. P.: An Empirical Approach to the Preliminary Design of a Closed Cycle Gas Turbine. ASME 98-GT-393. Humid Air Technologie 521. Corti, A.: Semi Closed Gas Turbine Cycle and Humid Air Turbine: Thermoeconomic Evaluation of Cycle Performance and of the Water Recovery Process. ASME 98-GT-031. 522. Facchini, B.: A Parametric Study of CHAT Cycle Performance: Thermodynamic and Design Features. ASME 98-GT-166. 523. Nakhamkin, M.: CHAT Technology: An Altenative Approach to Achieve Advanced Turbine Systems Efficiencies with Present Combustion Turbine Technology. ASME 98-GT-143. 524. Desideri, U.: Humid Air Turbine Cycles with Water Recovery: How to Dispose Heat in an Efficient Way. ASME 98-GT-060. 525. Song, C. H.: Performance Enhancement of a Gas Turbine with Humid Air and Utilization of LNG Cold Energy. ASME 98-GT-058. Kombination mit Brennstoffzellen 526. Campanari, S.: Thermodynamic Analysis of Advanced Power Cycles Based Upon Solid Oxide Fuel Cells, Gas Turbines and Rankine Bottoming Cycles. ASME 98-GT-585. 527. -: Brennstoffzellen-Kraftwerke. Westinghouse stellt SOFC-Prototyp vor. Blick durch die Wirtschaft, 41/1998, 36, 20.02.98, S. 6. 528. Massardo, A. F.: Internal Reforming Solid Oxide Fuel Cell-Gas Turbine Combined Cycles (IRSOFC-GT) Part A: Cell Model and Cycle Thermodynamic Analysis. ASME 98-GT-577. Indirekt gefeuerte Gasturbinen 529. Crosa, G.: Steady-State and Dynamic Performance Prediction of an Indirect Fired Gas Turbine Plant. ASME 98-GT-167 Andere Prozesse 530. Kellerer, A.: Betriebserfahrungen mit einer Cheng-Cycle-Anlage - Konzept und technische Besonderheiten des Cheng Cycles, Betriebserfahrungen. VGB Kraftwerkstechnik 78 (1998) 11, S. 4652. 531. Strasser, A.: First Small Size Cheng Cycle Series 5 Cogeneration System Installed in Europe. PowerGen Europe 98. 532. Jericha, H.: Graz-Cycle - eine Innovation zur CO2-Minderung; BWK 50 (1998) 10, S. 30-34. 533. Mathieu, Ph.: Zero Emission Matiant Cycle. ASME 98-GT-383. 534. Camporcale, S.: Uprate of an Industrial Gas Turbine to Evaporative Cycle. Power-Gen Europe 98. 535. Dalili, F.: Design of Tubular Humidifiers for Evaporative Gas Turbine Cycles. ASME 98-GT-203. 536. Dobrowolski, R.: New Combined Cycle with Integrated Solar Heat. Power-Gen Europe 98. 537. Korobitsyn, M. A.: Analysis of a Gas Turbine Cycle with Partial Oxidation. ASME 98-GT-033. 538. Gustafsson, J.-O.: Transient Analysis of a Small Gas Turbine to be Used in an Evaporative Cycle. ASME 98-GT-353. 539. Kuosa, M.: Refrigeration Process with High Speed Technology. ASME 98-GT-532. Kraft-Wärme-Kopplung 540. Vandesteene, J.-L.: GasTurbine Based Cogeneration Facilities: Key Issues to Be Addressed at an Early Design Stage. Power-Gen Europe 98. 541. Teodorescu, C.: Gas Turbines Cogeneration Power Plant: the Criteria and Method of the Choice for Plant Structure. Power-Gen Europe 98. 542. Reppen, D.: Benefits of Optimizing Thermal and Electrical Energy Production in a Cogeneration Facility, Power-Gen International 1998, 2.C.3. 543. Sheikh, A.: Project Optimisation and Construction of Cogeneration Power Plant for a Large Refinery and Petrochemical Complex in India. ASME 98-GT-200. 544. Haag, F.: Energie muß nicht teuer sein. Mit Wärmekraftkopplung zum Selbstversorger. Schweizer Maschinenmarkt, 1998, 4, S. 30-32. 545. Ruhl, H.: Modernes Versorgungskonzept (Wärme/Strom) für die Region. Das Wärmeverbundkraftwerk Freiburg (D.). Gas, Wasser, Abwasser, 78/1998, 2, S. 92-95. 546. Mercer, M.: Cogeneration Package Cuts VOC Emissions; Diesel & Gas Turbine Worldwide 6 1998, S. 38-40. 547. Minychthaler, G.: Der Betrieb der Kraft-Wärme-Kopplung in den Kraftwerken von WIENSTROM. VGB Kraftwerkstechnik 78 (1998) 5, S. 102-106. 548. Yokoyama, R.: Analysis of Cooperation between Central Power Utility and Dispersed Cogeneration Systems Through Time-of-Use Pricing. ASME 98-GT-199. 549. Gailfuß, M.: Stand der BHKW-Technologie; BWK 50 (1998) 9, S. 40-43. 550. Gailfuss, M.: Zukünftige BHKW-Potentiale in Deutschland. Eine Prognose für das Jahr 2010. Wärmetechnik - Versorgungstechnik, 43/1998, 1, S. 45-51. 551. Chodkiewicz, R.: Electric Power and Nitric Acid Coproduction a New Concept in Reducing the Energy Cost. Power-Gen Europe 98. Fahrbare und Marine Anwendung 552. Berenyi, St. G.: Hybrid Vehicle Turbine Engine Technology Support (HVTE-TS) Program 1997-98 Progress. ASME 98-GT-451. 553. O’Brien, P.: Development of a 50-KW, Low-Emission Turbogenerator for Hybrid Electric Vehicles. ASME 98-GT-400. 554. Sexton, M. R.: Evaporative Compressor Cooling for NOx Suppression and Enhanced Engine Performance for Naval Gas Turbine Propulsion Plants. ASME 98-GT-332. 555. Plugnikov, V.: Combined-Cycle Propulsion Plant Uprated in Ship Conversion; Diesel & Gas Turbine Worldwide 10 1998, S. 22-24. 556. Zoccoli, M. J.: Development of the Next Generation Gas Turbine Based Jet Air Start Unit for the US Navy. ASME 98-GT-084. 557. Luck, D. L.: Extending Use of Marine Gas Turbines through Application of the LM2500+. ASME 98-GT041. 558. Carter, M.: A 21st Century Warship With a 21st Century Propulsion System. ASME 98-GT-437. 559. Chellini, R: Gas Turbine Power for Cruisers; Diesel & Gas Turbine Worldwide 7-8 1998, S. 38-39 560. Clevenger, M. T.: Turbines Provide Premium Speeds for Passenger Ferry; Diesel & Gas Turbine Worldwide 3 1998, S. 46 561. Kazatzis, P.: A Novel and Compact Marine Gas Turbine Propulsion System. ASME 98-GT-057. 562. Younghans, J. L.: Preliminary Design of Low Cost Propulsion Systems Using Next Generation Cost Modeling Techniques. ASME 98-GT-182. 563. Huete, J. I.: A New Propulsion System Proposal for Civil Supersonic Transport: The Retractable Fan Concept. ASME 98-GT-059. 564. Waldhelm, Ch.: Application of Gas Turbines on Floater Vessel for Power Generation Service. ASME 98GT-277. 565. Waldhelm, Ch.: Design Features of Gas Turbine Systems Applied to Floating Production Storage and Off-Loading (FPSO) Vessels. ASME 98-GT-330. Regelung 566. Wadman, B.: Controls Upgraded for Improved Reliability; Diesel & Gas Turbine Worldwide 9 1998, S. 71. 567. Martucci, A.: Fault Detection and Accommodation in Real Time Embedded Full Authority Digital Electronic Engine Controls. ASME 98-GT-155. 568. Simani, S.: Fault Detection and Isolation Based on Dynamic Observers Applied to Gas Turbine Control Sensors. ASME 98-GT-158. 569. Camporeale, S. M.: Dynamic Modeling and Control of Regenerative Gas Turbines. ASME 98-GT-172. 570. Peres-Blanco, H.: A Gas Turbine Dynamic Model for Simulation and Control. ASME 98-GT-078. 571. Vroemen, B. G.: Nonlinear Model Predictive Control of a Laboratory Gas Turbine Installation. ASME 98GT-100. 572. Thompson, H. A.: Multi-Objective Optimisation of Systems Architectures for Distributed Aero-Engine Control Systems. ASME 98-GT-045. 573. Shaffer, Ph. L.: Distributed Control System for Turbine Engines. ASME 98-GT-016. 574. Kozuhowski, H. J.: Integrated Testing of the Full Authority Digital Control and Redundant Independent Mechanical Start System for the U.S.Navy’s DDG-51 Ship Service Gas Turbine Generator Sets. ASME 98-GT-273. 575. Schley, W. R.: Distributed Flight Control & Propulsion Control Implementation Issues & Lessons Learned. ASME 98-GT-003. 576. Lorenz, W.: Development of a Smart Actuator for Turbine Engine Applications. ASME 98-GT-044. 577. Sobanski, K.: Gas Turbine Distributed Control Systems: Power Supply and Communication Data Bus Design Considerations. ASME 98-GT-414. 578. Grzybowski, R. R.: High Temperature Silicon Integrated Circuits and Passive Components for Commercial and Military Applications. ASME 98-GT-362. Aktive Regelung 579. Jackson, M. D.: Active Control of Combustion for Optimal Performance. ASME 98-GT-576. 580. Cohen, J. M.: Active Control of Combustion Instability in a Liquid - Fueled Low - NOx Combustor. ASME 98-GT-267. 581. Hope, R. W.: Adaptive Vibration Control of Industrial Turbomachinery. ASME 98-GT-405. 582. Perkavec, M.: Aktive Regelung von Gasturbinen; VDI Berichte Nr. 1438 (1998), S. 177-188. Betrieb Ausgeführte Anlagen 583. Dorra, H.: Betriebserfahrungen einer 40-MW-Gasturbine in der Papierindustrie; VDI Berichte Nr. 1438 (1998), S. 123-129. 584. Stein, P.: Erfahrungen aus dem Einsatz von Gasturbinen in einem Zementwerk; VDI Berichte Nr. 1421 (1998), S. 289-301. 585. Dopf, W.: Fernheizkraftwerk Linz-Süd - 4 Jahre Betriebserfahrung, erzielte Ergebnisse; VDI Berichte Nr. 1438 (1998), S. 79-91. 586. Heinisch, M.: Erfahrungen aus der Planung, der Inbetriebnahme und dem ersten Betriebsjahr des GuDKraftwerks des Gemeinschaftskraftwerk Tübingen GmbH; VDI Berichte Nr. 1438 (1998), S. 93-121. 587. Necker, P.: Bauüberwachung, Qualitätssicherung, Betriebserfahrungen mit dem neuen Heizkraftwerk II; VDI Berichte Nr. 1421 (1998), S. 47-74. 588. Svatck, J.: Results of the GT Prime Program Improvements to General Electric MS7001B Gas Turbines at the Houston Light and Power T.H. Wharton Site. ASME 98-GT-450. 589. Blomberg, G.: Fast-track Redeployment of AVON Quad-pack Improves Island’s Backup Power System. ASME 98-GT-455. 590. Brito, I.: Gas Turbine Spinning Reserve Operation to Support Frequency Drops in Small Grid. ASME 98GT-448. 591. Beyene, A.: Comparative Analysis of Gas Turbine Engine Starting. ASME 98-GT-419. Monitoring und Diagnose 592. McKay, I.: TIGER: Intelligent Continuous Monitoring of Gas Turbines. Power-Gen Europe 98. 593. Seeliger, J.: Condition Monitoring im Kraftwerk VDI Berichte Nr. 1421 (1998), S. 75-93. 594. Kosmann, G. P.: On-Line & Off-Line Steam Turbine Component Strain States Monitoring for the Diagnostic System. ASME 98-GT-456. 595. Hastings, M. M.: Integrated Condition Monitoring System Strategy at CEMEG. ASME 98-GT-129. 596. Wadman, B.: Advances in Gas Turbine Monitoring; Diesel & Gas Turbine Worldwide 9 1998, S. 58-60. 597. Eftekhari, K.: An Open Approach to Condition Monitoring, Diagnosis, and Decision Support Systems. ASME 98-GT-156. 598. DePold, H. R.: The Application of Expert Systems and Neural Networks to Gas Turbine Prognostics and Diagnostics. ASME 98-GT-101. 599. Gluch, J.: Searching for Inefficient Components of Complex Power Systems. ASME 98-GT-076. 600. Stalder, J.-P.: Gas Turbine Compressor Washing - State of the Art - Field Experiences. ASME 98-GT420. Zuverlässigkeit und Verfügbarkeit 601. Bernstein, W.: Zuverlässigkeit und Verfügbarkeit von Gasturbinenanlagen - ein notwendiges Qualitätsmerkmal für Hersteller und Betreiber; VDI Berichte Nr. 1438 (1998), S. 49-62. 602. Klemp, K.: Experience in Industrial Gas Turbine Operation with Special Respect to Availability. PowerGen Europe 98. 603. Boley, W. M.: FT8 Phase II Reliability Improvement Program. ASME 98-GT-417. 604. Ali, Sy A.: Ultra-High Efficiency Power Systems with Near-Term Commercial Availability. ASME 98-GT452. Instandhaltung 605. Chellini, R.: Global Maintenance for Gas Turbines; Diesel & Gas Turbine Worldwide 6 1998, S. 44. 606. Birch, P. W.: Quality of both maintenance and breakdown provision for a 3.65 MWe gas turbine CHP plant: The Liverpool Experience; VDI Berichte Nr. 1438 (1998), S. 131-141. Störungen und Schäden 607. -: Tiger Tracks Faults on Gas Turbines; Diesel & Gas Turbine Worldwide 9 1998, S. 20-22. 608. -: Ice Detection System for Gas Turbines; Diesel & Gas Turbine Worldwide 9 1998, S. 42. 609. Hargrave, S. M.: The Use of Case-Based Reasoning Technology to Aid Fault Isolation in a Modern Gas Turbine Engine Design. ASME 98-GT-061. 610. Koubogiannis, D. G.: A Parallel CFD Tool to Produce Faulty Blade Signatures for Diagnostic Purposes. ASME 98-GT-169. 611. Yoshida, H.: Experiment on Foreign Object Damage of Gas Turbine-Grade Silicon Nitride Ceramic. ASME 98-GT-399. 612. Valk, M.: Schäden an Strömungsmaschinen; VDI Berichte Nr. 1421 (1998), S. 1-23. 613. Lange, G.: Beispiele für Schäden an Flugtriebwerken; VDI Berichte Nr. 1421 (1998), S. 243-266. 614. Busch, H.-G.: Beispielhafte Schäden an stationären Gasturbinen; VDI Berichte Nr. 1421 (1998), S. 267287. Festigkeit Rotordynamik 615. Casanova, E. L.: Analysis of an Accelerating Rotor-Bearing System with Flexible Damped Supports. ASME 98-GT-411. 616. Vazquez, J. A.: Representing Flexible Supports by Polynomial Transfer Functions. ASME 98-GT-027. 617. Yakoub, R. Y.: A Fast Method to Obtain the Nonlinear Response of Multi-Mode Rotors Supported on Squeeze Film Dampers Using Planar Modes - Part I: Theory. ASME 98-GT-412. 618. Yakoub, R. Y.: A Fast Method to Obtain the Nonlinear Response of Multi-Mode Rotors Supported on Squeeze Film Dampers Using Planar Modes - Part II: Parametric Studies. ASME 98-GT-413. 619. Santiage de, O.: Imbalance Response of a Rotor Supported on Open-Ends Integral Squeeze Film Dampers. ASME 98-GT-006. 620. Arghir, M.: A Quasi 2D Method for the Rotordynamic Analysis of Centered Labyrinth Liquid Seals. ASME 98-GT-005. 621. Soto, E. A.: Experimental Rotordynamic Coefficient Results for (a) A Labyrinth Seal with and without Shunt Injection and (b) A Honeycomb Seal. ASME 98-GT-008. 622. Darden J. M.: Experimental Rotordynamic Characterization of Annular Seals: Facility and Methodology. ASME 98-GT-017. 623. Vazquez, J. A.: Comparison Between Calculated and Measured Free-Free Modes for a Flexible Rotor. ASME 98-GT-051. 624. Florjancic, St. S.: Vibration Measurement Techniques on an Industrial Gas Turbine Rotor Train. ASME 98-GT-297. 625. Behzad, M.: Accuracy of the Riccati Transfer Matrix Method in Rotor Dynamic Analysis. ASME 98-GT513. 626. Haq, I. U.: Identification of the Intermittent Synchronous Instability in a High Performance Steam Turbine Rotor Due to Deteriorated Labyrinth Seals. ASME 98-GT-305. 627. Memmott, E. A.: Stability Analysis and Testing of a Train of Centrifugal Compressors for High Pressure Gas Injection. ASME 98-GT-378. Scheiben 628. Kuang, J. H.: Mode Localization of a Cracked Blade-Disks. ASME 98-GT-105. 629. Bladh, R.: Reduced Order Modeling and Vibration Analysis of Mistuned Bladed Disk Assemblies with Shrouds. ASME 98-GT-484. 630. Kaneko, Y.: Vibrational Response Analysis of Mistuned Bladed Disk System of Grouped Blades. ASME 98-GT-410. 631. Cha, D.: Statistics of Response of a Mistuned Bladed Disk Assembly Subjected to White Noise and Narrow Band Excitation. ASME 98-GT-379. 632. Mignolet, M. P.: Identification of Mistuning Characteristics of Bladed Disks from Free Response Data. ASME 98-GT-583. 633. Gärtner, W.: A Momentum Integral Method to Predict the Frictional Torque of a Rotating Disk with Protruding Bolts. ASME 98-GT-138. 634. Maeng, D. J.: Characteristics of Discharge Coefficient in a Rotating Disk System. ASME 98-GT-266. 635. Cairo, R. R.: Twin Web Disk: A Step Beyond Convention. ASME 98-GT-505. Schaufelschwingungen 636. Yang. B. D.: Prediction of Resonant Response of Shrouded Blades with 3D Shroud Constraint. ASME 98-GT-485. 637. Chen, J. J.: Prediction of the Resonant Response of Frictionally Constrained Blade Systems Using Constrained Mode Shapes ASME 98-GT-548. 638. Chiang, H.-W.D.: A Cyclic Symmetry Analysis for Turbomachine Blade Flutter. ASME 98-GT-052. 639. Liu, Sh.Ji + F.: Computation of Flutter of Turbomachinery Cascades Using a Parallel Unsteady NavierStokes Code. ASME 98-GT-043. 640. Blaswich, M.: Effects of Variable Inlet Guide Vane Settings on Axial Compressor Blades Vibration in an Industrial Gas Turbine. ASME 98-GT-361. 641. Sensmeier, M. D.: Minimizing Vibratory Strain Measurement Error. ASME 98-GT-257. Werkstoffe 642. Schulenberg, T.: New Development in Land-Based Gas Turbine Technology; Materials for Advanced Power Engineering 1998, O16. 643. Ramaswarry, V.: Materials Advancements in Land-Based Gas Turbines, Power-Gen International 1998, 2.D.2. 644. Härkegärd, G.: Disc Materials for Advanced Land-Based Gas Turbines; Materials for Advanced Power Engineering 1998, O20. 645. Nazmy, M. Y.: Gamma TiAl Intermetallic for Gas Turbine Applications; Materials for Advanced Power Engineering 1998, O21. 646. Naka, S.: Considerations of Solidification Paths and Development of new Castable Gamma Titanium Aluminides; Materials for Advanced Power Engineering 1998, O22. 647. Tabakoff, W.: Erosion Rate Testing at High Temperature of Alloys and Coatings For Use in Turbomachinery. ASME 98-GT-025. 648. Stamm, W.: Thermomechanische Ermüdung beschichteter Einkristallwerkstoffe VDI Berichte Nr. 1421 (1998), S. 303-322. 649. Barykin, B.-M.: Effektive Wärmeleitfähigkeit von Zirkondioxid bei hohen Temperaturen. Teplofizika Vysokich Temperatur, 36/1998, 1, S. 44-47. 650. Mannan, S.: Long Term Thermal Stability of INCONEL Alloy 783. ASME 98-GT-508. 651. Sjödin, B.: A Non-Local Theory for the Assessment of Multiaxial High Cycle Fatigue Failure. ASME 98GT-509. 652. Wereszczak, A. W.: Strength Distribution Changes in a Silicon Nitride as a Function of Stressing Rate and Temperature. ASME 98-GT-527. 653. Woetting, G.: High-Temperature Properties of SiC-Si3N4 Particle Composites. ASME 98-GT-465. 654. Desai, V. H.: Oxidation Characteristics of Nickel Based Superalloys in Steam. ASME 98-GT-587. 655. Hurst, J. B.: ASTM Single Fiber Room Temperature Test Standard Development. ASME 98-GT- 567. 656. Brown, C.: PM 2000 Honeycomb Structures. ASME 98-GT-565. Schaufelwerkstoffe 657. Bullough, C. K.: The Characterisation of the single crystal superalloy CMSX-4 for Industrial Gas Turbine Blading Applications; Materials for Advanced Power Engineering 1998, O17. 658. Toulios, M.: Deformation Modelling of the single chrystal superalloy CMSX-4 for Industrial Gas Turbine Applications; Materials for Advanced Power Engineering 1998, O18. 659. Caron, P.: Third Generation superalloys for single crystal blades; Materials for Advanced Power Engineering 1998, O19. 660. Ford, D. A.: Improved Performance Rhenium Containing Single Crystal Alloy Turbine Blades Utilising PPM Levels of the Highly Reactive Elements Lanthanum and Yttrium. ASME 98-GT-371. 661. Henderson, P.: A Metallographie Technique For High Temperature Creep Damage Assessment in Single Crystal Alloys. ASME 98-GT-488. 662. Cherwu, N. S.: Influence of Metal Temperature on Base Material and Coating Degradation of GTD-111 Buckets. ASME 98-GT-511. Schutzschichten 663. Czech, N.: Maßgeschneiderte Schutzschichten machen Gasturbinenschaufeln leistungsfähiger; Siemens Power Journal 1/1998; S. 40 - 43. 664. Stoiber, J.: Schutzschichtschäden an Gasturbinenschaufeln; VDI Berichte Nr. 1421 (1998), S. 323-338. 665. Rettig, U.: Characterization of Fatigue Mechanisms of Thermal Barrier Coatings by a Novel Laser-Based Test. ASME 98-GT-336. 666. Mutasim, Z.: Effects of Alloy Composition on the Performance of Diffusion Aluminide Coatings. ASME 98-GT-401. 667. Warnes, B. M.: Improved Pt Aluminide Coatings Using CVD and Novel Platinum Electroplating. ASME 98-GT-391. 668. Page, R. A.: Inhibition of Interdiffusion from MCrAIY Overlay Coating by Application of a Ni-Re Interlayer. ASME 98-GT-375. 669. Cheruvu, N. S.: Cyclic Oxidation Behavior of Aluminide, Platinum Modified Aluminide, and MCrAIY Coating on GTD-111. ASME 98-GT-468. 670. Kameda, J.: Microstructure/Composition Evolution and Ductility Variation in Thermally Aged Aluminized CoCrAIY Coatings. ASME 98-GT-526. 671. Wereszczak, A. A.: Stress Relaxation of MCrAIY Bond Coat Alloys as a Function of Temperature and Strain. ASME 98-GT-403. 672. Schmidt, U. T.: The Creep Damage Behavior of the Plasma-Sprayed Thermal Barrier Coating System NiCr22Co12Mo9-NiCoCrAIY-ZrO2/7%Y2O3. ASME 98-GT-387. 673. Affeldt, E. E.: Influence of an Aluminide Coating on the TMF Life of a Single Crystal Nickel-Base Superalloy. ASME 98-GT-318. 674. Boudot, A.: Thermo-mechanical Characterizations of Coatings for HP Turbines. ASME 98-GT-324. 675. Bettridge, D. F.: The Explorations of Protective Coatings and Deposition Processes for NiBase Alloys and γ TiAI; Materials for Advanced Power Engineering 1998, O24. 676. Singheiser, L.: Thermal Barrier Coatings for Gas Turbines-Failure Mechanisms and Life Prediction; Materials for Advanced Power Engineering 1998, O25. 677. Chan, K. S.: Coating Life Prediction for Combustion Turbine Blades. ASME 98-GT-478. 678. Schenk, B.: A Unique Small Gas Turbine Test Facility for Low-Cost Investigations of Ceramic Rotor Materials and Thermal Barrier Coatings. ASME 98-GT-348. 679. Lenk, P.: Aktuelle Applikationsfelder der Hochleistungs-Elektronenstrahltechnik. Vakuum in Forschung und Praxis, 10/1998, 1, S. 29-31. Lebensdauer 680. Daleo, J. A.: Application of Stress Relaxation Testing in Metallurgical Life Assessment Evaluations of GTD111 Alloy Turbine Buckets. ASME 98-GT-370. 681. Osama, M. J.: Multiaxial Creep Life Prediction of Ceramic Structures Using Continuum Damage Mechanics and the Finite Element Method. ASME 98-GT-489. Keramik 682. Easley, M. L.: Ceramic Gas Turbine Technology Development. ASME 98-GT-554. 683. Jimenez, O.: Ceramic Stationary Gas Turbine Development Program-Design and Test of a Ceramic Turbine Blade. ASME 98-GT-529. 684. Faulder, L.: Ceramic Stationary Gas Turbine Development Program-Design and Test of a First Stage Ceramic Nozzle. ASME 98-GT-528. 685. Price, J. R.: Ceramic Stationary Gas Turbine Development Program - Fifth Annual Summary. ASME 98GT-181. 686. Hara, Y.: Development and Evaluation of Silicon Nitride Components for Ceramic Gas Turbine. ASME 98-GT-498. 687. Brinkmann, Ch. R.: Development of ASTM Standards in Support of Advanced Ceramics-Continuing Efforts. ASME 98-GT-530. 688. Choi, S. R.: Elevated-Temperature, ‘Ultra’-Fast Fracture Strength of Advanced Ceramics: An Approach to Elevated-Temperature "Inert" Strength. ASME 98-GT-479. 689. Taoka, T.: Current Status of the CGT301, Ceramic Gas Turbine. ASME 98-GT-288. 690. Kobayashi, H.: Current Status of Ceramic Gas Turbine (CGT302). ASME 98-GT-501. 691. Yoshida, M.: Development of Ceramic Components for Ceramic Gas Turbine Engine (CGT302). ASME 98-GT-398. 692. Grondahl, C. M.: Performance Benefit Assessment of Ceramic Components in an MS9001FA Gas Turbine. ASME 98-GT-186. 693. Dilzer, M.: Testing of a Low Cooled Ceramic Nozzle Vane Under Transient Conditions. ASME 98-GT116. 694. Day, W. H.: Development of Cooled, Ceramic First Stage Vanes for the FT8 Aeroderivative Gas Turbine. ASME 98-GT-133. 695. Klemm, H.: High-Temperature Oxidation and Corrosion of Silicon-Based Nonoxide Ceramics. ASME 98GT-480. 696. Razzell, A. G.: Oxide/Oxide Ceramic Matrix Composites in Gas Turbine Combustors. ASME 98-GT-030. 697. Nishio, K.: Development of a Combustor Liner Composed of Ceramic Matrix Composite (CMC). ASME 98-GT-104. 698. Kempster, A.: Protection against Oxidation of Internal Cooling Passageways on Turbine Blades and Vanes. Power-Gen Europe 98. 699. Takashi, O.: Reliability Evaluation of Structural Ceramics under Multiaxial Stress State. ASME 98-GT595. 700. Rahman, S.: Life Prediction and Reliability Analysis of Ceramic Structures under Combined Static and Cyclic Fatigue. ASME 98-GT-569. Fertigung, Reparatur 701. Tsay, Der Min: Generation of Five-Axis Cutter Paths for a Ball-End Cutter with Global Interface Checking. ASME 98-GT-549. 702. Greaves, W.: Manual GTAW of Superalloy Blade Materials Using High Strength Fillers. ASME 98-GT550. 703. Larker, R.: Diffusion Bonding of CMSX-4 to Udimet 720 Using PVD-Coated Interfaces and HIP. ASME 98-GT-589. 704. Subhas, B. K.: Dimensional Instability Studies in Machining of Inconel 718 Nickel Based Superalloys as Applied to Aerogas Turbine Components. ASME 98-GT-469. Reparatur 705. Picton, P. J.: Economic Considerations in the Development of New Repairs for Gas Turbines. ASME 98GT-559. 706. Kunberger, K.: Gas Turbine Repair & Test Facility; Diesel & Gas Turbine Worldwide 4 1998, S. 66-68. 707. -: Hot Gas Casing Repair; Diesel & Gas Turbine Worldwide 9 1998, S. 24-25. 708. Nerovnyi, V.-M.: Restoration of the end surface of working blades of gas turbines. Welding International, 12/1998, 1, S. 69-72. 709. Bremer, C.: Automatic Blade Repair System Based on Reverse Engineering Strategies. ASME 98-GT551. 710. Noble, M.: Turbine Blade Reconstruction from Elbar; Diesel & Gas Turbine Worldwide 9 1998, S. 50. 711. Roth, M.: Reparatur von gerichtet erstarrten und einkristallinen Gasturbinenschaufeln; VDI Berichte Nr. 1421 (1998), S. 339-353. 712. Swaminathan; V.P.: Microstructure and Property Assessment of Conventionally Cast and Directionally Solidified Buckets Refurbished After Long-Term Service. ASME 98-GT-510. 713. Mazur, Z.: Gas Turbine Rotor Disc Repair-Case History. ASME 98-GT-547. 714. Lundberg, R.: HIPed Silicon Nitride Components for AGATA - Properties and Evaluation. ASME 98-GT566. Meßtechnik und Instrumentierung 715. Vouillarmet, A.: Improvements in L2F Anemometry Technique for Inter-Blade Investigations in HighSpeed Turbomachinery. ASME 98-GT-157. 716. Dhadwal, H. S.: Dual-Laser Probe Measurement of Blade-Tip Clearance. ASME 98-GT-183. 717. Evans, C.: Testing and Modelling Gas Turbines Using Multisine Signals and Frequency-Domain Techniques. ASME 98-GT-098. 718. Mozumdar, S.: New Non-Dimensional Parameters in Fluid Mechanics and their Application to Turbine Flowmeter Data Analysis. ASME 98-GT-486. 719. Davies, M. R. D.: Local Measurement of Loss Using Heated Thin Film Sensors. ASME 98-GT-380. 720. Martins, N.: Radiation and Convection Heat Flux Sensor for High Temperature Gas Environment. ASME 98-GT-224. 721. Lou, W.: Total and Static Quantity Measurements in Unsteady Flow-Effect of Unsteadiness. ASME 98GT-533. 722. McGarry, E. T.: Digital Measuring Borescope System. ASME 98-GT-534. 723. Lepicovsky, J.: PSP Measurement of Stator Vane Surface Pressures in a High Speed Fan. ASME 98GT-499. 724. Anderson, R. C.: A Government / Industry Collaboration for Turbine Engine Instrumentation Development. ASME 98-GT-491. 725. Stange, W. A.: Advanced Instrumentation Technology for the Integrated-High-Performance-TurbineEngine-Technology and High-Cycle-Fatigue Programs. ASME 98-GT-458. 726. Brun, K.: Measurement Uncertainties Encountered During Gas Turbine Driven Compressor Field Testing. ASME 98-GT-001. Sonstiges Lagerung 727. Lewis, A. S.: Sliding Mode Output Feedback Control of a Flexible Rotor Via Magnetic Bearings. ASME 98-GT-407. 728. Kasarda, M. E. F.: Experimentally Determined Rotor Power Losses in Homopolar and Heteropolar Magnetic Bearings. ASME 98-GT-317. 729. Allaire, P. E.: Rotor Power Losses in Planar Radial Magnetic Bearings - Effects of Number of Stator Poles, Air Gap Thickness, and Magnetic Flux Density. ASME 98-GT-316. 730. Maslen, E. H.: Fault Tolerant Magnetic Bearings. ASME 98-GT-377. 731. Heshmat, H.: On the Performance of Hybrid Foil-Magnetic Bearings. ASME 98-GT-376. 732. Kondoleon, A. S.: A High Bandwidth, Low Loss Magnetic Supension System for Turbomachinery. ASME 98-GT-406. 733. Zachariadis, D.C.: Short Bearing Model for the Evaluation of Journal’s Dynamic Angular Misalignment Effects on Rotor Vibrations. ASME 98-GT-397. 734. Edney, St. L.: Testing, Analysis and CFD Modeling of a Profiled Leading Edge Groove Tilting Pad Journal Bearing. ASME 98-GT-409. Diffusoren 735. Harris, H.: A Performance Evaluation of a Three Splitter Diffuser and Vaneless Diffuser Installed on the Power Turbine Exhaust of a TF40B Gas Turbine. ASME 98-GT-284. 736. Zaryankin, A. E.: Experimental Investigations of an Annular Diffuser of the Gas Turbine Exhaust Hood; VDI Berichte Nr. 1438 (1998), S. 251-254. 737. Agrawal, A. K.: Flow Characteristics of an Annular Intercooler-Diffuser for Gas Turbines. ASME 98-GT283. 738. Sultanian, B. K.: Experimental and 3D CFD Investigation in a Gas Turbine Exhaust System. ASME 98GT-111. Dichtungen 739. Chen, L. H.: An Iterative CFD and Mechanical Brush Seal Model and Comparison With Experimental Results. ASME 98-GT-372. 740. Rhode, D. L.: Visualization and Measurements of Rub-Groove Leakage Effects on Straight-Through Labyrinth Seals. ASME 98-GT-506. 741. Zimmermann, H.: Air System Correlations, Part 1: Labyrinth Seals. ASME 98-GT-206. 742. Zimmermann, H.: Air System Correlations, Part 2: Rotating Holes and Two Phase Flow. ASME 98-GT207. 743. Li, J.: A Bulk-Flow Analysis of Multiple-Pocket Gas Damper Seals. ASME 98-GT-013. 744. Zirkelback, N. L.: Qualitative Characterization of Anti-Swirl Gas Dampers. ASME 98-GT-014. 745. Diaz, S. E.: Reduction of the Dynamic Load Capacity in a Squeeze Film Damper Operating with a Bubbly Lubricant. ASME 98-GT-109. Sicherheit 746. Santon, R. C.: Explosion Hazards at Gas Turbine Driven Power Plants. ASME 98-GT-215. 747. Sinai, Y. L.: Remediation of Gas Explosion Hazards in Gas Turbine Enclosures. ASME 98-GT-321. 748. Hunt, P. J.: A Risk Based Approach to the Potential for CCGT Enclosure Explosions A Study on Teesside Power Station. ASME 98-GT-446. 749. Schwamm, F.: FADEC Computer Systems for Safety Critical Application. ASME 98-GT-170. Diverses 750. Srivastava, R.: Application of Time-Shifted Boundary Conditions to a 3D Euler/Navier-Stokes Aeroelastic Code. ASME 98-GT-042. 751. Chuang, H. A.: A Nonlineat Numerical Simulator for Three-Dimensional Flows Through Vibrating Blade Rows. ASME 98-GT-018. 752. Acran, P.: Optimization of Design of High Pressure Compact and Light-Weight Liquid Heat Exchangers. ASME 98-GT-202. 753. Sonoda, T.: The Effect of Inlet Boundary Layer Thickness on the Flow within an Annular S-Shaped Duct. ASME 98-GT-260. 754. Matsubara, M.: Boundary Layer Transition at High Levels of Free Stream Turbulence. ASME 98-GT-248. 755. Schook, R.: Effects of Compressibility and Turbulence Level on Bypass Transition. ASME 98-GT-286. 756. Volino, R. J.: Wavelet Analysis of Transitional Flow Data under High Free-Stream Turbulence Conditions. ASME 98-GT-289. 757. Johnson, M. W.: Turbulent Spot Characteristics in Boundary Layers Subjected to Streamwise Pressure Gradient. ASME 98-GT-124. 758. Maryle, R. E.: A Theory for Predicting the Turbulent-Spot Production Rate. ASME 98-GT-256. 759. Clary, W.: Greenhouse Plants Benefit from Catalytic System; Diesel & Gas Turbine Worldwide 10 1998, S. 30-31. 760. Crosa, G.: Turbine Model Improvement for a Heavy-Duty Gas Turbine Plant Simulation. ASME 98-GT171. 761. Basu, R. D.: Modification and Redesign of GT Components. ASME 98-GT-586. 762. Morris, R. J.: Active Structural Control for Gas Turbine Engines. ASME 98-GT-514. 763. Yee, R.: Combined Gas Turbine and Diesel Generator Cooling Air Intake System. ASME 98-GT-280. 764. Tanaka, T.: Gas Turbine Inlet Air Cooling System with Liquid Air. ASME 98-GT-449. 765. Anders, J. M.: Achieving Acoustical and Structural Requirements for Gas Turbine Packages while Reducing Costs, Pressure Losses, and Weight. ASME 98-GT-083. 766. Moen, L.: Vibroacoustic Early Warning System for Gas Turbines Paper Presentation, ASME Turbo Expo., Land, Sea & Air 1998. ASME 98-GT-302. 767. Ekström, C.: Technology and Cost Options for Capture and Disposal of Carbon Dioxide from Gas Turbines. A System Study for Swedish Conditions. ASME 98-GT-443. 768. Haq, I. U.: Multistage Centrifugal Compressor Fouling Evaluation at High Power Settings. ASME 98-GT053. 769. Palmer, C. A.: Combining Bayesian Belief Networks with Gas Path Analysis for Test Cell Diagnostics and Overhaul. ASME 98-GT-168. 770. Wadman, B.: Contaminant Analysis for Gas Turbine Water Systems; Diesel & Gas Turbine Worldwide 10 1998, S. 75. 771. Steen, M.: Mechanical Property Scatter in CFCCs. ASME 98-GT-319. 772. Puente, I.: Influence of the Interface on the Energy Absorption Mechanisms of CMCs. ASME 98-GT-408. 773. Gyekenyesi, A. L.: Isothermal Fatigue Behavior and Damage Modeling of a High Temperature Woven PMC. ASME 98-GT-106. 774. Moftakhar, A. A.: Creep Analysis of High Temperature Components Under Multi-Axial Loading. ASME 98-GT-263.