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Journal articles on the topic 'Revision of steam turbine'

Author: Grafiati
Published: 4 June 2021
Last updated: 17 February 2022

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1

Abass, A. Z., D. A. Pavlyuchenko, A. M. Balabanov, and V. M. Less. "Inclusion of solar energy in iraq gas-turbine power plants as a method of solving the country's energy system shortage." Power engineering: research, equipment, technology 22, no. 2 (May 15, 2020): 98–107. http://dx.doi.org/10.30724/1998-9903-2020-22-1-98-107.

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At high ambient temperatures, the performance of gas turbine power plants drops significantly. Technical solutions of compensation for losses associated with the constant injection of water into the air intake of a gas turbine. This approach is not acceptable in regions with limited fresh water reserves. Radical solutions are required to reduce the cost of generated energy. Integrated Combined Solar Cycle (ISCCS) technology has proven itself on many projects. The addition of a combined cycle gas cycle with solar energy can significantly increase the overall efficiency of the power plant. Despite the increase in costs during the construction of its solar part, the total cost of operating solar collectors is several times less than a turbine installation. Given the global trend to fight carbon emissions, switching to a hybrid scheme is economically attractive. Trading in carbon credits for CO2 emissions will significantly reduce the payback period for the construction of gas turbine modernization under the ISCCS scheme. This paper presents an option to modernize a gas turbine power plant in the city of Basra (Iraq), using the advantages of solar radiation and recycling of combustion products from gas turbines. It is proposed to equip the existing 200 MW gas turbine plant with two steam turbine units with a capacity of 75 and 65 MW, working in conjunction with solar collectors producing low pressure water vapor. Due to modernization, the efficiency of the power plant should increase from 38% to 55%. The revision of the schematic and technical solutions of Iraq power plants will allow producing sufficient energy for the region.
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2

Iranzo, Alfredo. "CFD Applications in Energy Engineering Research and Simulation: An Introduction to Published Reviews." Processes 7, no. 12 (November 26, 2019): 883. http://dx.doi.org/10.3390/pr7120883.

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Computational Fluid Dynamics (CFD) has been firmly established as a fundamental discipline to advancing research on energy engineering. The major progresses achieved during the last two decades both on software modelling capabilities and hardware computing power have resulted in considerable and widespread CFD interest among scientist and engineers. Numerical modelling and simulation developments are increasingly contributing to the current state of the art in many energy engineering aspects, such as power generation, combustion, wind energy, concentrated solar power, hydro power, gas and steam turbines, fuel cells, and many others. This review intends to provide an overview of the CFD applications in energy and thermal engineering, as a presentation and background for the Special Issue “CFD Applications in Energy Engineering Research and Simulation” published by Processes in 2020. A brief introduction to the most significant reviews that have been published on the particular topics is provided. The objective is to provide an overview of the CFD applications in energy and thermal engineering, highlighting the review papers published on the different topics, so that readers can refer to the different review papers for a thorough revision of the state of the art and contributions into the particular field of interest.
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3

Chaibakhsh, Ali, and Ali Ghaffari. "Steam turbine model." Simulation Modelling Practice and Theory 16, no. 9 (October 2008): 1145–62. http://dx.doi.org/10.1016/j.simpat.2008.05.017.

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4

Riis, S. M. "STEAM TURBINE LUBRICATION." Journal of the American Society for Naval Engineers 42, no. 3 (March 18, 2009): 475–79. http://dx.doi.org/10.1111/j.1559-3584.1930.tb05736.x.

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5

Holcomb, Gordon R. "Steam Oxidation of Advanced Steam Turbine Alloys." Materials Science Forum 595-598 (September 2008): 299–306. http://dx.doi.org/10.4028/www.scientific.net/msf.595-598.299.

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Power generation from coal using ultra supercritical steam results in improved fuel efficiency and decreased greenhouse gas emissions. Results of ongoing research into the oxidation of candidate nickel-base alloys for ultra supercritical steam turbines are presented. Exposure conditions range from moist air at atmospheric pressure (650°C to 800°C) to steam at 34.5 MPa (650°C to 760°C). Parabolic scale growth coupled with internal oxidation and reactive evaporation of chromia are the primary corrosion mechanisms.
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6

Кондратьева, Екатерина, Ekaterina Kondrateva, Сергей Олейников, Sergey Oleynikov, Виктор Рассохин, Viktor Rassokhin, Алексей Кондратьев, Aleksey Kondratev, Александр Осипов, and Aleksandr Osipov. "STEAM TURBINE DEVELOPMENT FOR SUPERCRITICAL STEAM PARAMETERS." Bulletin of Bryansk state technical university 2017, no. 1 (March 31, 2017): 72–82. http://dx.doi.org/10.12737/24895.

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The paper reports the expediency and substantiation of the necessity for the gradual transition to power units on supercritical stream parameters in world power engineering. Basic stages in the development of steam turbine manufacturing with supercritical steam parameters are considered. The parameter increase at the input makes a profound impact upon the design of a flowing part of turbines. To operate a great difference in enthalpies in a cylinder without changing stages number one has to modernize them and sometimes to change the design completely. In the paper there is considered the expediency of the application of axial highloaded stages developed by the Polytechnics of Leningrad (LPI). There are also described the stages of designing steam turbine plants with critical and supercritical steam parameters at the input in a turbine. As an example there is analyzed SKR-100-300 steam turbine with the initial steam parameters of 29.4MPa and 650S. The results of solution computations directed to the efficiency increase of a regulatory stage of K-300-240 steam turbine with supercritical parameters of 580C and 29.0 MPa are presented. The application as a profile of an impeller the blade design of LPI allows increasing turbine plant efficiency in a wide range of mode parameters and also reducing a general number of turbine stages.
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7

Rice, I. G. "Steam-Injected Gas Turbine Analysis: Steam Rates." Journal of Engineering for Gas Turbines and Power 117, no. 2 (April 1, 1995): 347–53. http://dx.doi.org/10.1115/1.2814101.

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This paper presents an analysis of steam rates in steam-injected gas turbines (simple and reheat). In considering a gas turbine of this type, the steam-injection flow is separated from the main gas stream for analysis. Dalton’s and Avogadro’s laws of partial pressure and gas mixtures are applied. Results obtained provide for the accurate determination of heat input, gas expansion based on partial pressures, and heat-rejection steam-enthalpy points.
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8

Scaife, W. Garrett. "The Parsons Steam Turbine." Scientific American 252, no. 4 (April 1985): 132–39. http://dx.doi.org/10.1038/scientificamerican0485-132.

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9

Parsons, C. A. "THE MARINE STEAM TURBINE." Journal of the American Society for Naval Engineers 13, no. 2 (March 18, 2009): 432–42. http://dx.doi.org/10.1111/j.1559-3584.1901.tb03394.x.

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10

Meuth, H. "THE ELEKTRA STEAM TURBINE." Journal of the American Society for Naval Engineers 22, no. 2 (March 18, 2009): 402–16. http://dx.doi.org/10.1111/j.1559-3584.1910.tb05371.x.

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11

Capstaff, Jas A. "STEAM TURBINE BLADE FASTENINGS." Journal of the American Society for Naval Engineers 27, no. 2 (March 18, 2009): 313–31. http://dx.doi.org/10.1111/j.1559-3584.1915.tb00391.x.

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12

Capstafp, Jas A. "STEAM TURBINE BLADE FASTENINGS." Journal of the American Society for Naval Engineers 28, no. 1 (March 18, 2009): 55–57. http://dx.doi.org/10.1111/j.1559-3584.1916.tb00599.x.

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13

Jaffee, R. R. "Titanium steam turbine blades." JOM 41, no. 3 (March 1989): 31–35. http://dx.doi.org/10.1007/bf03220994.

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14

Ikeda, Kazutaka, Hideo Nomoto, Koichi Kitaguchi, Shinya Fujitsuka, and Takashi Sasaki. "F205 Development of Advanced-Ultra Super Critical Steam Turbine System(Steam Turbine-2)." Proceedings of the International Conference on Power Engineering (ICOPE) 2009.2 (2009): _2–463_—_2–468_. http://dx.doi.org/10.1299/jsmeicope.2009.2._2-463_.

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15

Langston, Lee S. "Cogeneration: Gas Turbine Multitasking." Mechanical Engineering 134, no. 08 (August 1, 2012): 50. http://dx.doi.org/10.1115/1.2012-aug-4.

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This article describes the functioning of the gas turbine cogeneration power plant at the University of Connecticut (UConn) in Storrs. This 25-MW power plant serves the 18,000 students’ campus. It has been in operation since 2006 and is expected to save the University $180M in energy costs over its 40-year design life. The heart of the UConn cogeneration plant consists of three 7-MW Solar Taurus gas turbines burning natural gas, with fuel oil as a backup. These drive water-cooled generators to produce up to 20–24 MW of electrical power distributed throughout the campus. Gas turbine exhaust heat is used to generate up to 200,000 pounds per hour of steam in heat recovery steam generators (HRSGs). The HRSGs provide high-pressure steam to power a 4.6-MW steam turbine generator set for more electrical power and low-pressure steam for campus heating. The waste heat from the steam turbine contained in low-pressure turbine exhaust steam is combined with the HRSG low-pressure steam output for campus heating.
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16

SOMERSCALES, Euan F. C. "The Vertical Curtis Steam Turbine." Transactions of the Newcomen Society 62, no. 1 (January 1990): 157–58. http://dx.doi.org/10.1179/tns.1990.008.

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17

SOMERSCALES, Euan F. C. "The Vertical Curtis Steam Turbine." Transactions of the Newcomen Society 63, no. 1 (January 1991): 1–52. http://dx.doi.org/10.1179/tns.1991.001.

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18

Ghosh, S. J., and A. Srivastava. "Cracks in steam turbine components." Russian Journal of Nondestructive Testing 42, no. 2 (February 2006): 134–46. http://dx.doi.org/10.1134/s1061830906020112.

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19

Mazur, Zdzislaw, Rafael Garcia-Illescas, Jorge Aguirre-Romano, and Norberto Perez-Rodriguez. "Steam turbine blade failure analysis." Engineering Failure Analysis 15, no. 1-2 (January 2008): 129–41. http://dx.doi.org/10.1016/j.engfailanal.2006.11.018.

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20

Dyson, C. W. "TEST OP TERRY STEAM TURBINE." Journal of the American Society for Naval Engineers 21, no. 3 (March 18, 2009): 884–90. http://dx.doi.org/10.1111/j.1559-3584.1909.tb03511.x.

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21

Christie, A. G. "TRENDS IN STEAM-TURBINE DEVELOPMENT." Journal of the American Society for Naval Engineers 43, no. 2 (March 18, 2009): 331–42. http://dx.doi.org/10.1111/j.1559-3584.1931.tb03758.x.

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22

Ivanov, S. A., and K. O. Tsvetkov. "660 MW Ultrasupercritical Steam Turbine." Power Technology and Engineering 49, no. 2 (June 14, 2015): 124–27. http://dx.doi.org/10.1007/s10749-015-0585-3.

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23

Averkina, N. V., I. V. Zheleznyak, Yu Ya Kachuriner, I. A. Nosovitskii, V. G. Orlik, and V. I. Shishkin. "Wet-steam erosion of steam turbine disks and shafts." Power Technology and Engineering 44, no. 5 (January 2011): 386–93. http://dx.doi.org/10.1007/s10749-011-0196-6.

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24

Kuryanov, Anton, Ivo Mõik, and Oksana Grigoryeva. "Combined Cycle Gas Turbine (CCGT) with Freon Steam Turbine." Applied Mechanics and Materials 792 (September 2015): 351–58. http://dx.doi.org/10.4028/www.scientific.net/amm.792.351.

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The article considers the prospect of a combined-cycle plant with freon as the working fluid of the steam turbine. Methodical approach to the study of such plants is expounded. For the option, CCGT with gas turbine M701G2 and use of freon R134a results of calculations of technical and economic efficiency, gas-dynamic characteristics, design-layout parameters are shown. The effectiveness of investments has been assessed.
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25

Blažević, Sebastijan, Vedran Mrzljak, Nikola Anđelić, and Zlatan Car. "COMPARISON OF ENERGY FLOW STREAM AND ISENTROPIC METHOD FOR STEAM TURBINE ENERGY ANALYSIS." Acta Polytechnica 59, no. 2 (April 30, 2019): 109–25. http://dx.doi.org/10.14311/ap.2019.59.0109.

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In this paper, a comparison of two different methods for a steam turbine energy analysis is presented. A high-pressure steam turbine from a supercritical thermal power plant (HPT) was analysed at three different turbine loads using the energy flow stream (EFS) method and isentropic (IS) method. The EFS method is based on steam turbine input and output energy flow streams and on the real steam turbine produced power. The method is highly dependable on the steam mass flow rate lost through the turbine gland seals. The IS method is based on a comparison of turbine steam expansion processes. Observed energy analysis methods cannot be directly compared because they are based on different sources of steam turbine energy losses, so, an overall steam turbine energy analysis is presented. Unlike most steam turbines from the literature, the analysed HPT did not have the highest overall energy efficiency at a full load due to exceeding the water/steam critical pressure at the turbine inlet during such operation.
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26

Mrzljak, Vedran, Jasna Prpić-Oršić, and Igro Poljak. "Energy Power Losses and Efficiency of Low Power Steam Turbine for the Main Feed Water Pump Drive in the Marine Steam Propulsion System." Journal of Maritime & Transportation Science 54, no. 1 (June 2018): 37–51. http://dx.doi.org/10.18048/2018.54.03.

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Steam turbine for the main feed water pump (MFP) drive is a low power turbine, for which energy power losses and energy efficiency analysis are presented in this paper. The MFP steam turbine analysis has been performed within a wide range of turbine loads. The influence of steam specific entropy increment of the real (polytropic) steam expansion upon the MFP turbine energy power losses and energy efficiency has been investigated. During all the observed loads MFP steam turbine energy power losses were in the range between 346.2 kW and 411.4 kW. The MFP steam turbine energy power losses and energy efficiency were most significantly influenced by the steam specific entropy increment. Change in the steam specific entropy increment is directly proportional to the change in MFP turbine energy power losses, while the change in the steam specific entropy increment is reversely proportional to the MFP turbine energy efficiency change. For the observed turbine loads, the MFP steam turbine energy efficiency was in the range between 46.83% and 51.01%.
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27

Chao, Dong, and Sun Yongjian. "Working process of steam turbine and establishment of start-up model." International Journal of Physics Research and Applications 4, no. 1 (May 24, 2021): 039–47. http://dx.doi.org/10.29328/journal.ijpra.1001040.

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In the research of steam turbine rotor, start-up optimization is a very key research problem. A series of start-up optimization research can greatly improve the start-up efficiency of steam turbine and the safety performance of the unit. The start-up optimization of steam turbine is inseparable from the analysis of the start-up process of steam turbine and the mathematical model of the startup process of steam turbine unit, because the optimization of steam turbine unit can be regarded as a function to find the optimal solution. This paper analyzes the start-up process of 300 MW steam turbine, analyzes the start-up process of steam turbine unit through the data used in the actual power plant, and gives the mathematical model of cold start-up of steam turbine according to the start-up process of steam turbine, so as to further study the start-up optimization of steam turbine. Finally, the optimization model is determined by several key parameters, which are three weight coefficients α1,α2,α3, the actual damage value Di and damage limit value Dlim, and the start-up time ti and total start-up time t0 of each stage.
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28

SAITO, Eiji, Shinya IMANO, and Kenichi MURATA. "F202 PROGRESS OF STEAM TURBINE DEVELOPMENT THAT ACHIEVES 700℃ CLASS ADVANCED ULTRA SUPER CRITICAL STEAM CONDITION(Steam Turbine-1)." Proceedings of the International Conference on Power Engineering (ICOPE) 2009.2 (2009): _2–451_—_2–454_. http://dx.doi.org/10.1299/jsmeicope.2009.2._2-451_.

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29

Mrzljak, Vedran, Sandi Baressi Šegota, Hrvoje Meštrić, and Zlatan Car. "Comparison of Power Distribution, Losses and Efficiencies of a Steam Turbine with and without Extractions." Tehnički glasnik 14, no. 4 (December 9, 2020): 480–87. http://dx.doi.org/10.31803/tg-20200629122146.

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The paper presents an analysis of two steam turbine operation regimes - regime with all steam extractions opened (base process) and regime with all steam extractions closed. Closing of all steam extractions significantly increases turbine real developed power for 5215.88 kW and increases turbine energy and exergy losses with simultaneous decrease of turbine energy and exergy efficiencies for more than 2%. First extracted steam mass flow rate has a dominant influence on turbine power losses (in comparison to turbine maximum power when all of steam extractions are closed). Cumulative power losses caused by steam mass flow rate extractions are the highest in the fourth turbine segment and equal to 1687.82 kW.
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30

Mrzljak, Vedran. "Low Power Steam Turbine Energy Efficiency and Losses During the Developed Power Variation." Tehnički glasnik 12, no. 3 (September 25, 2018): 174–80. http://dx.doi.org/10.31803/tg-20180201002943.

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This paper investigates low power marine steam turbine during the variation in its developed power. The turbine is used for the Main Feedwater Pump (MFP) drive. Energy analysis of the Main Feedwater Pump Turbine (MFPT) is based on the measurements performed in nine different operating regimes. The measured operating parameters were steam pressure and temperature at the turbine inlet, steam pressure at the turbine outlet, and a water volume flow through MFP. Turbine energy power losses are most influenced by steam mass flow through the turbine and by steam specific enthalpy at the turbine outlet. An increase in turbine developed power causes a continuous increase in turbine energy efficiency. Analyzed turbine is balanced as most of the other steam system components – maximum energy efficiency will be obtained at the highest load, on which the majority of turbine and system operation can be expected during exploitation.
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31

Mrzljak, Vedran, Jan Kudláček, Đerzija Begić-Hajdarević, and Jelena Musulin. "The Leakage of Steam Mass Flow Rate through the Gland Seals – Influence on Turbine Produced Power." Journal of Maritime & Transportation Science 58, no. 1 (June 2020): 39–56. http://dx.doi.org/10.18048/2020.58.03.

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In this paper is presented an analysis of gland seals operation and their influence on the performance of low power steam turbine with two cylinders and steam reheating, which can be used in marine applications. Performed analysis presents a comparison of steam turbine main operating parameters when gland seals operation is neglected (as usual in the most of the literature) and when steam mass flow rates leaked through all gland seals are taken into consideration. Steam mass flow rate leakage through all gland seals reduces produced power of the whole turbine and both of its cylinders. Operation of gland seal mounted at the inlet in the first cylinder of any steam turbine (cylinder which operates with the steam of the highest pressure) has the most notable influence on the reduction of the whole turbine produced power. Gland seal mounted at the outlet of the last turbine cylinder (cylinder which operates with the steam of the lowest pressure) did not have any influence on the reduction of steam turbine produced power. In any detail analysis of a steam turbine (especially the complex turbine with multiple cylinders), gland seals operation should be considered due to their notable influence on the turbine performance.
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32

Medica-Viola, Vedran, Sandi Baressi Šegota, Vedran Mrzljak, and Daniel Štifanić. "Comparison of conventional and heat balance based energy analyses of steam turbine." Pomorstvo 34, no. 1 (June 30, 2020): 74–85. http://dx.doi.org/10.31217/p.34.1.9.

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This paper presents a comparison of conventional and heat balance based energy analyses of steam turbine. Both analyses are compared by using measured operating parameters from low power steam turbine exploitation. The major disadvantage of conventional steam turbine energy analysis is that extracted energy flow streams are not equal in real (polytropic) and ideal (isentropic) expansion processes, while the heat balance based energy analysis successfully resolved mentioned problem. Heat balance based energy analysis require an increase of steam mass flow rates extracted from the turbine in ideal (isentropic) expansion process to ensure always the same energy flow streams to all steam consumers. Increase in steam mass flow rate extracted through each turbine extraction (heat balance based energy analysis) result with a decrease in energy power losses and with an increase in energy efficiency of whole turbine and all of its cylinders (when compared to conventional analysis). All of the obtained conclusions in this research are valid not only for the analyzed low power steam turbine, but also for any other steam turbine with steam extractions.
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33

Kolovratník, Michal, and Ondřej Bartoš. "Wet steam wetness measurement in a 10 MW steam turbine." EPJ Web of Conferences 67 (2014): 02055. http://dx.doi.org/10.1051/epjconf/20146702055.

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34

Egorov, Mikle, Alexander Ivanov, Ivan Kovalenko, Irina Krectunova, Nadezhda Litvinova, and Elena Popova. "Steam reheater with helical tube bundle for wet steam turbine." E3S Web of Conferences 178 (2020): 01069. http://dx.doi.org/10.1051/e3sconf/202017801069.

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Since steam heat exchangers, used at steam cycle of Russian nuclear power stations, were designed while the knowledge about the separation and the heat exchange processes was limited, deviations between its empirical and theoretical characteristics occur. This limitation also determined application of heating pipes with simple straight shape rather than curved. This study explores a steam heat exchanger with helical heating pipes. It was shown that the model may work stably within the range of parameters, simulating work conditions of the moisture separator and steam reheater at Leningrad nuclear power plant. The experiment included processing of pure water steam as well as mixture of steam and nitrogen. It was obtained a relationship between empirical the heat transfer coefficient and the steam mass flow rate. It was noted that presence of incondensable gas does not affect significantly the heat transfer from the coils, processing high pressure steam.
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35

Mingazhev, A. D., A. V. Novikov, N. K. Krioni, and R. R. Bekishev. "PROTECTIVE COATING FOR STEAM TURBINE BLADES." Oil and Gas Business, no. 4 (August 2014): 257–78. http://dx.doi.org/10.17122/ogbus-2014-4-257-278.

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36

Sudo, Nobuyuki. "History of Steam Turbine Training Ships." Journal of The Japan Institute of Marine Engineering 44, no. 4 (2009): 582–87. http://dx.doi.org/10.5988/jime.44.582.

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37

Goršek, A., and P. Glavič. "Process integration of a steam turbine." Applied Thermal Engineering 23, no. 10 (July 2003): 1227–34. http://dx.doi.org/10.1016/s1359-4311(03)00062-0.

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38

DUFFY, M. C. "The American Steam-Turbine-Electric Locomotive." Transactions of the Newcomen Society 57, no. 1 (January 1985): 79–99. http://dx.doi.org/10.1179/tns.1985.005.

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39

Дроконов, Алексей, Aleksey Drokonov, Алексей Дроконов, and Aleksey Drokonov. "Development of steam turbine governing diaphragm." Bulletin of Bryansk state technical university 2015, no. 2 (June 30, 2015): 26–31. http://dx.doi.org/10.12737/22861.

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40

Sun, W., and Y. Wang. "Selection of steam turbine bypass system." IOP Conference Series: Earth and Environmental Science 354 (October 25, 2019): 012066. http://dx.doi.org/10.1088/1755-1315/354/1/012066.

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41

Azevedo, C. R. F., and A. Sinátora. "Erosion-fatigue of steam turbine blades." Engineering Failure Analysis 16, no. 7 (October 2009): 2290–303. http://dx.doi.org/10.1016/j.engfailanal.2009.03.007.

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42

Valamin, A. E., A. Yu Kultyshev, A. A. Gol’dberg, Yu A. Sakhnin, V. N. Bilan, M. Yu Stepanov, E. N. Polyaeva, M. V. Shekhter, and T. L. Shibaev. "K-65-12.8 condensing steam turbine." Thermal Engineering 63, no. 11 (October 20, 2016): 771–76. http://dx.doi.org/10.1134/s0040601516110100.

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43

Leonov, V. P., I. V. Gorynin, A. S. Kudryavtsev, L. A. Ivanova, V. V. Travin, and L. V. Lysenko. "Titanium alloys in steam turbine construction." Inorganic Materials: Applied Research 6, no. 6 (November 2015): 580–90. http://dx.doi.org/10.1134/s2075113315060076.

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44

Fennell, E., K. Kozminski, M. Bajpai, S. Easterday-McPadden, W. Elmore, C. Fromen, J. Gardell, et al. "Sequential tripping of steam turbine generators." IEEE Transactions on Power Delivery 14, no. 1 (1999): 132–41. http://dx.doi.org/10.1109/61.736702.

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45

Parsons, C. A., and R. J. Walker. "DEVELOPMENT OF THE MARINE STEAM TURBINE.*." Journal of the American Society for Naval Engineers 18, no. 4 (March 18, 2009): 1229–42. http://dx.doi.org/10.1111/j.1559-3584.1906.tb00011.x.

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46

RUSSELL, EDWARD. "GLAND TROUBLES WITH A STEAM TURBINE." Journal of the American Society for Naval Engineers 19, no. 3 (March 18, 2009): 817–19. http://dx.doi.org/10.1111/j.1559-3584.1907.tb00521.x.

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47

Gladh, Magnus, and Per Wallén. "Embrittlement of a steam turbine rotor." Engineering Failure Analysis 2, no. 4 (December 1995): 297–305. http://dx.doi.org/10.1016/1350-6307(94)00022-1.

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Tripathy, S. C. "Digital speed governor for steam turbine." Energy Conversion and Management 35, no. 2 (February 1994): 159–69. http://dx.doi.org/10.1016/0196-8904(94)90076-0.

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Nishida, Kousuke, Toshimi Takagi, and Shinichi Kinoshita. "Regenerative steam-injection gas-turbine systems." Applied Energy 81, no. 3 (July 2005): 231–46. http://dx.doi.org/10.1016/j.apenergy.2004.08.002.

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Dettori, S., V. Colla, G. Salerno, and A. Signorini. "Steam Turbine Models for Monitoring Purposes." Energy Procedia 105 (May 2017): 524–29. http://dx.doi.org/10.1016/j.egypro.2017.03.351.

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