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Erschienen in:
Introduction to Solar Gas Turbines Kapitel lesen Erstes Kapitel lesen

2018 | OriginalPaper | Buchkapitel

7. Design and Testing of Solar Gas Turbines

verfasst von : Amos Madhlopa

Erschienen in: Principles of Solar Gas Turbines for Electricity Generation

Verlag: Springer International Publishing

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Abstract

System design and testing are important processes in the development of any technology. Usually, it is desirable to theoretically optimize the design of a solar gas turbine (SGT). Based on simulation results, a real SGT system can be constructed and tested. At present, prototyping of SGTs is based on modification of the existing conventional gas turbine engines. A review of previous work shows that there is a deficiency in Standards for testing of concentrating solar power technologies. Some initiatives are under way to bridge this gap, which may also facilitate the development of relevant standards for testing SGTs. A limited number of projects have been implemented to test the performance of SGTs. Most of these projects are at demonstration scale, and there is lack of commercial-scale SGT power plants. Some challenges to the development of the SGT technology have been presented and discussed.

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Vorheriges Kapitel Configurations of Solar Gas Turbines
Nächstes Kapitel Economic Performance of Solar Gas Turbines
Literatur
Ali B (1990) Theoretical study of main factors affecting the heliostat field design of tower power plant. Energy Convers Manag 30(2):101–106 MathSciNetCrossRef
Amelio M, Ferraro V, Marinelli V, Summaria A (2014) An evaluation of the performance of an integrated solar combined cycle plant with air-linear parabolic collectors. Energy 69:742–748 CrossRef
Anderson JD (1991) Fundamentals of aerodynamic. McGraw-Hill Inc., New York
Arancibia-Bulnes CA, Peña-Cruz MI, Mutuberría A, Díaz-Uribe R, Sánchez-González M (2017) A survey of methods for the evaluation of reflective solar concentrator optics. Renew Sustain Energy Rev 69:673–684 CrossRef
American Society of Mechanical Engineers International (2014) Gas turbines. American Society of Mechanical Engineers (ASME) International, Englewood
American Society of Mechanical Engineers International (2015) Standard PTC 46: Overall plant performance. American Society of Mechanical Engineers (ASME) International, Englewood
Atif M, Al-Sulaiman F (2015) Optimization of heliostat field layout in solar central receiver systems on annual basis using differential evolution algorithm. Energy Convers Manag 95:1–9 CrossRef
Aurousseau A, Vuillerme V, Bezian J (2016) Control systems for direct steam generation in linear concentrating solar power plants—a review. Renew Sustain Energy Rev 56:611–630 CrossRef
Barigozzi G, Bonetti G, Franchini G, Perdich A, Perdichizzi A, Ravelli S (2012) Thermal performance prediction of a solar hybrid gas turbine. Sol Energy 86:2116–2127 CrossRef
Bazvandi H (2017) Effect of additional holes on transient thermal fatigue life of gas turbine casing. Case Stud Eng Fail Anal 9:78–86 CrossRef
Behar O, Kellaf A, Mohamedi K, Belhamel M (2011) Instantaneous performance of the first integrated solar combined cycle system in Algeria. Energy Procedia 6:185–193 CrossRef
Bejan A, Tsatsaronis G, Moran M (1996) Thermal design and optimization. Wiley, New York MATH
Benaboud A, Rufer A (2016) Gas turbine: optimization of energy production and high efficiency by using power electronics. Procedia Eng 138:337–346 CrossRef
Bhattacharyya SC (2011) Energy economics: concepts, issues, markets and governance. Springer, London CrossRef
Boyce MP (2002) Gas turbine engineering handbook, 2nd edn. Gulf Professional Publishing, Boston
Budynas RG, Nisbett JK (2011) Shingley’s mechanical engineering design, 9th edn. McGraw Hill, Singapore
Cameretti MC, Langella G, Sabino S, Tuccillo R (2015) Modeling of a hybrid solar micro gas-turbine power plant. Energy Procedia 82:833–840 CrossRef
Chen L, Li Y, Sun F, Wu C (2004) Power optimization of open-cycle regenerator gas-turbine power-plants. Appl Energy 78:199–218 CrossRef
Cohen H, Rogers GF, Saravanamuttoo HI (1996) Gas turbine theory, 4th edn. Longman Group Limited, Essex
Cui Y, Geng Z, Zhu Q, Han Y (2017) Review: multi-objective optimization methods and application in energy saving. Energy 125:681–704 CrossRef
Del Río A, Korzynietz R, Brioso JA, Gallas M, Ordóñez I, Quero M (2015) Soltrec-pressurized volumetric solar air receiver technology. Energy Procedia 69:360–368 CrossRef
Devices Delta-T (2000) User manual for DL2e data logger. Delta-T Devices, Cambridge
Drouot L, Hillairet M (1984) The Themis program and the 2500-kW Themis solar power station at Targasonne. ASME Trans J Sol Energy Eng 106:83–89 CrossRef
Ebert M, Benitez D, Röger M, Korzynietz R, Brioso JA (2016) Efficiency determination of tubular solar receivers in central receiver systems. Sol Energy 139:179–189 CrossRef
Enjavi-Arsanjania M, Hirbodia K, Yaghoubi M (2015) Solar energy potential and performance assessment of CSP plants in different are as of Iran. Energy Procedia 69:2039–2048 CrossRef
Fernández-García A, Sutter F, Fernández-Reche J, Lüpfert E (2017) Mirrors. In: Heller P (ed) The performance of concentrated solar power (CSP) systems: modelling. Woodhead Publishing, Measurement and Assessment, pp 67–98 CrossRef
Giampaolo T (2003) The gas turbine handbook: principles and practices, 2nd edn. Fairmont, Lilburn
Gong M, Jiao L, Yang D, Ma W (2009) Research on evolutionary multi-objective optimization algorithms. J Softw 20(2):271–289 MathSciNetCrossRef
Grange B, Dalet C, Falcoz Q, Siros F, Ferrière A (2014) Simulation of a hybrid solar gas-turbine cycle with storage integration. Energy Procedia 49:1147–1156 CrossRef
Grove DM, Davis TP (1992) Engineering, quality and experimental design. Longman Scientific & Technical, Essex
Hans V, Windorfer H (2003) Comparison of pressure and ultrasound measurements in vortex flow meters. Meas 33:121–133 CrossRef
Henry M, Tombs M, Zamora M, Zhou F (2013) Coriolis mass flow metering for three-phase flow: a case study. Flow Meas Instrum 30:112–122 CrossRef
Herrmann U, Kearney D, Röger M, Prahl C (2017) System performance measurements. In: Heller P (ed) The performance of concentrated solar power (CSP) systems: analysis, measurement and assessment. Woodhead Publishing, Duxford, pp 115–163 CrossRef
Ho C (2017) Advances in central receivers for concentrating solar applications. Sol Energy 152:38–56 CrossRef
Incropera F, DeWitt D, Bergman T, Lavine A (2007) Fundamentals of heat and mass transfer, 6th edn. Wiley, New Jersey
International Organization for Standardization (1997a) Standard 3977-1: General introduction and definitions. International Organization for Standardization (ISO), Geneva
International Organization for Standardization (1997b) Standard 3977-2: gas turbine—procurement—Part 2: Standard reference conditions and ratings. International Organization for Standardization, Geneva
International Organization for Standardization (2002) Standard 3977-4: Gas turbine—procurement—Part 4: Fuels and environment. International Organization for Standardization, Geneva
International Organization for Standardization (2004) Standard 3977-3: gas turbine—procurement—Part 3: design requirements. International Organization for Standardization, Geneva
International Organization of Standardization (2009) ISO Standard 2314: Gas turbines—acceptance tests. International Organization of Standardization, Geneva
International Organization of Standardization (2013) ISO Standard 9806: solar energy—solar thermal collectors—test methods. International Organization of Standardization, Geneva
International Organization of Standardization (2016) ISO 19859 Standard: gas turbine applications-requirements for power generation. International Organization for Standardization, Geneva
International Organization of Standardization (2017) ISO Standard 20816-2: mechanical vibration—measurement and evaluation of machine vibration—Part 2: land-based gas turbines, steam turbines and generators in excess of 40 MW with fluid-film bearings. International Organization of Standardization, Geneva
Janotte N, Wilbert S, Sallaberrt F, Schroedter-Homscheidt M, Ramirez L (2017) Principles of CSP performance assessment. In: Heller P (ed) The performance of concentrated solar power (CSP) systems: modelling. Woodhead Publishing, Measurement and Assessment, pp 31–64 CrossRef
Kardooni R, Yusoff S, Kari F (2016) Renewable energy technology acceptance in Peninsular Malaysia. Energy Policy 88:1–10 CrossRef
Koopmans T (1951) Analysis of production as an efficient combination of activities. Wiley and Sons, New York MATH
Korzynietz R, Brioso JA, del Río A, Quero M, Gallas M, Uhlig R, Ebert M, Buck R, Teraji D (2016) Solugas—comprehensive analysis of the solar hybrid Brayton plant. Sol Energy 135:578–589 CrossRef
Ligrani P, Potts G, Fatemi A (2017) Endwall aerodynamic losses from turbine components within gas turbine engines. Propul Pow Res 6(1):1–14 CrossRef
Madhavan S, Jain R, Sujatha C, Sekhar AS (2014) Vibration based damage detection of rotor blades in a gas turbine engine. Eng Fail Anal 46:26–39 CrossRef
Madhlopa A, Okoroigwe E (2017) Solar gas turbine systems. In: Abraham M (ed) Encyclopedia of sustainable technologies. Elsevier, Amsterdam, pp 377–388 CrossRef
Maia TA, Faria OA, Barros JE, Porto MP, Filho BJ (2017) Test and simulation of an electric generator driven by a micro-turbine. Electr Pow Syst Res 147:224–232 CrossRef
Nafey A, Abdelkader M, Abdelmotalip A, Mabrouk A (2000) Parameters affecting solar still productivity. Energy Convers Manag 41:1797–1809 CrossRef
Next-CSP (2016) High Temperature concentrated solar thermal power plant with particle receiver and direct thermal storage. http://​next-csp.​eu. Accessed 4 Oct 2017
Nguyen HA, Iperen ZV, Raghunath S, Abramson D, Kipouros T, Somasekharan S (2017) Multi-objective optimisation in scientific workflow. Procedia Comput Sci 108:1443–1452 CrossRef
Nicholas J, White D (1994) Traceable temperatures: an introduction to temperature measurement and calibration. John Wiley & Sons, New York
Okoroigwe E, Madhlopa A (2016) An integrated combined cycle system driven by a solar tower: a review. Renew Sustain Energy Rev 57:337–350 CrossRef
Peterseim J, White S, Tadros A, Hellwig U (2013) Concentrated solar power hybrid plants, which technologies are best suited for hybridisation? Renew Energy 57:520–532 CrossRef
Pfahl A, Coventry J, Röger M, Wolfertstetter F, Vásquez-Arango JF, Gross F, Arjomandi M, Schwarzbözl P, Geiger M, Liedke P (2017) Progress in heliostat development. Sol Energy 152:3–37 CrossRef
Röger M, Prahl C, Pernpeintner J, Sutter F (2017) New methods and instruments for performance and durability assessment. In: Heller P (ed) The performance of concentrated solar power (CSP) systems: modelling. Woodhead Publishing, Measurement and Assessment, pp 205–252 CrossRef
Rybicka J, Tiwari A, Leeke G (2016) Technology readiness level assessment of composites recycling technologies. J Clean Prod 112:1001–1012 CrossRef
Salomé A, Chhel F, Flamant G, Ferrière A, Thiery F (2013) Control of the flux distribution on a solar tower receiver using an optimized aiming point strategy: application to THEMIS solar tower. Sol Energy 94:352–366 CrossRef
Schwarzbözl P, Buck R, Sugarmen C, Ring A, Crespo MJ, Altwegg P, Enrile J (2006) Solar gas turbine systems: design, cost and perspectives. Sol Energy 80:1231–1240 CrossRef
Selman JR, Chen C (2012) Scientific and technical maturity of molten carbonate technology. Int J Hydrog Energy 37:19280–19288 CrossRef
Singh V, Tharakan T (2015) Numerical simulations for multi-hole orifice flow meter. Flow Meas Instrum 45:375–383 CrossRef
SOLGATE (2005) Solar hybrid gas turbine electric power system: final publishable report. European Communities, Luxembourg
SOLHYCO (2011) Solar-Hybrid Power and Cogeneration Plants: Final Public Report. German Aerospace Centre (Deutsches Zentrum für Luft- und Raumfahrt, DLR), Cologne
Srilakshmi G, Venkatesh V, Thirumalai N, Suresh N (2015) Challenges and opportunities for solar tower technology in India. Renew Sustain Energy Rev 45:698–709 CrossRef
Stein WH, Buck R (2017) Advanced power cycles for concentrated solar power. Sol Energy 152:91–105 CrossRef
Stemmler H (1994) High-power industrial drives. Institute of Electrical and Electronics Engineers, New Jersey
Straub J (2015) In search of technology readiness level (TRL) 10. Aerosp Sci Technol 46:312–320 CrossRef
Sun H, Gong B, Yao Q (2014) A review of wind loads on heliostats and trough collectors. Renew Sustain Energy Rev 32:06–221 CrossRef
Toft M, Schuitema G, Thøgersen J (2014) Responsible technology acceptance: model development and application to consumer acceptance of Smart Grid technology. Appl Energy 134:392–400 CrossRef
Wang J, Jing Y, Zhang C, Zhao J (2009) Review on multi-criteria decision analysis aid in sustainable energy decision-making. Renew Sustain Energy Rev 13:2263–2278 CrossRef
Wang Y, Wallace S, Shen B, Choi T (2015) Service supply chain management: a review of operational models. Eur J Oper Res 247:685–698 CrossRef
Watral Z, Jakubowski J, Michalski A (2015) Electromagnetic flow meters for open channels: current state and development prospects. Flow Meas Instrum 42:16–25 CrossRef
World Bank (1999) Mexico—hybrid solar thermal power plant project: report number PID8128. World Bank, Washington DC
Xiaodong Q, Xiuli S (2015) Multidisciplinary design optimization of turbine disks based on ANSYS workbench platform. Procedia Eng 99:1275–1283 CrossRef
Xie L, Zhao Y, Aziz D, Jin X, Geng L, Goberdhansingh E, Qi F, Huang B (2013) Soft sensors for online steam quality measurements of OTSGs. J Process Contr 23:990–1000 CrossRef
Xu Y, Yu P, Zhu Z, Yuan C, Zhang T (2017) Over-reading modeling of the ultrasonic flow meter in wet gas measurement. Meas 98:17–24 CrossRef
Zhang HL, Baeyens J, Degrève J, Cacères G (2013) Concentrated solar power plants: review and design methodology. Renew Sustain Energy Rev 22:466–481 CrossRef
Zhang G, Zhang B, Halang WA (2018) Power electronics converters: past, present and future. Renew Sustain Energy Rev 81:2028–2044 CrossRef
Zhou H, Ji T, Wang R, Ge X, Tang X, Tang S (2018) Multipath ultrasonic gas flow-meter based on multiple reference waves. Ultrasonics 82:145–152 CrossRef
Metadaten
Titel
Design and Testing of Solar Gas Turbines
verfasst von
Amos Madhlopa
Copyright-Jahr
2018
Buch
Principles of Solar Gas Turbines for Electricity Generation

Print ISBN: 978-3-319-68387-4

Electronic ISBN: 978-3-319-68388-1

Copyright-Jahr: 2018

DOI
https://doi.org/10.1007/978-3-319-68388-1_7

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