Second Law Efficiency of the Rankine Bottoming Cycle of a Combined Cycle Power Plant

Gülen, S. Can; Smith, Ronald C.

doi:10.1115/1.3124787

Cited by 23 publications

(12 citation statements)

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“…Based on the premise that there is a well-designed (or optimal) RBC design for a given GT exhaust, different technology curves in the form of/(Texh) can be generated. Such a curve is given in Giilen and Smith [24]. This optimal curve goes through the data points representing the RBC exergetic efficiencies extracted from the trade publication data and is adequately described by the following formula:…”

Section: Rankine Bottoming Cycle (Rbc)mentioning

confidence: 99%

“…The net heat import and the ST power contribution can be evaluated in a manner similar to that for the gasifier via Eqs. (24). and (14) by replacing 0GSF with QQC-Typical values for non-CCS systems are provided in Table 1.…”

Section: (22)mentioning

confidence: 99%

“…Transactions of the ASME effective steam temperature is evaluated from the HRSG feed water supply and steam return (import) conditions as [24] .f _ "stin,i ~ hfw,i…”

Section: -^(14)mentioning

confidence: 99%

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Simple Parametric Model for Quick Assessment of IGCC Performance

Gülen¹,

Driscoll

2012

Journal of Engineering for Gas Turbines and Power

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Even though almost all components of an integrated gasification combined cycle (IGCC) power plant are proven and mature technologies, the sheer number of them, the wide variety of competing technologies (e.g., gasifiers, gas clean-up systems, heat recovery options), and system integration options (e.g., cryogenic air separation unit and the gas turbine), including the recent addition of carbon capture and sequestration (CCS) with its own technology and integration options, render fundamental IGCC peiformance analysis a monumental task. Almost all published studies utilize highly complex chemical process and power plant heat balance software, including commercially availahle packages and in-house proprietary codes. This makes an objective assessment of comparable IGCC plant designs, performance (and cost), and other perceived advantage claims (IGCC versus other technologies, too) very difficult, if not impossible. This paper develops a coherent simplified parametric model based on fully physics-based grounds to be used for quick design performance assessment of a large variety of IGCC power plants with and without CCS. Technology parameters are established from complex model runs and supplemented by extensive literature search. The model is tested using published data to establish its confidence interval and is satisfactory to carry conceptual design analysis at a high level to identify promising alternatives and development areas and assess the realism in competing claims.

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Section: Rankine Bottoming Cycle (Rbc)mentioning

confidence: 99%

Section: (22)mentioning

confidence: 99%

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Simple Parametric Model for Quick Assessment of IGCC Performance

Gülen¹,

Driscoll

2012

Journal of Engineering for Gas Turbines and Power

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“…Gulen and Smith [184] described an accurate method based on the second law of thermodynamics to estimate the Rankine bottoming cycle power output directly from the gas turbine exhaust exergy. Woudstra et al [185] analyzed combined cycles using the same gas turbine but having the different number of pressure levels in heat recovery steam generator in the steam bottoming cycles.…”

Section: Gas Fired Combined Cycle Power Plantsmentioning

confidence: 99%

Thermodynamic performance evaluation of solar and other thermal power generation systems: A review

Gupta¹,

Kaushik

Ranjan

et al. 2015

Renewable and Sustainable Energy Reviews

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“…In addition, by decreasing the ambient temperature and increasing the humidity of the air, the output power can be increased. Gülen and Smith (2010) carried out a study on the Rankin bottoming cycle (RBC) efficiency of the combined cycle (CC). They developed a CC_RBC performance model based on the second law and exergy concept.…”

Section: Vmentioning

confidence: 99%

Thermodynamic Analysis of Different Configurations of Combined Cycle Power Plants

Ebaid¹,

Al-Hamdan²

2015

MER

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Several modifications have been made to the simple gas turbine cycle in order to increase its thermal efficiency but within the thermal and mechanical stress constrain, the efficiency still ranges between 38 and 42%. The concept of using combined cycle power or CPP plant would be more attractive in hot countries than the combined heat and power or CHP plant. The current work deals with the performance of different configurations of the gas turbine engine operating as a part of the combined cycle power plant. The results showed that the maximum CPP cycle efficiency would be at a point for which the gas turbine cycle would have neither its maximum efficiency nor its maximum specific work output. It has been shown that supplementary heating or gas turbine reheating would decrease the CPP cycle efficiency; hence, it could only be justified at low gas turbine inlet temperatures. Also it has been shown that although gas turbine intercooling would enhance the performance of the gas turbine cycle, it would have only a slight effect on the CPP cycle performance.

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Second Law Efficiency of the Rankine Bottoming Cycle of a Combined Cycle Power Plant

Cited by 23 publications

References 12 publications

Simple Parametric Model for Quick Assessment of IGCC Performance

Simple Parametric Model for Quick Assessment of IGCC Performance

Thermodynamic performance evaluation of solar and other thermal power generation systems: A review

Thermodynamic Analysis of Different Configurations of Combined Cycle Power Plants

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