A Thermoeconomic Study of Low-Temperature Intercooled-Recuperated Cycles for Pure-Solar Gas-Turbine Applications

James Spelling; Björn Laumert; Torsten Fransson

Source: Journal of Solar Energy Engineering:;2012:;volume( 134 ):;issue: 004::page 41015

Author:

James Spelling

Björn Laumert

Torsten Fransson

DOI: 10.1115/1.4007532

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: A dynamic model of a megawatt-scale low-temperature intercooled-recuperated solar gas-turbine power plant has been developed in order to allow determination of the thermodynamic and economic performance. The model was then used for multi-objective thermoeconomic optimization of both the power plant performance and cost, using a population-based algorithm. In order to examine the trade-offs that must be made and identify ‘optimal’ plant sizes and operating conditions, two conflicting objectives were considered, namely minimum investment costs and maximum annual electricity production. Levelized electricity costs from a 65 MWe power plant operating at 950 °C are predicted to be below 130 USD/MWhe , competitive with other solar thermal power technologies. Optimal plant sizes and configurations have been identified.

keyword(s): Temperature , Gas turbines , Optimization , Power stations , Solar energy , Cycles , Industrial plants , Water , Low temperature , Heat exchangers , Design , Pipes , Modeling AND Algorithms ,

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A Thermoeconomic Study of Low-Temperature Intercooled-Recuperated Cycles for Pure-Solar Gas-Turbine Applications

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contributor author	James Spelling
contributor author	Björn Laumert
contributor author	Torsten Fransson
date accessioned	2017-05-09T00:54:18Z
date available	2017-05-09T00:54:18Z
date copyright	November, 2012
date issued	2012
identifier issn	0199-6231
identifier other	JSEEDO-926222#041015_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/150199
description abstract	A dynamic model of a megawatt-scale low-temperature intercooled-recuperated solar gas-turbine power plant has been developed in order to allow determination of the thermodynamic and economic performance. The model was then used for multi-objective thermoeconomic optimization of both the power plant performance and cost, using a population-based algorithm. In order to examine the trade-offs that must be made and identify ‘optimal’ plant sizes and operating conditions, two conflicting objectives were considered, namely minimum investment costs and maximum annual electricity production. Levelized electricity costs from a 65 MWe power plant operating at 950 °C are predicted to be below 130 USD/MWhe , competitive with other solar thermal power technologies. Optimal plant sizes and configurations have been identified.
publisher	The American Society of Mechanical Engineers (ASME)
title	A Thermoeconomic Study of Low-Temperature Intercooled-Recuperated Cycles for Pure-Solar Gas-Turbine Applications
type	Journal Paper
journal volume	134
journal issue	4
journal title	Journal of Solar Energy Engineering
identifier doi	10.1115/1.4007532
journal fristpage	41015
identifier eissn	1528-8986
keywords	Temperature
keywords	Gas turbines
keywords	Optimization
keywords	Power stations
keywords	Solar energy
keywords	Cycles
keywords	Industrial plants
keywords	Water
keywords	Low temperature
keywords	Heat exchangers
keywords	Design
keywords	Pipes
keywords	Modeling AND Algorithms
tree	Journal of Solar Energy Engineering:;2012:;volume( 134 ):;issue: 004
contenttype	Fulltext

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