Operational- Economics Based Evaluation And Selection of A Power Plant Using Graph Theoretic Approach
This paper presents a methodology for operational and
economic characteristics based evaluation and selection of a power
plant using Graph theoretic approach. A universal evaluation index
on the basis of Operational and economics characteristics of a plant is
proposed which evaluates and ranks the various types of power plants.
The index thus obtained from the pool of operational characteristics
of the power plant attributes Digraph. The Digraph is developed
considering Operational and economics attributes of the power plants
and their relative importance for their smooth operation, installation
and commissioning and prioritizing their selection. The sensitivity
analysis of the attributes towards the objective has also been carried
out in order to study the impact of attributes over the desired outcome
i.e. the universal operational-economics index of the power plant.
[1] Mohan, M. and Gandhi, OP and Agrawal, VP,Systems modelling of a coalbased
steam power plant Proceedings of the Institution of Mechanical
Engineers, Part A: Journal of Power and Energy, volume 217, pages 259-
277, number 3, 2003
[2] Gupta, V. K and Agrawal, V P,Quality evaluation of a thermal power plant
by Graph-Theoretical methodology, International Journal of Power and
Energy Systems, volume 27, number 1,2007
[3] Mohan, M. and Gandhi, O P and Agrawal, V P,Maintenance strategy for
a coal-based steam power plant equipment: a graph theoretic approach
Proceedings of the Institution of Mechanical Engineers, Part A: Journal
of Power and Energy, volume 218, pages 619-636, number 8, 2004
[4] Heppenstall, T.,Advanced gas turbine cycles for power generation: a
critical review Applied Thermal Engineering, volume 18, pages 837-846,
number 9-10, 1998
[5] Najjar, Y. S. H.,Gas turbine cogeneration systems: a review of some novel
cycles Applied thermal engineering, volume 20, pages 179-197, number
2, 2000
[6] Beer, J.M.,High efficiency electric power generation: The environmental
role, Jourmal of Progress in Energy and Combustion Science, volume
33, pages 107-134, number 2, 2007
[7] Guarinello Jr, F. and Cerqueira, S. A. A. G. and Nebra,
S. A.,Thermoeconomic evaluation of a gas turbine cogeneration
system, Energy conversion and management, volume 41, pages
1191-1200, number 11, 2000
[8] Sue, D.C. and Chuang, C.C.,Engineering design and exergy analyses for
combustion gas turbine based power generation system Energy, volume
29, pages 1183-1205, number 8, 2004
[9] Kanoglu, M. and Dincer, I.,Performance assessment of cogeneration
plants Energy Conversion and Management, volume 50, pages 76-81,
number 1, 2009
[10] Knight, R. and Perz, E. and Traverso, A. and others, GTPOM: Thermoeconomic
optimization of whole gas turbine plant Journal of Engineering
for Gas Turbines and Power, volume 128, pages 535, 2006
[11] Danov, S. N. and Gupta, A. K.,Modeling the Performance Characteristics
of Diesel Engine Based Combined-Cycle Power PlantsPart I:
Mathematical Model, Journal of Engineering for Gas Turbines and
Power, volume 126, pages 28, 2004
[12] Xiaotao, Z. and Hideaki, S. and Weidou, N I and Zheng, L I,Economics
and Performance Forecast of Gas Turbine Combined Cycle environment,
volume 1, pages 3, 2005
[13] Polyzakis, A L and Koroneos, C. and Xydis, G.,Optimum gas turbine
cycle for combined cycle power plant Energy conversion and management,
volume 49, pages 551-563, number 4, 2008
[14] Emberger H. and Hofman D. and Kolk C.,Economic evaluation of
Cycling plants- An approach to show the value of Operational flexibility
SIEMENS Power Plant References, 2007
[15] Meherwan P. Boyce, Gas Turbine Engineering Handbook Gulf
Professional Publishing, 2002
[1] Mohan, M. and Gandhi, OP and Agrawal, VP,Systems modelling of a coalbased
steam power plant Proceedings of the Institution of Mechanical
Engineers, Part A: Journal of Power and Energy, volume 217, pages 259-
277, number 3, 2003
[2] Gupta, V. K and Agrawal, V P,Quality evaluation of a thermal power plant
by Graph-Theoretical methodology, International Journal of Power and
Energy Systems, volume 27, number 1,2007
[3] Mohan, M. and Gandhi, O P and Agrawal, V P,Maintenance strategy for
a coal-based steam power plant equipment: a graph theoretic approach
Proceedings of the Institution of Mechanical Engineers, Part A: Journal
of Power and Energy, volume 218, pages 619-636, number 8, 2004
[4] Heppenstall, T.,Advanced gas turbine cycles for power generation: a
critical review Applied Thermal Engineering, volume 18, pages 837-846,
number 9-10, 1998
[5] Najjar, Y. S. H.,Gas turbine cogeneration systems: a review of some novel
cycles Applied thermal engineering, volume 20, pages 179-197, number
2, 2000
[6] Beer, J.M.,High efficiency electric power generation: The environmental
role, Jourmal of Progress in Energy and Combustion Science, volume
33, pages 107-134, number 2, 2007
[7] Guarinello Jr, F. and Cerqueira, S. A. A. G. and Nebra,
S. A.,Thermoeconomic evaluation of a gas turbine cogeneration
system, Energy conversion and management, volume 41, pages
1191-1200, number 11, 2000
[8] Sue, D.C. and Chuang, C.C.,Engineering design and exergy analyses for
combustion gas turbine based power generation system Energy, volume
29, pages 1183-1205, number 8, 2004
[9] Kanoglu, M. and Dincer, I.,Performance assessment of cogeneration
plants Energy Conversion and Management, volume 50, pages 76-81,
number 1, 2009
[10] Knight, R. and Perz, E. and Traverso, A. and others, GTPOM: Thermoeconomic
optimization of whole gas turbine plant Journal of Engineering
for Gas Turbines and Power, volume 128, pages 535, 2006
[11] Danov, S. N. and Gupta, A. K.,Modeling the Performance Characteristics
of Diesel Engine Based Combined-Cycle Power PlantsPart I:
Mathematical Model, Journal of Engineering for Gas Turbines and
Power, volume 126, pages 28, 2004
[12] Xiaotao, Z. and Hideaki, S. and Weidou, N I and Zheng, L I,Economics
and Performance Forecast of Gas Turbine Combined Cycle environment,
volume 1, pages 3, 2005
[13] Polyzakis, A L and Koroneos, C. and Xydis, G.,Optimum gas turbine
cycle for combined cycle power plant Energy conversion and management,
volume 49, pages 551-563, number 4, 2008
[14] Emberger H. and Hofman D. and Kolk C.,Economic evaluation of
Cycling plants- An approach to show the value of Operational flexibility
SIEMENS Power Plant References, 2007
[15] Meherwan P. Boyce, Gas Turbine Engineering Handbook Gulf
Professional Publishing, 2002
@article{"International Journal of Electrical, Electronic and Communication Sciences:51639", author = "Naresh Yadav and I.A. Khan and Sandeep Grover", title = "Operational- Economics Based Evaluation And Selection of A Power Plant Using Graph Theoretic Approach", abstract = "This paper presents a methodology for operational and
economic characteristics based evaluation and selection of a power
plant using Graph theoretic approach. A universal evaluation index
on the basis of Operational and economics characteristics of a plant is
proposed which evaluates and ranks the various types of power plants.
The index thus obtained from the pool of operational characteristics
of the power plant attributes Digraph. The Digraph is developed
considering Operational and economics attributes of the power plants
and their relative importance for their smooth operation, installation
and commissioning and prioritizing their selection. The sensitivity
analysis of the attributes towards the objective has also been carried
out in order to study the impact of attributes over the desired outcome
i.e. the universal operational-economics index of the power plant.", keywords = "Power plant evaluation, Digraph methods, Matrixmethod, operational characteristics of Power plant, Gas turbines", volume = "4", number = "3", pages = "443-11", }