This paper describes a gas turbine combined cycle (GTCC) power plant system, which addresses the three key design challenges of postcombustion CO2 capture from the stack gas of a GTCC power plant using aqueous amine-based scrubbing method by offering the following: (i) low heat recovery steam generator (HRSG) stack gas temperature, (ii) increased HRSG stack gas CO2 content, and (iii) decreased HRSG stack gas O2 content. This is achieved by combining two bottoming cycle modifications in an inventive manner, i.e., (i) high supplementary (duct) firing in the HRSG and (ii) recirculation of the HRSG stack gas. It is shown that, compared to an existing natural gas-fired GTCC power plant with postcombustion capture, it is possible to reduce the CO2 capture penalty—power diverted away from generation—by almost 65% and the overall capital cost ($/kW) by about 35%.

Issue Section:
Gas Turbines: Cycle Innovations
Keywords:
Energy, Energy conversion, Gas turbine technology, Power , Power systems, Thermodynamics, Co- generation
Topics:
Carbon capture and storage, Carbon dioxide, Ducts, Gas turbines, Heat recovery steam generators, Steam, Temperature, Combined cycles, Flow (Dynamics), Pressure, Firing, Exhaust systems, Flue gases, Design, Power stations

References

1.
CCST, 2018, “
MIT CCS Project Database
,” Carbon Capture & Sequestration Technologies, Cambridge, MA, accessed Apr 6, 2018, https://sequestration.mit.edu/tools/projects/ccs_project_updates.html
2.
VGB, 2018, “
CO2 Capture and Storage, a VGB Report on the State of the Art
,” VGB PowerTech e.V, Essen, Germany, Report.
3.
IEA GHG
,
2000
, “
Leading Options for the Capture of CO2 Emissions at Power Stations
,” International Energy Agency Greenhouse Gas R&D Programme, Cheltenham, UK, Report No. PH3/14.
4.
Bolland
,
O.
,
2002
, “
Gaskraftverk med CO2-håndtagning. Studie av alternative teknologier
,” SINTEF Energiforskning AS, Trondheim, Norway, Report No. TR A5693 (in Norwegian).
5.
Gas Turbine World, 2015,
Gas Turbine World 2014-15 Handbook
, Vol.
31
,
Pequot Publishing
,
Fairfield, CT
.
6.
Rollins
,
W. S.
, III,
2003
, “
High Power Density Combined Cycle Power Plant System
,” U.S. Patent No.
6,606,848, B1
.https://patents.google.com/patent/US6606848
7.
Tanaka
,
Y.
,
Nose
,
M.
,
Nakao
,
M.
,
Saitoh
,
K.
,
Ito
,
E.
, and
Tsukagoshi
,
K.
,
2013
, “
Development of Low NOx Combustion System With EGR for 1700 °C-Class Gas Turbine
,”
Mitsubishi Heavy Ind. Tech. Rev.
,
50
(
1
), pp. 1–7.http://www.mhi.co.jp/technology/review/pdf/e501/e501001.pdf
8.
Elkady
,
A. M.
,
Evulet
,
A.
,
Brand
,
A.
,
Ursin
,
T. P.
, and
Lynghjem
,
A.
,
2009
, “
Application of Exhaust Gas Recirculation in a DLN F-Class Combustion System for Postcombustion Carbon Capture
,”
ASME J. Eng. Gas Turbines Power
,
131
(
3
), p.
034505
.
Google Scholar
Crossref
Search ADS
 
9.
Thermoflow, 2018, “
Thermoflow Suite, Version 25.0.1
,” Thermoflow, Southborough, MA.
10.
Wilcox
,
J.
,
2012
,
Carbon Capture
,
Springer
,
New York
.
11.
BRE, 2018, “
ProMax® 3.2
,”
Bryan Research & Engineering
,
Bryan, TX
.
12.
NETL, 2015, “Cost and Performance Baseline for Fossil Energy Plants Volume 1a: Bituminous Coal (PC) and Natural Gas to Electricity Revision 3,” National Energy Technology Laboratory, Pittsburgh, PA, Report No. DOE/NETL-2015/1723.
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