Presentation is loading. Please wait.

Presentation is loading. Please wait.

Conceptual Gas Turbine Modeling for Oxy-Fuel Power Cycles TURBO POWER Program Conference 14 April 2011 Egill Maron Thorbergsson Department of Applied Mechanics.

Published byArabella Briggs Modified over 8 years ago

Similar presentations

Presentation on theme: "Conceptual Gas Turbine Modeling for Oxy-Fuel Power Cycles TURBO POWER Program Conference 14 April 2011 Egill Maron Thorbergsson Department of Applied Mechanics."— Presentation transcript:

1 Conceptual Gas Turbine Modeling for Oxy-Fuel Power Cycles TURBO POWER Program Conference 14 April 2011 Egill Maron Thorbergsson Department of Applied Mechanics Chalmers

2 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Cycle analysis of Graz cycle and SCOC Conceptual turbomachinery design Component optimization Full cycle optimization Project objectives

3 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Introduction Joint Chalmers University/Lund University project –Project started 18 th Jan. 2010 Design components for two cycles; the Graz cycle and the semi-closed oxy-fuel combustion combined cycle Develop design tools to design turbomachinery components in oxy-fuel cycles. Conceptual design work is divided according to: –Chalmers focuses on compressor design –Lund University focuses on turbine design

4 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak What is an oxy-fuel combustion cycle? Oxygen is separated from air before combustion –Working fluid is different –Carbon dioxide in semi closed oxy-fuel combustion combined cycle (SCOC-CC) –Water (steam) in the Graz cycle  different design principles for the gas turbine

5 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak What is an oxy-fuel combustion cycle? Oxygen is separated from air before combustion –Working fluid is different –Carbon dioxide in semi closed oxy-fuel combustion combined cycle (SCOC-CC) –Water (steam) in the Graz cycle  different design principles for the gas turbine

6 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak What is a conceptual design tool? One step beyond traditional thermodynamic analysis by estimating the key dimensions of the gas turbine Thermodynamics, aerodynamics and mechanics constraints

7 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Conceptual compressor design In-house tool –Mean line design tool Handles non-ideal fluids (REFPROP) –Wright & Miller loss correlations Adapted to oxy-fuel gas composition Implemented in MATLAB Calibrated against NASA data (Ideal gases) Transonic compressors Suitable for double circular arc profile Selection of incidence angles and pitch-cord and aspect ratio based on McKenzie

8 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak SCOC-CC – Compressor Meanline design Sammak, M. et al. ”CONCEPTUAL DESIGN OF A MID-SIZED, SEMI-CLOSED OXY-FUEL COMBUSTION COMBINED CYCLE” ASME TURBO EXPO 2010

9 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Conceptual optimization approach ISABE conference in Göteborg september 2011. –Multicriteria optimization of conceptual compressor aerodynamic design

10 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Multidisciplinary conceptual design of a transonic high pressure compressor –Funda Ersavas –Started in November and will finish in June (60 credits) Master Thesis

11 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Cycle analysis of Graz cycle and SCOC Conceptual turbomachinery design Component optimization Full cycle optimization Project objectives

12 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak SCOC-CC Semi-Closed Oxy-fuel Combustion Combined Cycle TURBO POWER Program Conference, Gothenburg 14 April 2011 Majed Sammak Lund University

13 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Topics Introduction Calculations Results Papers

14 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Introduction Purpose –Combined cycle –CO 2 capture system Description Requirements –Competes with other CO 2 capture systems Post combustion –Chilled Ammonia –Advanced Ammine Pre combustion Oxy fuel combustion

15 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Introduction Requirements –CO 2 capture efficiency –Impact on environments –Energy consumption ASU CO 2 compression Integration –Availability Integration Components design

16 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Calculations 1.Changing the working fluid from Air to CO 2 2. Heavier gas, Lower speed of sound  Impact both in the cycle design and gas turbine design Thermodynamic properties UnitsAirCarbon dioxide CpCp kJ/kg  C 1.0050.846 CvCv kJ/kg  C 0.7180.657 R kJ/kg  C 0.2870.189 γ-1.41.289 ρkg/m 3 1.21.84 Mkg/kmol28.9 44.01

17 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Calculations 1.Cycle simulation: IPSEpro+REFPROP –Impact on cycle Oxy combustion COT around 1400 o C Gas turbine cooling from the compressor 30% from turbine inlet flow –Work done Mid-sized, semi-closed dual-pressure oxy-fuel combustion combined cycle 136 MW ( Gross power), 108 MW (Net power). Gas turbine cooling Optimization

18 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Calculations

19 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Calculations Single shaft -Complex + Higher rotations speed + Less stages Twin shaft + Simple -Bigger compressor -Lower rotations speed

20 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Calculations Single shaft (Turbine design) –Lower Speed of sound  Higher Mach number –Mach number limitations to 0.6

21 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Results SCOC-CC Compressor mass flowkg/s190 Compressor pressure ratio-39 Combustor outlet temp. oCoC1400 Gas turbine power, TurbineMW156 Gas turbine power, Compressor MW 67 Gas turbine power MW 87 Total heat inputMW230 Steam turbine powerMW49 Gross power outputMW136 Gross efficiency%59 O 2 generation + CompressionMW23 CO 2 compression to 200 barMW5 Net power outputMW108 Net efficiency%47

22 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Results Turbine design –N=5200 rpm –U=380 m/s –AN 2 = 40  10 6 –4 stages

23 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Papers Work Done: ASME paper: Conceptual Design of A mid-sized Semi- Closed Oxy-Fuel Combustion Combined Cycle, Draft- GT2011-46299 Accepted Master thesis: ”Parametric Blade Profiling Methods and Improvements on LUAX-T With Emphasis on Oxy-Fuel Cycles”, Jonas Svensson –Rapid 11 parameter blade profiling with start-value recommendations –Radiation from three-atomic gas

24 Chalmers – Egill Thorbergsson / Lund University – Majed Sammak Parametric blade profiling

Download ppt "Conceptual Gas Turbine Modeling for Oxy-Fuel Power Cycles TURBO POWER Program Conference 14 April 2011 Egill Maron Thorbergsson Department of Applied Mechanics."

Similar presentations

A novel IGCC system with steam injected H2/O2 cycle and CO2 recovery P M V Subbarao Professor Mechanical Engineering Department Low Quality Fuel but High.

A novel IGCC system with steam injected H2/O2 cycle and CO2 recovery P M V Subbarao Professor Mechanical Engineering Department Low Quality Fuel but High.
Thermodynamics & Gas dynamics of Real Combustion in Turbo Combustor P M V Subbarao Professor Mechanical Engineering Department Tools for precise estimation.

Thermodynamics & Gas dynamics of Real Combustion in Turbo Combustor P M V Subbarao Professor Mechanical Engineering Department Tools for precise estimation.
Lecture #12 Ehsan Roohi Sharif University of Technology Aerospace Engineering Department 1.

Lecture #12 Ehsan Roohi Sharif University of Technology Aerospace Engineering Department 1.
Advanced Thermodynamics Note 6 Applications of Thermodynamics to Flow Processes Lecturer: 郭修伯.

Advanced Thermodynamics Note 6 Applications of Thermodynamics to Flow Processes Lecturer: 郭修伯.
Jet Engine Design Idealized air-standard Brayton cycle

Jet Engine Design Idealized air-standard Brayton cycle
ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma.

ENGR 2213 Thermodynamics F. C. Lai School of Aerospace and Mechanical Engineering University of Oklahoma.
Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lect 27b Jet Aircraft Propulsion.

Department of Mechanical Engineering ME 322 – Mechanical Engineering Thermodynamics Lect 27b Jet Aircraft Propulsion.
Jet Engine Design 1 23 4 5 6 diffuser compressor combustion chamber turbine nozzle 1 2 3 4 5 6 P=constant q out q in T s 1-2 Isentropic compression in.

Jet Engine Design diffuser compressor combustion chamber turbine nozzle P=constant q out q in T s 1-2 Isentropic compression in.
Effect of Piston Dwell on Engine Performance P M V Subbarao Professor Mechanical Engineering Department Sufficiency of time to Execute a Process…..

Effect of Piston Dwell on Engine Performance P M V Subbarao Professor Mechanical Engineering Department Sufficiency of time to Execute a Process…..
Introduction to Propulsion

Introduction to Propulsion
Lecture 7 – Axial flow turbines

Lecture 7 – Axial flow turbines
SINTEF Energy Research Power cycles with CO 2 capture – combining solide oxide fuel cells and gas turbines Dr. ing. Ola Maurstad.

SINTEF Energy Research Power cycles with CO 2 capture – combining solide oxide fuel cells and gas turbines Dr. ing. Ola Maurstad.
Lecture 5 Shaft power cycles Aircraft engine performance

Lecture 5 Shaft power cycles Aircraft engine performance
Chapter 1 VAPOR AND COMBINED POWER CYCLES

Chapter 1 VAPOR AND COMBINED POWER CYCLES
ENERGY CONVERSION ES 832a Eric Savory www.eng.uwo.ca/people/esavory/es832.htm Lecture 11 – A small-scale power plant worked example Department of Mechanical.

ENERGY CONVERSION ES 832a Eric Savory Lecture 11 – A small-scale power plant worked example Department of Mechanical.
“Energy Efficiency Guide for Industry in Asia”

“Energy Efficiency Guide for Industry in Asia”
Gas turbine cycles for aircraft propulsion In shaft power cycles, power is in form of generated power. In air craft cycles, whole power is in the form.

Gas turbine cycles for aircraft propulsion In shaft power cycles, power is in form of generated power. In air craft cycles, whole power is in the form.
Shaft Power Cycles Ideal cycles Assumptions:

Shaft Power Cycles Ideal cycles Assumptions:
MAE431-Energy System Presentation

MAE431-Energy System Presentation
Combined_Cycle_Power_Plant Prepared by: Nimesh Gajjar.

Combined_Cycle_Power_Plant Prepared by: Nimesh Gajjar.

Similar presentations

Ads by Google