Prediction of NO_x Emissions from High-temperature Gas Turbines : Numerical Simulation for Low-NO_x Combustion
スポンサーリンク
概要
- 論文の詳細を見る
In recent years, turbine inlet temperatures in gas turbine systems have continued to rise in order to enhance efficiency and performance. However, higher temperatures results in increased levels of NO_x emission and this in turn seriously affect the environment. Development of prediction methods for NO_x emissions is important, since this allows one to evaluate the environmental contributions of gas turbine systems. The gas turbine combustor geometries are very complex so that the flow pattern, chemical and thermal field inside the combustor is very complex. Numerical methods for predicting the performance of the combustor and NO_x formation and emission levels are attractive as they provide inexpensive solutions to the complex geometry problem without physically building the hardware. This paper provides numerical simulations for predicting the NO_x emissions from gas turbine systems using : (i) chemical equilibrium and simplified kinetic reaction approaches, and (ii) flamelet and reaction progress variable approaches.
- 社団法人日本機械学会の論文
- 2002-05-15
著者
-
Gupta A
Univ. Maryland Md
-
YAMAMOTO Takahisa
Research Center for Advanced Energy Conversion, Nagoya University
-
FURUHATA Tomohiko
Research Center for Advanced Energy Conversion, Nagoya University
-
ARAI Norio
Research Center for Advanced Energy Conversion, Nagoya University
-
GUPTA Ashwani
University of Maryland, College Park
-
Arai N
Nagoya Univ. Nagoya Jpn
-
Furuhata Tomohiko
Research Center For Advanced Energy Conversion
-
Furuhata T
Research Center For Advanced Energy Conversion Nagoya University
-
Arai Norio
Research Center For Advanced Energy Conversion
-
Gupta Ashwani
University Of Maryland College Park
-
Yamamoto Takahisa
Research Center For Advanced Energy Conversion Nagoya University
関連論文
- Prediction of NO_x Emissions from High-temperature Gas Turbines : Numerical Simulation for Low-NO_x Combustion
- Raman Scattering In (1 - X)Pb(Zn_Nb_)O_PbTiO_3 Mixed Crystal System II
- Effect of Raw-Fuel Flow Rate on Soot Formation Reaction in Carbon Black Furnace
- Non-Oxidizing Heating by High Temperature Nitrogen Gas Jet Stream
- Research of Energy Conversion and Environmental Technologies in Research Center for Advanced Energy Conversion Nagoya University (RAN)(Letters from R&D Groups)
- An Appraisal of Experimental, Predictive and Correlative Contributions to Fully Developed Turbulent Flow in a Round Tube
- An Appraisal of Resources and Methodologies for Prediction of Flow and Convection in Channels
- A New Concept of Correlation for Turbulent Convection
- Combustion Technology in a Novel Gas Turbine System with Steam Injection and Two-Stage Combustion
- A112 High Efficiency Gas Tuirbine Cogeneration System Using High-Level Steam Addition (HISA) Cycle(Advanced thermal system analysis-2)
- A101 COMBUSTION CHARACTERISTICS UNDER CONDITION OF LOW-OXYGEN ATMOSPHERE AND HIGH-LEVEL STEAM ADDITION(Nuclear power-1/combustion)
- Spectroscopic Two-dimensional Observation of Flames in an Industrial Furnace for Steel Processing
- IMPROVEMENT OF HIGH-TEMPERATURE ENDURANCE OF C/C COMPOSITES BY DOUBLE COATING WITH SiC AND GLASS MATERIALS
- Effects of Isoflurane on Kinetics of N_2O Catalytic Decomposition over Rh/Al_2O_3 in Medical Operating Rooms
- Excitation Characteristics and Matrix Effect in a Helium Radiofrequency Atomization and Excitation Source for Atomic Emission Spectrometry
- Improvement in Oxidation Resistance of a C/C Composite by Using CVD-SiC Coating with SiC Fiber-Composite Layer
- Intercalation of Spirooxazine Induced by Zinc Cation Chelation in Montmorillonite and Its Photochromic Behavior
- Passive Enhancement Technique for Free Convection-Dominated Melting of Phase Change Material in Horizontal Cylindrical Annulus
- The Characteristics of Heat Transfer and the Decomposition of N_2O in a Double-Spiral Heat Exchanger/Catalytic Reactor