Fuels, Combustion and Environmental Considerations in Industrial Gas Turbines - Introduction and Overview

Brian M Igoe & Michael J Welch Fuels, Combustion and Environmental Considerations in Industrial Gas Turbines - Introduction and Overview Restricted Siemens AG 20XX All rights reserved. siemens.com/answers

AGENDA Fuels, Combustion and Emissions Introduction Environmental Impact Combustion Systems Fuel Types Page 2

AGENDA Fuels, Combustion and Emissions Introduction Environmental Impact Combustion Systems Fuel Types Page 3

Introduction Industry requires Energy Electricity Mechanical Power Heat Most commonly provided through the combustion of fossil fuels Number of technologies can be used Gas Turbines Boiler / Steam Turbines Reciprocating Engines For this Symposium subjects covered include Fuels and Emissions issues surrounding Gas Turbines Page 4

Fluids / Gases Turbine Entry / Exit Some of the fluids entering or exiting the gas turbine core or package Exhaust Gas Combustion Air Ventilation Air Compressed Air Lubricating Oil through cooler Gas and Liquid Fuels Page 5

AGENDA Fuels, Combustion and Emissions Introduction Environmental Impact Combustion Systems Fuel Types Page 6

Environmental Impact Pollutant Effect Method of Control Carbon Dioxide Greenhouse Gas Cycle Efficiency Sulphur Oxides Acid Rain Fuel Treatment Nitrogen Oxides Ozone Depletion Smog Combustion System Carbon Monoxide Poisonous Combustion System Hydrocarbons Poisonous Greenhouse Gas Combustion system Smoke Visible Pollution Combustion System Page 7

Environmental Impact DLE - Introduction / Drivers Improve the environmental impact More stringent environmental limits Customer goals and requirements Improved operational reliability Simple design with simple operating philosophy required Minimal impact of product cost Easy to understand Easy to maintain Wide fuel range coverage Part load capable Page 8

NOx Formation 2200 T [ C] 2000 1800 1600 1400 1200 1000 Combustor GT Lean Pre-mix Combustor GT Diffusion NO X real mixing NO X stoichiometric mixing P V2 = 16 bar T V2 = 400 C = 20 ms Flame temperature NO x [ppm] 800 0 0 0,5 2 1 1 Equivalence ratio = 1/excess air ratio 2 0,5 3 0,3 Page 9

Emission Abatement Options Emissions Abatement Diffusion Flame Dry Low Emissions WI SSI PSI Wet Injection Methods: WI = Water Injection PSI = Primary Steam Injection SSI = Secondary Steam Injection Page 10

Combustion NOx Impact Diffusion flame Produces high combustor primary zone temperatures NOx is a function of temperature Results in high thermal NOx formation Use of wet injection (Water or Steam) directly into the primary zone Lowers combustion temperature Reduced NOx formation Dry Low Emissions Lean pre-mixed combustion Results in low combustion temperature Low NOx formation Low NOx across a wide load and ambient range NOx Formation Rate [ ppm/ms ] 1000 100 10 1 0.1 0.01 0.001 0.0001 0.00001 Lean Pre-mix 0.000001 1300 1500 1700 1900 2100 2300 2500 F lam e T em perature [ K ] Diffusion Flame Flame Temperature as a function of Air/Fuel ratio Flame temperature Lean burn Lean Pre-mixed (DLE/DLN) Diffusion flame reaction zone temperature Diffusion flame Lean Stoichiometric Fuel Air Ratio Rich Page 11

Environmental Aspects Pollutant Effect Method of Control Carbon Dioxide Greenhouse gas Cycle Efficiency Carbon Monoxide Poisonous DLE System Sulphur Oxides Acid Rain Fuel Treatment Nitrogen Oxides Ozone Depletion DLE System Smog Hydrocarbons Poisonous DLE System Greenhouse gas Smoke Visible pollution DLE System NOx/CO TRADE-OFF 1675 0 C DLE combustion Emissions level Optimum Temperature Combustion Aspects Diffusion Flame Lean Pre-mix Operability 2175 0 C Reactor temp Diffusion Flame (Pressure Jet burner) Excessive CO Excessive NOx Page 12

Introduction Fuels, Combustion and Emissions Introduction Fuels Types Combustion Systems Environmental Impact Page 13

Combustion Combustion Systems Available ANNULAR Used on aero engines Used on medium and large gas turbines Tends not to be site serviceable Requires major engine disassembly CAN-ANNULAR Versatile Can be changed out at site Does not require engine disassembly DLE Combustion SILO Used in some medium and large gas turbines Can be single or dual combustors Conventional Combustion Page 14

Combustion Arrangements Reverse Flow In-Line Flow Page 15

Dry Low Emissions Gas Fuel Injection/Mixing Page 16

Combustion Properties and flashback Flame speed Flame speed is determined by the combustion reaction rates and those rates depend on: Equivalence ratio Fuel type Flow regime (laminar or turbulent) Flame speed Flame Speed v Fuel Type Laminar Flame Speed Laminar Flame Stability If Air flow velocity > Flame speed (SL) Blow off If Air flow velocity < Flame speed (SL) Flashback Page 17

Combustion Combustion Types More pilot means greater diffusion flame Higher emissions and pilot temperature Pilot Burner Less pilot means more premix less NOx but higher dynamics 80 70 Main burner Pilot Split (%) 60 50 40 30 20 High Pilot => High Pilot tip temperature 10 Low Pilot => High Combustion 0 Dynamics Instability 900 1000 1100 1200 1300 1400 1500 1600 Control Parameter Page 18

AGENDA Fuels, Combustion and Emissions Introduction Environmental Impact Combustion Systems Fuel Types Page 19

Fuel Type Various fuel types - Gaseous Fuels 100% 80% vol % 60% 40% 20% 0% CO2 N2 CO H2 C3H8 C2H6 CH4 Page 20

Fuel Parameters - gaseous fuel Assessment requirements Fuel composition Fuel Placement Include contamination Supply conditions Environmental requirements Air Placement Combustion Products Page 21

Evaluation Water Vapour H2O 0.00 Oxygen O2 0.00 Carbon Dioxide CO2 0.50 Carbon Monoxide CO 0.00 Hydrogen H2 0.00 Methane CH4 94.00 Ethane C2H6 3.50 Propane C3H8 1.20 i-butane i-c4h10 0.00 n-butane n-c4h10 0.00 i-pentane i-c5h12 0.00 n-pentane n-c5h12 0.00 n-hexane n-c6h14 0.00 n-heptane n-c7h16 0.00 n-octane n-c8h18 0.00 n-nonane n-c9h20 0.00 n-decane n-c10h22 0.00 Hydrogen Sulphide H2S 0.00 Nitrogen N2 0.80 Ethene C2H4 0.00 Propene C3H6 0.00 Total 100 Density kg/m3 (ISO conditions) 0.7235 Molecular Mass 17.11 LCV kj/m3 (ISO conditions) 35065 LCV kj/kg 48468 LCV Btu/scf 941 Temperature corrected Wobbe Index kj/m3 46652 Wobbe Index Calculation Temperature C 2.5 Dewpoint Temperature C < -20 Pressure bara 20.0 Minimum gas supply temperature C 2.5 Maximum gas supply temperature C 120.0 Gas Constant ft lbf/lb K 162.47 Gamma 1.294 Specific Gravity (ISO conditions) 0.591 Page 22 INPUT DATA OUTPUT DATA Step 1: Start with a typical natural gas composition Species Formulae Mol% Methane CH4 94 Ethane C2H6 3.5 Propane C3 H8 1.2 Carbon Dioxide CO2 0.5 Nitrogen N2 0.8 Simple things: Visual Inspection Anything unusual? Wt%, Mol %, add to 100%, contaminants,? Step 2: Complete an assessment using gas analysis methods Can see other species that may be present in other fuels Calculations shown in lower section OUTPUT, includes: Lower Calorific (Heating) Value (LCV or LHV) Wobbe Index (WI) Dewpoint Density

Fuel Assessment Assessment requirements Wobbe Index (WI) parameter Compares energy input of different gas fuel compositions, and indicates the inter-changeability of gas fuels WI LCV sg Cv = Net Calorific Value sg = specific gravity Temperature Corrected Wobbe Index (TCWI) Gas may be heated e.g. due to dew point T 15 WI T WI 15 * T T Temp in Kelvin WI T WI 15 * 288 T T Page 23

Gaseous fuels- Assessment Page 24

Hydrocarbon Dew Point Water Vapour H2O 0.00 Oxygen O2 0.00 Carbon Dioxide CO2 0.50 Carbon Monoxide CO 0.00 Hydrogen H2 0.00 Methane CH4 94.00 Ethane C2H6 3.50 Propane C3H8 1.20 i-butane i-c4h10 0.00 n-butane n-c4h10 0.00 i-pentane i-c5h12 0.00 n-pentane n-c5h12 0.00 n-hexane n-c6h14 0.00 n-heptane n-c7h16 0.00 n-octane n-c8h18 0.00 n-nonane n-c9h20 0.00 n-decane n-c10h22 0.00 Hydrogen Sulphide H2S 0.00 Nitrogen N2 0.80 Ethene C2H4 0.00 Propene C3H6 0.00 Total 100 Importance of DEW Point Ensure fuel gas is maintained in vapour phase Normal to apply superheat margin Let us look at the reasons for understanding dew point and the need to apply a margin of superheat Density kg/m3 (ISO conditions) 0.7235 Molecular Mass 17.11 LCV kj/m3 (ISO conditions) 35065 LCV kj/kg 48468 LCV Btu/scf 941 Temperature corrected Wobbe Index kj/m3 46652 Wobbe Index Calculation Temperature C 2.5 Dewpoint Temperature C < -20 Pressure bara 20.0 Minimum gas supply temperature C 2.5 Maximum gas supply temperature C 120.0 Gas Constant ft lbf/lb K 162.47 Gamma 1.294 Specific Gravity (ISO conditions) 0.591 Page 25

Hydrocarbon Dew Point In the previous example the dew point for a typical pipeline gas fuel is very low so a minimum value is applied this prevents freezing in the fuel system vent pipework. Take an example where the C5 species is defined as 1.9%+ Parameter Mol % Oxygen, O2 0.37 Nitrogen, N2 9.54 Carbon Dioxide, CO2 8.00 Methane, C1 73.17 Ethane, C2 3.91 Propane, C3 1.91 Butane, C4 1.14 Propane+; C5+ 1.96 Assume all is C5: Dew Point = 2.6 O C Replacing C5 with a representative breakdown: Parameter Mol % I propane 0.5 N propane 0.5 Pentane 0.5 Heptane 0.25 Octane 0.12 Nonane 0.06 Decane 0.03 Revised dew point 52.5 O C This demonstrates the importance of providing and using the correct fuel composition. Incorrect dew point hence incorrect supply conditions results in gas condensate and impact on turbine operation. Page 26

Summary A brief overview in the use of fuels in a gas turbine and impact on the environment Method of assessment and why it is important to declare as early as possible the full details of the composition Combustion systems types and why DLE, DLN systems dominate new equipment sales Aspects of Siemens Energy standard combustion system detailed THANK YOU FOR YOUR ATTENTION Page 27